Resonance in Chirogenesis and Photochirogenesis: Colloidal Polymers Meet Chiral Optofluidics

Metastable colloids made of crystalline and/or non-crystalline matters render abilities of photonic resonators susceptible to chiral chemical and circularly polarized light sources. By assuming that μm-size colloids and co-colloids consisting of π- and/or σ-conjugated polymers dispersed into an optofluidic medium are artificial models of open-flow, non-equilibrium coacervates, we showcase experimentally resonance effects in chirogenesis and photochirogenesis, revealed by gigantic boosted chiroptical signals as circular dichroism (CD), optical rotation dispersion, circularly polarized luminescence (CPL), and CPL excitation (CPLE) spectral datasets. The resonance in chirogenesis occurs at very specific refractive indices (RIs) of the surrounding medium. The chirogenesis is susceptible to the nature of the optically active optofluidic medium. Moreover, upon an excitation-wavelength-dependent circularly polarized (CP) light source, a fully controlled absolute photochirogenesis, which includes all chiroptical generation, inversion, erase, switching, and short-/long-lived memories, is possible when the colloidal non-photochromic and photochromic polymers are dispersed in an achiral optofluidic medium with a tuned RI. The hand of the CP light source is not a determining factor for the product chirality. These results are associated with my experience concerning amphiphilic polymerizable colloids, in which, four decades ago, allowed proposing a perspective that colloids are connectable to light, polymers, helix, coacervates, and panspermia hypotheses, nuclear physics, biology, radioisotopes, homochirality question, first life, and cosmology.


What Is the Life?-Open System, Negative Entropy, Non-Equilibrium Thermodynamics
Humankind has been thinking about life for a long time; where did life come from? Where will life go? Does life exist on earth only? So far, many scientists have postulated several scenarios throughout the primordial eons to address these curious questions. Regarding the first life on earth, the origin of biomolecular handedness remains an unanswered question in the scientific community .
In 1944, Erwin Schrödinger, one of the leading quantum physicists in his day, wrote an essay book titled What is Life? With Mind and Matter and Autobiographical Sketches [1]. Entropy inevitably increases only in a closed system-like universe as the consequence of the second law of thermodynamics. Living matters, thus, cannot elude conventional physics laws, but should involve other physics laws. To avoid a thermodynamic equilibrium by a spontaneous decay, living matters have to acquire and maintain negative entropy in an open system. Because living organisms exist as metastable states, metabolism that is a biological term of maintaining negative entropy is needed through all processes of eating, drinking, breathing, and, in case of plants, assimilating. To my knowledge, the two key concepts are rarely stated in most chemistry textbooks and not lectured in schools and colleges, although Schrödinger was the first to invoke an importance of these concepts. advantage factors are universal, deterministic for the biomolecular handedness, while the local advantage factors are mirror-symmetric, hence, provide the by-chance mechanism. Among the advantage factors, the g* of circularly polarized (CP) light source is considerably high on the order of 10 −4 -10 −2 .
On the other hand, the g* for handed β − -electron is extremely small, only 10 −9 -10 −11 , while the values of g* for: (i) static magnetic field with linearly polarized light, known as the Faraday effect; (ii) Coriolis force (rotation) with static electric filed and static magnetic field; and (iii) Coriolis force with static magnetic field and gravitational field are on the order of 10 −4 . Coriolis force with gravitational force is a mirror symmetric chiral force, corresponding to the vectoral hydrodynamic flowing, often called swirling flow and vortex flow. Handed weak neutral current provides the smallest g* on the order of 10 −17 . Static magnetic field, static electric filed (so-called Stark effect), and gravitational field alone do not induce the left-right preference. CP-light, Coriolis force, static electric filed, static magnetic field, and gravitational field are parity-conserving mirror-symmetrical physical forces, while a weak neutral current and β − -electron are parity-violating handed physical sources.
In 1953, Frank treated, mathematically, the first seminal bifurcation model account for a spontaneous mirror symmetry breaking in terms of evolution of biological homochirality [45]. For visibility and clarity, Goldanskii et al. illustrated two bifurcation models connecting to double-well and single-well potential curves [42][43][44]; a mirror-symmetric bifurcation model with a mirror-symmetric double-well potential curve and a non-mirrorsymmetric bifurcation model with a non-mirror-symmetric double-well potential curve. Based on these bifurcation models associated with the g* values discussed above, Goldanskii et al. showed two scenarios, allowing us to well recognize both the bi-chance and necessity mechanisms for the spontaneous mirror symmetry breaking. Knowing the fluctuation behaviors around these bi-furcation points with those g* values, namely, a phase transition characteristics from the single-well to the double-well or from the double-well to the single-well is the key to rationally design the left-right preference, followed by the homochirality systems [7,8,46].

Circularly Polarized Light Source
Historically, in 1874, LeBel, and in 1894, van't Hoff, proposed independently a possibility of absolute asymmetric synthesis (AAS) using rand l-CP light as chiral physical source [46][47][48][49]. A half century after their predictions, in 1929, Kuhn and Broun experimentally realized their conjectures as photodestruction mode AAS [46]. Their pioneering work prompted allowed many researchers to investigate AAS for a century because expensive chiral chemical substances are no longer needed [47][48][49][50]. However, most researchers have long believed that l-CP light produces left-hand (or right-hand) molecules preferentially and vice versa because the product chirality is determined solely by the hand of CP light. The AAC with rand l-CP light covers absolute asymmetric photosynthesis, photodestruction, and photoresolution modes [47][48][49]. Generating left-right preference endowed with CP-light was coined photochirogenesis by Yoshihisa Inoue as the key concept of CP light-matter interactions in 1996 [7,8,51].
In the 1970s, Calvin et al. reported an anomaly of an excitation wavelength dependent CP light-driven photosynthesis mode AAS recognized as a switching product chirality of [8]-helicene in homogeneous toluene solution [52]. In 2014, Meinert et al. reported the wavelength-dependent CP light-driven photodestruction mode AAS revealing switching chirality when rac-alanine film was decomposed upon irradiation of two vacuum-UV light sources (184 and 200 nm) [53]. A recent development of wavelength-dependent CP light driven photoresolution mode AAS employed by us will be given in Section 4.5 [54][55][56].

Static Electric Field
According to recent works, with static electric fields, so-called Stark effects, in the absence of magnetic field, Auzinsh et al. reported chirogenesis as emission modes on the order of g = 0.20 (10% for circularity) at 7 D 3/2 state and g = 0.15 (7.5% for circularity) at 9 D 3/2 state of parity-violating, paramagnetic Cs vapor placed between two mirrored electrodes [57]. On the other hand, Datta et al. indicated an occurrence of lowering molecular symmetry of achiral diamagnetic aromatic molecules by a computer simulation. Coronene, a 6-fold highly symmetric molecule, undergoes D 6h →C 2 distortions via vibrational instability upon application of sufficiently intense static external electric field [58]. The electric field induced structural distortion is understood as resulting from excess charge accumulation of planar rings circumvented by symmetry lowering. Contrarily, tribenzopyrene, a contorted polyaromatic compound due to a repulsion by two pairs of syn H-atoms, undergoes, spontaneously, C 2v →C 2 distortions in the absence of the electric field. Coronene, tribenzopyrene, and other fused aromatics are assumed to be the representative polycyclic aromatic hydrocarbons, so-called PAHs, which are abundant in the universe [59]. Because C 2 -symmetric molecules are chiral, a naive question remains to be elucidated experimentally, whether C 2 -coronene and C 2 -tribenzopyrene exist as racemic mixtures or single enantiomers in connection with the homochirality question in the universe. Collision-free, gas-phase circularly polarized luminescence (CPL) spectroscopy may allow us to provide an answer to this question.

Static Magnetic Field
With the origin of biological chirality in mind, Pasteur was the first to attempt a chemical process called enantioselection, showing whether left-handed or right-handed molecules are produced under magnetic field, but failed because the magnetic field is a pseudo-vector that cannot be coupled with molecular chirality [60]. In 1994, Zadel et al. published an astonishing paper titled Enantioselective Reactions in a Static Magnetic Field [61]. Several research teams attempted to reproduce these results immediately, but failed [62,63], because, prior to the experiments, in the solutions, under 2.1 Tesla of static magnetic field (NMR instrument) in the paper, all reaction solutions were in advance design and manipulated [64]. Static magnetic field on the order of 2 Tesla does not induce any detectable enantioselective reaction in a fluidic solution under non-restricted Brownian molecular motions. Uniform static magnetic fields do not induce molecular chirality because of the time-odd, axial vector [60,65] Naaman and Wadeck reviewed theory and experiments of chiral-induced spin selectivity (CISS), where ordered films of chiral molecules on surfaces can act as electron spin filters [66]. By applying the idea of CISS, in 2018 and 2019, Naaman and his international team succeeded in enantiospecific crystallization of three L-/D-amino acids and thiolated L-/D-alanine-based helical oligomers at the magnetized surface with a gold-coated ferromagnet cobalt film [67,68]. Enantioselectivity is determined by north-up and south-up geometry of the magnet and the nature of chiral substances. An attractive force between electrons in the substrate and in the molecules is on the order of several tens of kJ mol −1 when a molecule surface distance is 0.1-0.2 nm [68]. Brownian motion of floppy molecules is considerably restricted at the molecule surface interface, followed by a great suppression of the molecular motions during crystallization at the surface. Since a magnetic field is a short-distance force compared to the electric field, a proximity effect of the molecule at the magnetized surface should be considered.
In 1955, Akabori proposed the polyglycine hypothesis-foreproteine as the origin of protein homochirality on Earth [22]. The hypothesis involves three steps: (i) formation of aminoacetonitrile from formaldehyde, ammonia, and hydrogen cyanide, which were ubiquitous in primordial Earth; (ii) polymerization of aminoacetonitrile at a solid surface, such as a Kaolinite that is a two-dimensional aluminosilicate Al 4 Si 4 O 4 (OH) 4 , followed by hydrolysis to yield polyglycine and ammonia; (iii) introduction of side chains to polyglycine. The experimental results showed that: (i) methylene groups of polyglycine are adsorbed on Kaolinite; and (ii) glycyl residues are converted to serine and threonine residues reacted with formaldehyde and acetaldehyde, respectively. Although achiral glycine has two equal C-H bonds, the two C-H bonds at each residue of helical oligoglycine and polyglycine are no longer equal. The two C-H bonds at each glycine residue of the helix may reveal different reactivity toward chemical species. Akabori conjectured that the origin of all L-selectivity in amino acids of proteins results from the by-chance mechanism because there is no chirality in Kaolinite. The hypothesis, followed by experiments, were reported just before the groundbreaking fever in 1956-1958 that the parity in the β-decay process of 60 Co is violated, though a left-right equality of enantiomers was a concrete common sense in chemistry in those days [69][70][71][72][73][74][75][76].
Knowing the magnetic minerals and the first geodynamo on Earth is an important clue how Earth's core, atmosphere, biomolecular chirality, and life evolved [33][34][35][36]. In 2015, Tarduno et al. claimed that, by analyzing inside of zircon crystals, which were indestructible for nearly 4.4 billion years, in Western Australia, Earth's magnetic field had evolved already from more than 4 billion years ago [33]. Likewise, from the oldest rocks in South Africa, Earth's magnetic evolved around 3.5 billion years ago [34]. Moreover, a recent work indicates that, from magnetic minerals in ancient Greenlandic rocks, Earth's magnetic field arose at least 3.7 billion years ago [35,36], enabling to magnetically shield primitive life and chiral substances evolved on Earth.
The CISS theory [66], along with the experimental results [67,68] proven by Naaman et al., encourages to test whether: (i) helical oligoglycine and polyglycine are adsorbed vertically at the magnetized surface; (ii) the two C-H bonds at each residue reveal a different chemical reactivity toward several chemical species in the absence and presence of UV-light around 190-220 nm; and (iii) enantioselectivity is determined solely by north-up and south-up geometry.
In 2019, Stevenson and Davis proposed a possibility of magnetophoresis that radical species of D-and L-substances are separable and sortable under an ultrastrong magnetic field gradient of >4.4 × 10 9 Tesla [77]. Such an ultrastrong magnetic field and gradient can no longer obey the standard Maxwell equations. Paramagnetic chiral molecular species in the universe may be passing through in the vicinity of magnetar, which are newborn neutron stars spinning very fast that generate the ultrastrong magnetic field. Kouveliotou et al. think that more than 100 million magnetars are wandering through the interstellar universe and trillions of organic paramagnetic materials are imbedded in cold molecular clouds [78]. The ultrastrong magnetic field causes vacuum birefringence, photon splitting, scattering suppression, and distortion of atoms [78]. Although magnetic field gradients are widely utilized in NMR imaging, so-called MRI, the feasibility of the ultrastrong magnetic field gradient is challenging.

Hydrodynamic Flowing as a Model of Coriolis Force with Gravitational Force
When artificial molecular chromophores and luminophores are dispersed in the fluidic medium, hydrodynamic swirling flowing clockwise (CW) and counterclockwise (CCW) are experimentally testable models to validate the origin of the gravitational field's left-right preference [79][80][81][82][83]. The vectoral hydrodynamic flowing is often called as swirling flow and/or vortex flow. The unidirectional hydrodynamic flowing in the CW or CCW direction imparts the left-right preference at the molecular and supramolecular levels. The left-right preference in the northern hemisphere may be opposite to that in the southern hemisphere due to parity-conserving physical force on Earth.
In 1993, Ohno et al. reported chirogenesis of circular dichroism (CD)-active J-aggregates from achiral free-base porphyrin derivative in acidic water solution by mechanically swirling in CW and CCW directions [79]. They observed two clear couplet-like CD bands around 410-450 nm due to Soret band and 480-500 nm due to Q-band. The couplet-like CD band profiles were inverted by choosing the CW or CCW direction during the propagation of J-aggregate. Very weak non-couplet CD band around 480 nm, however, was recognized under a stagnant condition. Obviously, the hydrodynamic flowing appears responsible for the chirogenesis, but a statistical analysis was not performed yet. It is unclear whether this event occurs using the specific porphyrin derivative at a specific laboratory.
In 2001, Ribó et al. confirmed, by the statistical analysis from nearly a hundred of independent experiments that macroscopic swirling forces in the CW and CCW directions indeed generate homochiral aggregates from water soluble achiral porphyrin derivatives that slightly differ from the porphyrin above [80]. The hydrodynamic flowing indeed acted as a trigger of the spontaneous homochiral l-or-r aggregation [81].
Although water-soluble porphyrin derivatives carrying multiple phenyl rings at mesopositions are directly connected to biomolecular substances, the idea of hydrodynamic flowing is applicable to chain-like synthetic polymers and several chromophore/luminophore during their association processes that feel the handed force of the hydrodynamic flowing, regardless of the northern and the southern hemispheres on Earth and other exoplanets. The author assumes that, since unsubstituted free-base porphyrin framework is very floppy, these porphyrin derivatives substituted with tetraaryl groups at meso-positions may adopt dynamically twisting two structures, between left and right, in a fluidic solution at ambient temperature.
In line with the bifurcation scenario, in 2011, Okano et al. succeeded in chirogenesis from achiral rhodamine B as a red luminescent molecular probe doped to a water-soluble sol-gel polymer, revealed by CPL spectroscopy [82]. Based on a statistic analysis, the sign in CPL signals at 580 nm was controlled by the CW/CCW motions of hydrodynamic flowing in a cuvette. The critical temperature (T c ) for gelation was controlled by tuning the concentration of the polymer in aqueous solution. The polymer solution was in a sol state with a low viscosity, while stirring above the T c , while the solution below the T c spontaneously underwent a non-flowing gel state in a very high viscosity.
In 2018, by mimicking submarine rock micropores at primordial Earth, Liu and collaborators designed a sophisticated microfluidic chirogenesis system [83]. The fluidic system was composed of ten pairs of inclined microchambers to efficiently generate pairs of CW and CCW microvortices using achiral 3-fold molecular symmetric aromatic molecules that possessed supramolecular gelation capability. By a statistical analysis based on 56 totally independent experiments, they ascertained that the microfluidic chirogenesis system works very efficiently by simulating a behavior of hydrodynamic flowing in the microchamber. They re-confirmed that the microfluidic system is viable for a very rapid chirogenesis within 1 ms of the water-soluble porphyrin derivative. These results should shed light on the origin of the biomolecular homochirality; how oceanic vortices play a critical role in protein folding and self-organization in primordial Earth.

Static Magnetic Field with Polarized Light
Static magnetic field with linearly polarized light and static magnetic field with unpolarized light, which are called magneto-optical effects, including Faraday and polar Kerr effects, are possible to be chiral physical sources, enable to induce mirror symmetrical, left-right imbalance in the ground and photoexcited states. The left-right chiroptical preference from achiral substances in the ground and photoexcited states is determined by north-up and south-up magnetic fields to propagation of incident light, called magnetic circular dichroism (MCD) [84][85][86][87] and magnetic circularly polarized luminescence (MCPL) [88][89][90][91], respectively. The phenomena are closely connected to Zeeman splitting of degenerate molecular orbitals. Recently, Imai, Fujiki, and coworkers verified mirror symmetrical MCPL characteristics from diamagnetic achiral organic and racemic lanthanide luminophores. These luminophores radiate land r-CP light upon unpolarized light at north-up and south-up Faraday geometry [92][93][94]. However, it is obscure whether mirror symmetrical MCPL arises from Zeeman splitting of degenerate molecular orbitals in the ground states or in the photoexcited states because a comparison with the corresponding MCD spectra is not elucidated yet. Nevertheless, in analogy with the first report of Raman scattering in 1928 [95], the MCPL characteristics teach that the handed light emission under external magnetic field is becoming a new type of secondary radiation sources, land r-CP light, in the absence of any chemical chirality, when achiral luminophores are, by-chance, placed on magnetized substances (even on ubiquitous), but a weak geomagnetic field of 3 × 10 −5 T. In that case, the magnetic fields should satisfy north-up and south-up Faraday geometries. A magnetic field-caused CP light source from achiral luminophores may be ubiquitous in the universe, and was therefore the source of circularly polarized radiation as seeds of molecular chirality in the past (and now all over universe).
Rikken and Raupach designed a static magnetic field-driven photoresolution molecular system using racemic K 3 Cr III (oxalate) 3 complex in water upon irradiation of Ti:sapphire laser at 696 nm [96]. They demonstrated an occurrence of mirror-symmetrical photoresolution from the complex, in which a preferential chirality is determined by north-up and south-up Faraday geometries. Recently, Sharma calculated (based on the MCD effect) that unpolarized ultraviolet sunlight, so-called UV-C region, combined with atmospheric paramagnetic oxygen diluted with carbon dioxide can possibly trigger an initial enantiomeric excess (ee) to determine the biomolecular handedness under the geomagnetic force in Archaean Earth [97]. Notably, when the UV-C light destructs several biomolecular constituents, a preferential chirality between purine and pyrimidine nucleosides depends on a partial pressure of carbon dioxide. However, a preference in the product chirality of amino acids is always L-form. Thus, a static magnetic field with unpolarized light becomes one candidate for efficient photodestruction, and photoresolution modes in racemic amino acids and nucleosides in water disregard of terrestrial and interstellar conditions.
In 1959, this discovery prompted Vester and Ulbricht to propose so-called Vester-Ulbricht (V-U) hypothesis: parity-violating, spin-polarized left-handed β-electron causes circularly polarized bremsstrahlung that preferentially decomposes D-amino acids and left-handed DNA precursors, thus remaining l-amino acids and right-handed DNA on Earth [98,99]. In 1984, Bonner reported the failure of the V-U hypothesis-that several racemic amino acids cause radioracemization when polarized β-electron Bremsstrahlen from radioisotopes 90 Sr-90 Y, 14 C, and 32 P is applied [100].
In 1982 and 1984, Zitzewitz et al. utilized low-energy, right-handed β-positron in place of left-handed β-electron, and reported a weak asymmetry of leucine while cystine and tryptophan had little V-U effects [101,102]. In 2014, Dreiling and Gay confirmed successfully that the V-U hypothesis is valid, based on the detection of a preferential L-D decomposition of racemic 3-bromocamphor [103]. In 2018, Dreiling et al. confirmed volatile ester derivatives of DL-amino acids and DL-sugar molecules with low-energy β-electron and β-positron may be suited to verify the V-U hypothesis.

Handed Weak Neutral Current Mediated by Z 0 Boson
The β − -and β + -decay processes are mediated by massive W − boson (80.4 Gev) and W + (80.4 Gev) boson, respectively. On the other hand, parity-violating weak neutral current mediated by massive Z 0 boson (91.2 Gev) is ultimately a handed chiral physical bias for subatoms, atoms, molecules, supramolecules, polymers, colloids, crystals, inorganics, possibly our life, and upward disregard of terrestrial and extraterrestrial origins. According to the electroweak theory, massive three W − , W + , Z 0 bosons and massless photon (boson, light) can be unified to the same family above~10 15 eV [104]. Upon rapid cooling of our universe, the parity-violating weak force and parity-conserving electromagnetic force are separated at~10 15 eV by the bifurcation mechanism.
Up until now, many scientists in chemistry and molecular physics argued theoretically a possibility of parity-violation in molecules, in relation to the origin of biomolecular handedness on Earth, often called molecular parity-violation hypothesis. Parity-violation energy difference (PVED) of L-and D-molecules predicted theoretically is ultrasmall on the order of 10 −8 −10 −14 kcal mol −1 or 10 −9 -10 −15 % ee. In 1983, Mason and Tranter showed that, from calculation of the PVED with Slater-type-orbitals (STO) with 6-31G basis set, L-alanine and L-polypeptide in α-helix and β-sheet are energetically stabilized compared to the corresponding D-alanine and D-polypeptide, due to parity violating weak nuclear current [3,113]. However, the PVED is ultrasmall on the order of 10 −23 kcal mol −1 . Most chemists, therefore, think that the molecular parity-violation hypothesis is doubtful and skeptical. Even if the hypothesis is true, it is experimentally impossible to prove by ordinary spectroscopy and enantioseparation column chromatography.
Most theories are treating ideal isolated molecules, including simple amino acids, carbohydrates, hypothetical, and realistic molecules, including heavier atoms in a vacuum at absolute temperature of zero-Kelvin. Additionally, the molecular parity-violation theorists always require experimentalists, who directly detect the tiny PVED for a pair of left-and right-molecules and well-defined oligomers in a collision-free condition, such as a reduced pressure, using precision high-resolution spectroscopy. Theorists think that solutions, solids, aggregates, gels, and polymers should be excluded in testing the molecular parityviolation hypothesis. Most theories focused on the PVED at the electronic, vibrational, and ro-vibrational ground states [3,[113][114][115][116][117]. Experimentalists attempted to detect the PVED as absorption mode, using several sophisticated high-resolution spectrometers [118]. In 2003, Berger calculated the PVED of formyl aldehyde, HFC = O, in the electronically excited states that are suited to experimentally test the PVED hypothesis because of an enhanced PVED amplitude from a well-defined photoexcited parity [119].
In an analogy of Kasha's rule in photochemistry, radioisotopes 60 Co and 58 Co as excited states of the corresponding stable isotopes 60 Ni and 58 Fe, respectively, allowed to unveil the parity-violation in their β ± -decay radiation processes. Similarly, detecting atomic parity violation as emission mode from atomic vapors is more obvious, rather than absorption mode [109][110][111][112]. These spontaneous radiation processes to the ground state, connecting to parity, commonly arise from the far-from, non-equilibrium excited state.
The β ± -decay process, atomic parity violation as emission mode, and Berger's theory stimulated the author and coworkers to measure spontaneous radiation processes from S 1 state of nearly sixty non-rigid rotamers as achiral and/or racemic luminophores homogeneously dissolved in achiral solvents (not optofluidic solvents) in the photoexcited states to detect difference as emission modes between L-D molecular state upon excitation of unpolarized light [120,121]. All of these rotamers showed (−) sign CPL signals in the UV-visible region, suggesting temporal generation of energetically inequal, non-racemic structures under conditions of far-from, open-flow, non-equilibrium S 1 -state, realized only upon a continuous irradiation of incoherent unpolarized light. Unpolarized light is an equal mixture of left-and right-CP light. For comparison, unsubstituted achiral fused aromatic luminophores that adopt rigid planar structures did not show CPL signals. Furthermore, D-and L-camphor, an enantiomeric pair of rigid chiral XYC = O dialkyl ketone luminophores, showed ideal mirror-image CPL spectra. From these comprehensive results, the author and coworkers invoked that the parity of non-rigid molecular rotamers in the photoexcited is violated, followed by radiating (−) sign CPL signals without any exception [120,121].
Currently, experimentally testing the molecular parity-violation hypothesis remains a hot topic and very challenging. Collision-free, gas-phase CPL spectroscopy may be a useful tool to provide a definitive answer to this long-standing question. Although this topic is not a major issue in this paper, the author, his coworkers, his students, his researchers, and his technical staff are aware of the facts that non-ideal mirror-image CPL and CD spectral characteristics can be often seen in our colloidal polymers dispersed in optofluidic media with tuned RIs. Some of the readers may be aware of the non-ideal mirror-image CPL and CD spectral characteristics in this paper. The author conjectures that these non-ideal mirror-image chiroptical characteristics from the colloidal polymers in tuned optofluidic media could be connected to certain mechanisms, in an enhancement in weak neutral currents at molecular and polymer levels. Those who are interested in this topic should read related parity-related reviews, monographs, and original papers, shown above.

Extraterrestrial Origins of Life and Chirality-Panspermia Hypotheses
Apart from the physical aspects in the previous sections, the fascinating, awesome extraterrestrial scenarios might be several panspermia hypotheses [122,123]. Panspermia means seeds everywhere in a Greek word. The panspermia hypothesis assumes that seeds of life ubiquitously exist in the past and, even now, all over universe, allowing to spread from one to another spaces and locations. The hypotheses may invoke us that seeds of chirality are ubiquitous in the past and, even now, all over universe.
In the late 19th century, Louis Pasteur, William Thomson (Lord Kelvin), and Hermann von Helmholtz conjectured extraterrestrial origin of life (and biological chirality). In 1903, Svante Arrhenius, Swedish physicist and chemist, proposed the radio-panspermia hypothesis; certain seeds of life with sizes of 200-300 nm traveled by radiative pressure of solar light and stellar light, landed on Earth [122]. In the 1960s-1980s, Hoyle and Wickramasinghe hypothesized cometary panspermia based on detection of astronomical radiation and reflectance in the range of 2.5-4.0 µm (~3000-3800 cm −1 ) from dust coma of Comet Halley and Comet 67P/Churyumov-Gerasimenko [123]. The cometary panspermia, including comets, interstellar dusts, and asteroids, can carry several viruses and microbials, which landed on Earth from the primordial era (and even now) [123]. The scenarios led to propose further lithopanspermia (often referred to interstellar panspermia) and ballistic panspermia hypotheses (often referred to interplanetary panspermia). In lithopanspermia, impact-expelled rocks and meteorites from a surface of planet acts as spaceships to spread biological materials and microbials from one solar system to another solar system, while, in ballistic panspermia, the same events occur within the same solar system.
In 2013, Kawaguchi, Yamagishi, and coworkers hypothesized massapanspermia that microbial aggregates are transferrable between planets [124]. In 2020, they confirmed that aggregates of Deinococcus radiodurans (a representative radioresistant bacteria) can survive under the very severe space environment for 2-8 years, enabling the interplanetary travel that delivers the seeds of life and related chemical stuffs for many years [125]. The new hypotheses might encourage astrobiologists and astrochemists to pursue the possibility of the extraterrestrial life and related chemical substances, including liquid water and chiral molecules conducted by sophisticated spacecrafts, orbiting telescopes, and high-resolution spectrograph on Earth, followed by recent triumphs in astroscience.
For example, astroscientists confirmed plumes of water vapor and are now confident about the existence of water ocean on Europa (that is one of Jupiter's moons), with help from auroral emissions of hydrogen and oxygen by the Hubble space telescope (HST, National Aeronautics and Space Administration: NASA), observation by the Galileo spacecraft (NASA), and direct detection of water vapor using near-IR spectrograph at the 10-m Keck Observatory (Hawaii) [126]. The Rosetta space probe (European Space Agency: ESA) detects prebiotic constituents and water on Comet 67P/Churyumov-Gerasimenko, one of the comets in the Jupiter family [127,128]. The Cassini spacecraft (NASA), the Saturn probe launched in 1997, discovers water under the surface of Enkelados, which is one of the Saturnian moons, with help from the quadrupole gravity measurement system [129]. JPL (Jet Propulsion Laboratory at NASA) reported that Titan, which is the largest Saturnian moon, possesses water comprising inorganic salts [130]. The Kepler space telescope (NASA) discovered over 2600 exoplanets; among them, numbers of Earth-like planets are hidden in habitable zones [131,132]. In 2016, astronomers discovered interstellar chiral propylene oxide generating in SagittariusB2 of the Milky Way Galaxy by analyzing the unique absorption bands in the range of mm-wavelength of Parkes radio telescope at Australia Observatory [133]. A preference between L-and D-propylene oxides remains obscure because the telescope is not a polarized microwave spectrometer. In 2019, an international team from Japan and USA showed, for the first time, evidence of extraterrestrial origin 13 C-enriched sugars from carbonaceous chondrites in two meteorites (NWA801 and Murchison) by means of gas chromatography-mass spectrometry (GC-MS) [134].
In December 2014, aiming to verify the panspermia hypothesis associated with the origin of life and molecular chirality on Earth, the Hayabusa-2 spacecraft (Japan Aerospace Exploration Agency: JAXA (Chofu, Tokyo, Japan)) launched to land on the surface of 'Ryugu', which is one of the carbon-rich asteroids. In December 2020, on the way to the next target (1998KY26, a rapidly spinning asteroid), the spacecraft delivering a small capsule, called Urashima's treasure chest, containing organic and gaseous ingredients for life, had just returned to Earth [135]. Importantly, the substances captured from the sub-surface of Ryugu did not contain any contaminations existing on Earth. Japanese researchers are analyzing all of the ingredients. The team anticipates evidence of extraterrestrial-origin molecular substances associated with preferential chirality if the substances are chiral.

Terrestrial Origins of Life and Chirality
In 1953 and 1959, Miller and Urey reported production of nearly forty amino acids including glycine, α-alanine, β-alanine, aspartic acid, and so on, by applying electric discharge under reducing atmosphere containing CH 4 , NH 3 , H 2 O, and H 2 [136,137]. The system is regarded as an open-flow, recycling chemical reaction system that is experimentally testable at ordinary lab level to mimic primitive Earth. Although the product chirality was not characterized at those days, the electric discharge was thought be, at least for the author, an unpolarized high-energy electromagnetic force that produces racemic amino acids. In 2013, Bada reviewed his insights of prebiotic chemistry under the volcanic condition [138].
In 2017, a Japanese team reported an astonishing result that thundering is generating γ-ray, called atmospheric photonuclear reaction [139]. The thundering acts as a naturally occurring accelerator, which might ubiquitously generate in primordial Earth, and is regarded as a realistic electric discharge in the Miller-Urey experiments [136,137]. The naturally occurring γ-ray is responsible for several photonuclear reactions. When γ-ray collides to the atmospheric 14 N molecule, radioactive 13 N (t 1/2 598s) and neutron (t 1/2~8 90s) will be generated. The unstable 13 N causing β + -decay reaction produces stable 13 C, positron, and neutrino. The neutron with 14 N produces radioactive 14 C (t 1/2 5700±30yr). The unstable radioactive 15 N (t 1/2 122s) by capturing the neutron re-generates γ-rays. The Japanese team detected γ-rays at 0.511MeV regenerated by electron-positron annihilation. These scenarios infer that all electron, positron, neutron, and radioactive atoms may become parity-violating handed physical sources.
A non-naturally occurring radioisotope 60 Co, which is synthesized from stable isotope 59 Co by capturing one neutron only in a nuclear reactor, cannot contribute to the left-right imbalance on primordial Earth. However, naturally occurring, long-lifetime radioisotopes 235 U, 238 U, 232 Th, 87 Rb, and 40 K, embedded to continental crust, mantle, oceanic crust, and sediment of Earth contribute in principle to the left-right imbalance through the β − -decay channels radiating handed elemental particles and radiating γ-rays [140][141][142].

Extraterrestrial Origins of Circularly Polarized Radiation Sources
On the other hand, scientists have long argued that several kinds of circularly polarized electromagnetic sources, including γ-ray, X-ray, and vacuum-UV in the universe, are responsible for the biomolecular handedness [4][5][6][7][8][9][13][14][15][16]. Alternatively, a subtle imbalance of L-and D-amino acids as tiny chiral chemical seeds significantly catalyze asymmetric chemical reactions to yield carbohydrates with a high ee, leading to the handed biomolecular world [48]; a nearly racemic substance in 10 −5 % ee attained a nearly~100% ee when the Soai reaction was regarded as a testable model of the chemical evolution of chirality in prebiotic eons [143,144].
When these substances are homogeneously dissolved in solutions, a probability of CP light (photon chirality) that reacts with racemic and prochiral biomolecular is, at most, one-chance with quantum efficiency of 1.0 by assuming the Beer-Lambert law. We assume that non-rigid, efficient, photonic resonators adaptable to photon chirality is possibly suited for recycling CP light-matter interactions, such as whispering gallery mode (WGM).

Coacervate Hypothesis
In the 1920s-1930s, Oparin [23] and Haldane [145] proposed the coacervate hypothesis, which is a prototype of living cells during the chemical evolution of life. The coacervate refers to sphere shape, cell-wall free colloidal droplets, from 1 µm and 100 µm in diameter, surrounded by fluidic water. The colloids comprising organic substances were postulated to spontaneously lead to a metabolism after a prolonged time. The hypothesis relies on a scenario of spontaneous self-organization arising from non-covalent interactions, such as hydrogen bonds, electrostatic, van der Waals, dipole-dipole, and so on. The hypothesis was mostly abandoned because the closed coacervate systems in an equilibrium state did not evolve living organisms.
In 2020, Lu and Spruijt demonstrated experimentally and theoretically how immiscible multicomponent droplets consisting of oppositely charged polyelectrolytes in the presence of several additives undergo a spontaneous formation of ca. 1-10 µm size multi-phase coacervates, with help from interfacial tensions and concentration of salts [146]. The multiphase coacervates dispersed in water containing salts spontaneously propagate to hierarchically self-organize cellular structures with time. The coacervates hypothesis is not an old-fashioned concept. A remodeled coacervates hypothesis sheds light on a new insight of how non-equilibrium colloidal particles in fluidic solutions propagate spatiotemporally [146]. In-situ observations of spatiotemporal propagation behaviors associated with a preferred handedness in chirogenesis of coacervates, using sophisticated circular dichroism (CD) and circularly polarized luminescence (CPL) microscopy, are challenging [147][148][149][150][151][152].

Colloids
Colloid science has a long history [153]. Colloids involve micelles, vesicles, shapecontrolled polymers, molecular and macromolecular aggregates, emulsion of polymers, core-shell nanoparticles, spherulite, microgel, and possibly, coacervate. In 1919, le Chatelier hypothesized that the size of colloids ranges from 1 nm to 1000 nm [154]. In the 1920s, makromolekül (macromolecule) was categorized to one of the colloids because the makromolekül hypothesis proposed by Staudinger was controversial [155]. Although the concept was established in the 1930s, charged colloids made of macromolecules and/or polymers did not appear to be well-recognized in those days. It is obscure whether Oparin and Haldane recognized in those days that the coacervate hypothesis was intimately connected to colloid science, macromolecular/polymer science, and supramolecular science. In 1952, Terayama proposed polyion complexes in water of oppositely charged water-soluble polyelectrolytes, nowadays, widely known as the colloid titration method [156]. Non-charged co-colloidal polymers, however, did not appear to be well-recognized until recently. It is still unclear how co-colloidal chiral polymers propagate with time.

Ostwald Ripening and Viedma Ripening
In 1990, Kondepudi et al. found that, from saturated solution of C 3v -symmetric achiral sodium chlorate (NaClO 3 ) in water, L-or D-crystal in nearly 100% ee is dominantly generated in a beaker solely by mechanically stirring. Contrarily, no preference in the L-D crystal was obtained under stagnant condition [157]. The homochiral L-or D-world in the beaker is determined by the by-chance mechanism. Martin et al. indicated that damages in the first-generation crystals, led by the stirring, can produce numbers of the second-generation crystals in smaller size, which are responsible for the production of Lor D-crystal in a vessel [158]. The initial chirality in the first-generation crystals act as the seed of chirality in the second-generation crystals during mechanical stirring, leading to autocatalytic homochiral crystallization. It is noted that hydrodynamic convection flow as mimic model of Coriolis force was not responsible for the L-or-D crystallization [158].
These studies stimulated another autocatalytic homochiral crystallization, known as the Viedma ripening. In 2005, Viedma observed attrition-enhanced de-racemization phenomenon in a mixture of solid/liquid of enantiomorphous crystals using NaClO 3 [159]. In 2008, Viedma and coworkers developed this approach to evolution of homochiral crystal D-or L-aspartic acid in the presence of salicylaldehyde as a catalyst at elevated temperatures (90-160 • C) [160]. Enantiomerically pure aspartic acid that is rapidly racemized upon heating is assumed to be a realistic amino acid existing on the primordial Earth.
Possible mechanisms underlining should involve four steps [161]: (i) Ostwald ripening with an initial chirality with help from the gliding to introduce crystal damage/defects and non-racemic additives; (ii) enantiospecific aggregation to a larger aggregation with the same chirality; (iii) a breakage of the aggregates; and (iv) racemization. Ostwald ripening with chirality is a dynamic process of chirality crystal growth and dissolution due to the crystal-size dependent solubility. A larger size chiral crystal has a lower solubility due to a smaller specific surface area, conversely, a smaller size chiral crystal has a higher solubility due to a large specific surface area.
In 2007, Viedma tested the parity-violation hypothesis of whether handed crystals (L or D) using NaClO 3 and NaBrO 3 are generated [162]. Heavy Br atom was expected to boost the parity-violation effect obeying 5-6 power dependency of the weak neutral current based on a large spin-orbit coupling. Systematic experimental results of mirror symmetry breaking on a macroscopic level, however, did not support the parity-violation hypothesis. The results were ascribed to unidentified cryptochiral impurity existing in environmental conditions. The crystallization protocol is, possibly, very susceptible to external impurities as chiral seeds, rather than the weak neutral current effect.
These studies infer to us that, by controlling the dynamic process between chirality and non-chirality at the solid-liquid interface, an alternative heterogeneous chirogenic system comprising colloid and its dispersion solvent is possible, when proper colloidal polymers with chiral liquefied media are chosen.

Optofluidics Connecting to Colloids and Circularly Polarized Light
In 1986, Qian et al. reported the first laser emission from free-falling droplets doped with red-color dyes upon excitation of a 532 nm laser based on WGM mode, or morphological dependent resonance mode, whereas rhodamine 590 and rhodamine 640 were used as dyes [163]. In 2006 to 2010, the optofluidics, which is analogous to the corresponding solid-state optical devices, was coined for a conceptional fusion of integrated optics and microfluidics [164][165][166][167]. Microfluidics is an essential science of precisely controlling and manipulating fluidic medium in the range of ten-to-hundred µm in diameter. One can design unique µm-scale liquid-based optical devices with a greater flexibility; for example, it is easy to: (i) tailor several optical properties of the fluidic medium, such as refractive index (RI), wettability, and viscosity; (ii) construct optically smooth colloid-liquid interfaces; and (iii) confine massless light into an optical resonator. Moreover, Whitesides, Psaltis, and coworkers demonstrated that ultralow threshold dual-color lasing from rhodamine 560 and rhodamine 640 in 20-40 µm size droplets of benzyl alcohol (n D = 1.54) is possible when dispersing in C 7 F 15 OC 2 H 5 , which is a low RI fluorinated solvent with n D = 1.29 [168]. Note that n D means an average RI value at 589.0 and 589.6 nm of doublet D-lines arising from vapor of atomic sodium. The lasing droplet device is realized based on the WGM scheme [163,168,169]. The idea of optofluidics was recently realized as Varioptic ® from Corning ® (Corning, NY, USA), which is a commercial product of variable focus liquid lens. The Fabry-Pérot resonator in a planar microfluidic geometry using Bragg-type grating reflectors shows a resonantly enhanced transmission with a sharp peak at a well-tuned RI in a fluidic medium [170].
In a light-harvesting plant system, stroma in chloroplasts is adaptable to any alterations, such as osmotic pressure, Mg 2+ /K + ions, sunlight intensity, temperature, and so on [171][172][173][174]. The stroma may work as naturally occurring, self-tuning optofluidic medium. The underlying mechanism teaches that, to maintain the non-CP and CP light-driven photophysical and biological properties, the chirally assorted macro-colloids surrounding optofluidic stroma appear key [171][172][173][174]. Likewise, the adaptability and flexibility to any alterations in chemical and physical biases are crucial in the chemical evolution and propagation of life.
The noticeable advantages facilitate anyone to fabricate the low-reflection-loss chromophoric and/or luminophoric colloidal molecules and polymers with high RIs by surrounding a fluidic medium with a lower RI to resonantly boost chiroptical spectral responses in the ground and the photoexcited states. Based on the optofluidics, the colloidal polymers in the ground and photoexcited states as a function of RI of the surrounding solvents are rarely studied. We showcase several optofluidic effects of colloidal polymers in the ground and photoexcited states by tuning the RI of the solvents in the following.

Microdroplets and Aerosols-Prebiotic Chemical Reactors
Atmospheric µm-sized aerosols and µm-sized droplets called microdroplets in water offer unique chemical and photochemical reactors by concentrating molecules, which serve several key precursors, such as oligopeptides and ribonucleosides in the prebiotic Earth [175][176][177]. The µm-sized aerosols and µm-sized microdroplets are regarded as realistic models testable of the coacervate hypothesis on a laboratory scale.
Recently, researchers became aware of the fact that various chemical reactions and processes in the microdroplets are significantly accelerated by several orders of the magnitudes, compared with the corresponding reactions and processes in the bulk phase [178]. These reactions and processes confined in the microdroplets differ from the conventional chemistry in homogeneous solutions. The reactions involve protein unfolding [178], helix formation [179], phosphorylation in ribonucleosides [176,177], production of nanostructures [180], autoreduction [181], and so on. Although the oil/water, air/water, and silica/water interfaces are used as the platforms, the cause of the acceleration mechanisms in these microdroplets is as a matter of debate.
To address the issue, in 2018, Zare et al. designed-to experimentally and computationally study the distribution and photoluminescence (PL) polarization anisotropy of rhodamine 6G as a PL probe doped into microdroplet oils (3M TM Fluorinate ® FC-40-a mixture of two perfluoroalkyl amines, n d = 1.29) dispersed in water (n d = 1.33) [182]. They found that, when a radius of the microdroplet increases and a concentration of rhodamine 6G decreases, the density of rhodamine 6G is significantly higher on the surface than in the center of the microdroplets and that the ratio of the surface density to that of the center grows. Moreover, PL polarization anisotropy on the surface of the microdroplets is significantly large, indicating that rhodamine 6G is well-aligned on the surface. The reduced entropy affects the significant change in the free-energy for the reactions [182].
The concept of optofluidics is applicable to photoexcited microdroplets and aerosols that are regarded as open-flow, non-equilibrium, volatile photochemical resonators. Relative RIs of organic microdroplets in water and aerosols in air are n d (droplet)/n d (water) = 1.4-1.6/1.33 and n d (water solution)/n d (air) ≥ 1.33/1.00, respectively. When prochiral substances in the photoexcited microdroplets and aerosols are concentrated on their sur-faces, one can anticipate WGM-driven accelerated photochemical reactions in absolute asymmetric synthesis (AAS) or absolute photochirogenesis (APC) with a CP light source in the absence of an external magnetic field and unpolarized light in the presence of an external magnetic field.

Our Hypothesis for Chirogenesis and Photochirogenesis
As mentioned above, the multiple concepts of panspermia and coacervate hypotheses, g* value, bi-furcation model, circularly polarized (CP)-light driven photochirogenesis, optofluidics, and WGM stimulated us to investigate open-flow, non-equilibrium colloidal systems composing of artificial chain-like polymeric chromophores and luminophores dispersed in optofluidic biomolecular liquefied chiral terpenes, as chiral foods and beverages. Moreover, we explored a possibility of AAS or APC of the artificial coacervate as a suspension state in achiral organic solvents upon excitation of a wavelength-dependent CP-light source as a model of cosmos-origin chiral electromagnetic forces. These external chirality-driven, open-flow systems allowed to mimic the tempo-spatial transcription of molecular chirality and light chirality in the cell-wall free colloids on Earth at ambient temperatures in the absence and presence of CP light sources.
The open-flow, dissipative structures connected to molecular motions is a curious subject in the present special issue [183]. This is beneficial because chirogenesis and photochirogenesis from optically inactive colloids of π-/σ-conjugated polymers in the ground state and in the photoexcited state are easy to quantitatively characterize by means of CD, optical rotation dispersion (ORD), CPL, and CPL excitation (CPLE) spectroscopy. The π-/σ-conjugated polymers are excellent chromophores and luminophores as probes in place of amino acids and sugars.
Our knowledge and understandings of the π-/σ-conjugated polymers at ordinary laboratories on the northern hemisphere of the spinning Earth could shed light on rethinking about possible scenarios of the first life associated with L-amino acids and D-sugars, regardless of terrestrial and extraterrestrial origins.

Resonance Effects from Colloidal Systems in Optofluidic Media in the Ground and Photoexcited States
In the following sections, we highlight the importance of optofluidics for achieving an efficient chirogenesis and an efficient photochirogenesis using several π-/σ-conjugated polymers in UV-visible-near IR (NIR) regions. Particularly, a fine tuning of the RI value of the surrounding liquids allows us to resonantly boost chiroptical signals and photochemical reactions within a µm-size colloidal polymers. To our knowledge, such comprehensive, systematic studies, showcasing marked resonance effects of chirogenesis and photochirogenesis in the realms of chiroptical spectroscopy, asymmetric chemistry, synthetic chemistry, polymer chemistry, colloid chemistry, photochemistry, photophysics, and materials chemistry, have not been reported yet.
All of the spectral analyses of colloidal substances in the ground and photoexcited states were conducted by practical chiroptical approaches using JASCO J-725/J-820/CPL-200 spectrometers equipped with commercial and custom-made accessories. First, a classical ORD spectroscopy shows us, exactly, a left-right imbalance of chiral chromophores in the ground state as differences in relative RIs and/or light speeds between left-and rightcircular polarized light as a function of wavelength in a vacuum. Next, CD spectroscopy allows detecting a left-right imbalance of chiral chromophores in the ground state as a difference in absorption (attenuation) between left-and right-circular polarized light as a function of wavelength in a vacuum. Moreover, CPL spectroscopy can detect a left-right imbalance of chiral luminophores in the photoexcited state as a difference in radiation probability between the left-and right-CP light emission processes when unpolarized light is excited at a specific wavelength of the chromophore as a function of wavelength in a vacuum [184]. In an analogy to achiral photoluminescence excitation (PLE) spectroscopy, CPLE spectroscopy provides differences in absorption band profiles in the ground state responsible for the specific CPL signals in the photoexcited state solely by monitoring, at a specific CPL band, as a function of wavelength in a vacuum. Although CPLE spectroscopy is rare in the realm of chiroptical spectroscopy, we often apply this technique to clarify which unpolarized absorption and CD bands are responsible for CPL/PL bands, particularly, dual/multiple CPL bands with opposite chiroptical signs [185]. Importantly, CPL, CPLE, PL, and PLE spectroscopy cannot apply to non-luminescent and ultraweak luminescent chromophores. More importantly, achiral and 50:50 racemic mixture of chromophores in the ground state and luminophores in the photoexcited state reveal zero-signals because of any differences between left-and right-ORD, between left-and right-CD, between leftand right-CPL, and between left-and right-CPLE signals. Notably, we should pay attention to artifact signals when anisotropic specimens, oriented films, solid substrate with periodicity acting as additional linear polarizers are employed [186]. It is beneficial that, because µm-size colloidal particles are randomly dispersed in fluidic medium that is similar to optically anisotropic molecules in homogeneous solutions, the chiroptical artifact is not a serious issue, even if an individual colloid is optically anisotropic.

Colloid-Induced Chiroptical Enhancement and Aggregation-Induced Emission
Firstly, we briefly touch upon two histories in the communities of artificial chiral chemistry, solution chemistry, and colloid/aggregation chemistry, including colloid-induced chiroptical enhancement (CIE) and aggregation-induced emission (AIE).
A photophysical transition from nearly non-emissive molecules dissolved in homogeneous solutions to highly photoluminescent colloidal particles dispersed in heterogeneous solutions was established as a well-known phenomenon in the last two decades [187,188]. In 2001, Tang et al. found an anomaly in the enhancement of quantum yield from aggregates made of 1-methyl-1,2,3,4,5-pentaphenylsilole [189]. The silole derivative revealed an abrupt enhancement in the quantum yield (φ) of PL by solely adding water from a weak φ ≈ 0.06% in ethanol to high φ ≈ 90% in water-ethanol cosolvents. The aggregation process is responsible for the enhanced quantum yield. The phenomenon was coined aggregation-induced emission (AIE). Soon, the origin of the AIE phenomenon was explained by restricted intramolecular rotations of multiple C-C bonds of phenyl groups at peripheral position of the silole ring [190]. Either increasing solvent viscosity or decreasing solution temperature efficiently enables suppressing the rotational freedom at a molecular level in the aggregates. This idea was viable for several aggregates made of polyacetylenes substituted with floppy 1,1,2,3,4,5-hexaphenylsilole (HPS) in acetone-water cosolvents. In 2012, the aggregate of silole derivative carrying two long D-sugar-based tails in n-hexane-dichloromethane cosolvents showed the first AIE-circular dichroism (AIE-CD) in the ground state and AIE-circularly polarized luminescence (AIE-CPL) in the photoexcited state [188,191]. The Kuhn's dissymmetry ratio in the CPL spectrum (g CPL ) value [188] reached ≈ −0.32 at 500 nm, in which the degree of circular polarization was −0.16. Similarly, the aggregate of tetraphenylethylene (TPE) substituted with two L-valines in a mixture of dichloroethane and methanol revealed AIE-CPL of g CPL ≈ −5 × 10 −3 . Highresolution images of scanning electron microscope and transmission electron microscope (TEM) indicated that one-dimensional helical fibers of the TPE aggregate are responsible for the AIE-CPL and AIE-CD [188,192].
We should touch on major differences between AIE-CD/AIE-CPL and CIE-ORD/CIE-CD/CIE-CPL/CIE-CPLE because both phenomena are related to significant amplification of chiroptical signals in the ground and photoexcited states.
First, AIE-chiroptical systems rely on significant suppressions of rapid intramolecular rotations among single bonds based on very low rotational/twisting barrier heights, which are responsible for thermally excited, non-radiation processes in the photoexcited and ground states. To achieve the suppressions at a molecular level, adding poor-or nonsolvent-like water to homogeneous solutions, e.g., tetrahydrofuran (THF) and acetone as good solvents, of the weakly emissive substances is the key. The poor-/non-solvent and good solvents are completely miscible in any volume fractions. Actually, the building blocks of AIE, such as TPE and HPS, are highly emissive in the solid states, owing to great suppression of molecular motions and vibrations, where they dissolved in good solvents, are weakly emissive due to rapid rotational/twisting mobilities. In my view, controlling RI values of a mixed co-solvents of poor-/non-solvent and good solvent does not appear to be a major factor. However, the n D value might alter in response to volume fractions of THF-water cosolvents because a lower RI water (n D = 1.333) and a higher RI THF (n D = 1.407) are mixed together. Thus, we assume that AIE-chiroptical signals of the aggregates are possible, to maximize at specific volume fractions, namely, specific n D , of good-poor co-solvents, to satisfy a resonance condition.
Contrarily, CIE chiroptical systems are largely affected by relative RI values between colloidal polymers and the surrounding fluidic media. To rationally realize the resonance condition in chiroptical signals, we often use semi-flexible and rod-like chain-like chromophoric polymers with a narrower molecular weight distribution. These polymers are inherently highly emissive, even in dilute homogeneous solutions, and in solid films. The reason for the semi-flexible and rod-like polymers is to restrict rotational freedoms along huge numbers of single bond sets. These polymers ensure spontaneous association of well-ordered packing structure during a controlled slow addition of a poorer solvent to the polymer solution, monitored by the naked eye. This approach belongs to a fractionation technique, to isolate the desired molecular weight of polymer from a broad molecular weight distribution of synthetic polymers, during a two-phase separation phenomenon. In our case, fine tuning the RI value of poor and good cosolvents, however, is the key, because polymers in the colloids often involve the surrounding co-solvents and usually exist as a swollen state. Thus, we have to experimentally determine the best volume fraction, namely, RI value, of poor and good cosolvents by measuring CD spectral shape with CD signal magnitudes of the colloidal systems. However, more importantly, when a specific resonance condition in the colloidal system is established with help from the RI-tuned cosolvents, the tiny chiroptical signals are enhanceable by huge times of reflection at the colloid-liquid interfaces due to confinement of traveling light in line with WGM, as mentioned in the following section.

Open-Flow, Non-Equilibrium Coacervate Hypothesis Meets Optofluidics
Our early assumption had to be remodeled when we came across optofluidics-that is an influential combined concept, at least for us, between liquid-based microoptics and soft-matter based optical devices. A traveling light, massless photon energy source, enables to efficiently confine polarized light in the interior of a droplet in a fluidic medium. The confinement causes a recurring polarized light-matter interaction within the droplet and/or at the droplet-liquid interfaces. An extension from optofluidics to chiral optofluidics might be applicable to chirogenesis and photochirogenesis from (at least) 1 to 100 µm-sized colloidal particles, with a higher RI, by dispersing in a fluidic medium with a lower RI, although their RIs have to be tuned precisely. The medium is not restricted to fluidic media. Likewise, solidified media, such as glassy polymers and inorganic solids, are possible to use.
Linearly polarized light is a superposition of left (l-) and right (r-) circularly polarized (CP) light. The land r-CP-light carry angular momenta of integer spins (±h), respectively [193][194][195][196]. Previously, Ghosh and Fischer [193] and Silverman et al. [194] simulated that the optical rotation from chiral liquids is boosted by several orders of magnitude when a coupled geometry of multiple prisms is filled with optically active biomolecular liquids, such as limonene, carvone, and a mixture of camphorquinone and methanol. The concept of AAS with light, one of the curious topics in the present special issue of Symmetry [197], is classified to: (i) absolute asymmetric photosynthesis; (ii) photodestruction; and (iii) photoresolution [47][48][49].
According to a theory led by Mortensen et al., the slow light of colloidal particles, by filling with a liquid medium, could enhance the CD signal at the edges of the optical band gap [195,196]. This theory is verified by enhanced ORD signals in a fluidic medium with a tuned RI. ORD spectroscopy allows us to detect differences in light speeds between land r-CP light as a function of incident light. In an analogy of the ORD signal enhancement, one can assume that CD spectrum as a function of wavelength of incident land r-CP light is possible to detect enhanced differences in light speeds between land r-CP light when optically active colloids are dispersed into a proper liquid medium by solely tuning RI.

Steady-State CD and CPL Spectroscopies
Steady-state CPL spectral datasets tell us information of the short-lived chiral species in the photoexcited state, while steady-state CD and ORD spectral datasets indicate long-lived chiral species in the ground state. Here we applied Kasha's rule and Jablonski diagram [216,217] to the nature of optically active luminophores and chromophores ( Figure 1). The short-lived species (S 1 , S 2 . . . ) upon excitation of unpolarized light are generated on the timescale of~10 −15 s based on the Franck-Condon principle [218]. The shortlived species, followed by non-radiative relaxation processes with vibrational modes, relax spontaneously to the lowest vibronic state (S 1 with υ' = 0), such as the metastable photoexcited state at the time scales of 10 −11 -10 −12 s. Finally, a spontaneous relaxation occurs from the low-entropy handed S 1 -state (υ' = 0) to the high-entropy, non-handed S 0 -state (υ = 0, 1, 2 . . . ), proven by CPL signals with a lifetime of 10 −9 -10 −6 s. Absolute temperature of 300 K equals to 0.60 kcal mol −1 (0.0259 eV and 208 cm −1 ). When luminescent molecules and polymers are photoexcited at 400 nm in a vacuum, the 400 nm light energy corresponds to 35,970 K (3.10 eV, 71.5 kcal mol −1 , 25,000 cm −1 ). CPL/CPLE and CD/ORD spectroscopy, thus, allow to dictate different chiral information in the photoexcited and ground states, respectively. Although CPL signals dictate a temporal short-lived chiral species at 35,970 K, CD and ORD spectral data provide information of long-lived chiral species at 300 K. When one can ensure the identity chiral species in the ground and photoexcited states, enantiomeric pairs of rigid luminophores and rigid chromophores are needed to restrict by intra-/intermolecular rotations at 35,970 K. Optically active luminescent colloids are candidates to design WGM-based chiroptical resonators between a pair of (+)-and (−)-CIE-CPL signals.  [212,[216][217][218] of chiral σ-/π-conjugated chromophores with/without rotational freedom in the absence of optical resonator, whispering gallery mode (WGM), and optofluidic effects. Singleheaded arrow stands for restricted rotation clockwise (CW) or counter-clockwise (CCW); doubleheaded arrow indicates a free rotation CW and CCW. Modified from an original article [199] and a book chapter [212].
This idea predicts that, although a non-rigid chiral luminophore arising from substantial rotational freedom in the ground state does not reveal detectable CD and weak CD signals known as cryptochirality, the luminophores does not emit clearly CPL signal, and emits, apparently, no detectable CPL with the corresponding unpolarized PL due to an equal probability of leftand right-hand chiral structures in the photoexcited state. However, if a non-rigid chiral luminophore produces certain chiral colloids induced by the restricted rotational freedom, one can detect the spatiotemporal chiral colloid as CIE-CPL signal as well as CIE-CD and CIE-ORD signals. One can detect steady-state CIE-CPL signals because the lifetime of the spatiotemporal species is on the order of ≈1-10 ns.
One may question whether the chiral optofluidics is valid for CIE-CD and CIE-CPL beyond an extension of AIE-CPL and AIE-CD. To prove the idea that the concept is generally applicable to a wide range of colloidal system suspensions in the fluidic media, we had to elucidate whether the chiroptical amplitudes in the resulting CD and CPL signals from several colloidal polymers were resonantly enhanced at specific RI values of the surrounded media. However, we had to consider serious concerns of the suspension heterogeneous systems. This is because anisotropic films and the vortex flowing from the chromophores and luminophores often cause unfavorable chiroptical artifacts and apparent sign inversion, as well as alteration in the absolute magnitudes in the CD and CPL signals [186]. To practically solve these artifacts, the use of optically anisotropic colloids dispersed in isotropic fluidic medium is one candidate. This approach is routinely applied to artifact-free CD and CPL spectral measurements by dissolving optically anisotropic molecules by dissolving in isotropic solution, although inherent anisotropic molecular information is lost. This is similar to routinely obtaining a solution of 1 H-and 13 C NMR spectra to measure highly anisotropic molecules in homogeneous solutions by rotating sample tubes and solid-state 13 C NMR spectrum of an anisotropic solid sample, by rapidly rotating sample tubes with a magic angle (54.7 • ) to cancel anisotropic terms.
Therefore, extremum wavelengths, chiroptical amplitudes, and signs in CPL/CPLE/CD/ORD signals, as well as those in PL excitation (PLE) and PL signals are not significantly affected by Rayleigh-Mie scatterings in proportion to λ −4 (λ: wavelength of light in a vacuum). The scatterings often cause an unfavorable increment and apparent spectral shift embedded into the background UV-visible spectrum. Instrumental knowledge is crucial to characterize inherent chiroptical signals from optically active colloids in the ground and photoexcited states. It is noted that the RI value alters as a function of wavelength. ORD spectroscopy can measure the difference in RI between left (l)-and right (r)-CP light. Unpolarized light is a superposition of r-CP and l-CP light. Fine tuning RIs of colloidal particles and the surrounding medium is key when the idea of the chiral optofluidics is applied to CIE-driven chiroptical enhanced signals. We showcase several examples in the following sections.

Gigantic Enhanced CD, ORD, and CPL from Colloidal Optically Active Helical Poly-silanes-Importance of Controlled RI in Optofluidic Medium
Herein, we showcase, for the first time, a clear example that a precisely controlled RI of the surrounding medium, which is the essential concept of optofluidic, is critical to boost CIE-CD, CIE-ORD, and CIE-CPL signals for colloidal particles of several helical polysilanes. We tested poly{p-(S)-2-methylbutoxypheneyl-n-propylsilane} (1S) [219], poly(n-decyl-(S)-3-methylpentylsilane) (2S) [220] poly(n-decyl-(S)-2-methylbutylsilane) (3S) [221], poly(n-dodecyl-(S)-2-methylbutylsilane) (4S) [21,199,221], and poly(n-dodecyl-(R)-2-methylbutylsilane) (4R) [21,199] (Figure 2). Poly(n-hexyl-(S)-2-methylbutylsilane) (5S) [208][209][210]222,223] and poly(n-hexyl-(R)-2-methylbutylsilane) (5R) [208][209][210]222,223] were used as helical scaffoldings of producing chiral co-colloidal particles with several optically inactive π-conjugated polymers. First, we highlighted the colloidal 3S as a function of RI value of the surrounding cosolvents, by assuming that RI value of the colloidal 3S is n D ≈ 1.7 [199]. The CIE-CD, CIE-ORD, and CIE-CPL spectra of the 3S are shown in Figure 3a-c. From Figure 3a, the 3S clearly shows negative exciton couplet CD bands at the lowest Siσ-Siσ* band at 323 nm. The Kuhn's dissymmetry ratio in the CD spectrum (g CD ) attain −0.31 at 325 nm and +0.33 at 313 nm, respectively. These g CD values are comparable to ≈16% left (l)-circular polarization and ≈17% right (r)-circular polarization, respectively, while pure land r-circular polarizations are g CD = ±2.0, respectively [224]. (d) The Kuhn's dissymmetry ratio in the CD spectrum (g CD ) of the colloidal 3S, 4S, and 4R as a function of refractive index (RI) in methanol-tetrahydrofuran (THF) cosolvents. The CIE-CD and CIE-CPL spectra are normalized by Kuhn's dissymmetry ratio in the ground and the photoexcited states [212,224,225]; (e) Schematic Jablonski diagram of the 3S; (f) a possible explanation for the CIE-CPL by confining left (l)-and right (r)-circularly polarized (CP) light in the 3S in optofluidic medium with a tuned RI [199]. Modified from an original article [199] and a book chapter [212]; (g) incident UV light at~0 • of the cuvette surface travels a very dilute CHCl 3 solution of stilbene 420 upon excitation of unpolarized light at 350 nm of cylindrical quartz cuvette (22 mm in diameter, 1 mm in thickness of cell wall, 10 mm in cuvette optical path); (h) incident light at~50 • of the cuvette surface infinitely travels the stilbene solution, undergoing to WGM by four-time reflections per one-cycle at the CHCl 3 -quartz interfaces. Figure 3b, the colloidal 3S clearly shows negative bisignate ORD spectra at the 323 nm Siσ-Siσ* transition. The traveling light speed of r-CP at 330 nm significantly slows down compared to the traveling speed of l-CP light at 320 nm. Likewise, a traveling speed of l-CP light at 320 nm slows down relative to the traveling speed of r-CP light at 320 nm. Therefore, the relative RI value between rand l-CP light largely relies on wavelengths of incident light. A higher RI value results in slower CP-light along with shortening of wavelength because the wavenumber is unchanged, regardless of RI, by the conservation law of light energy.

As shown in
The 3S showed clearly single (−)-CPL signal at the 330 nm PL band associated with a small Stokes' shift of 466 cm −1 , as depicted in Figure 3c. This small Stokes' shift indicates a very minimal structural reorganization owing to a very restricted rotational motion in the colloidal 3S in the photoexcited state. The magnitude of g CPL attained −0.65 at 330 nm, corresponding to ≈33% r-circular polarization, whereas the ideal land r-circular polarization in the photoexcited state occurs at g CPL = ±2.0, respectively [225].
Both CIE-CD and CIE-CPL characteristics of the 3S are nearly similar to those of the 4S and 4R. Notably, the CIE-CD and CIE-CPL characteristics of the 3S, 4S, and 4R boost at the very specific n D of mixed solvents of methanol and tetrahydrofuran (THF) (Figure 3d). The g CD value of the 3S is resonantly boosted at n D = 1.374, which is a specific volume fraction of the cosolvent. Likewise, the g CD values of the 4S and 4R are resonantly boosted at n D = 1.359 and n D = 1.365, respectively. The n D dependent chiroptical resonance effects are an evidence of the chiral optofluidics, where noticeable differences in a traveling light speed between land r-CP in the µm-scale colloids in the ground state is evinced by tuning n D of a liquid medium. The resonance effects are responsible for CIE-CD signals, followed by CIE-CPL signals in the photoexcited state.
From Figure 3a-c, a modified Jablonski diagram with chirality of the 3S associated with the Kasha's rule and exciton coupling theory is schematically illustrated in Figure 3e [199]. With the aid of the chiroptical resonator for selective lor r-CP light, a large difference in the RI between lor r-CP light is crucial.
In Figure 3f, we provide a plausible explanation for the CIE-CPL occurring in an optical resonator as a recurring WGM mode endowed with an efficiently confining land r-CPL in the 3S with a high RI surrounded by optofluidic medium with a lower RI [199]. The optically active spherical colloids should work as chiroptical resonator for the respective land r-CP light. As a result, efficient separation between land r-CP light as radiation from the colloids is realized. Internal total reflection modes (Brewster angle and recurring numbers) at the colloid-liquid interface should be kept in mind.
Firstly, unpolarized light at 317 nm (3.90 eV), which is an equal mixture of land r-CP light, excites simultaneously the colloidal 3S with a high n 2 surrounded by the liquid with a lower RI. The RI value of l-CP light, n 1 (l), at 317 nm is higher than that of r-CP light, n 1 (r), at 317 nm. The respective n 1 (l), n 1 (r), and n 2 are assumed to 1.8, 1.6, and 1.4. By Snell's law, the respective critical angles of refraction (θ c ) for land r-CP light are evaluated to 51 • and 61 • . The difference in the θ c angles of land r-CP light, thus, efficiently acts as chiroptical filter between land r-CP light at the colloid-liquid interface, such as a quarter-wave plate toward unpolarized light.
For clarity and visibility of the WGM concept, we demonstrate how an incident light travels interior of the µm-size colloidal resonator using two macroscopic models consisting of a fused quartz cylindrical cuvette with optically smooth surfaces (22 mm in diameter, 1 mm cell wall in thickness) filled with a very dilute CHCl 3 solution of stilbene 420, which is a sky-blue-color luminophore, upon excitation of unpolarized light at 350 nm. The cm-size cylindrical cuvette is a cross-section model of a µm-size colloidal sphere shape. The macroscopic demonstration is a zoom-in model of light-matter interaction occurring in a µm-scale resonator to persuade non-specialists.
From Figure 3g, the incident UV light at~0 • of the cuvette surface to excite stilbene 420 travels straightly and emits from the opposite side of the cuvette. In this case, only one-time interaction of light with the luminophore is possible. On the other hand, it is obvious from Figure 3h that, when an incident light at a very specific angle of~50 • of the cuvette surface, the light reflects four times per one-cycle at the CHCl 3 -quartz interface and undergoes into the WGM with the traveling light circulation mode. This recycling enables the incident light to infinitely interact with the luminophore, if attenuation by the absorbing light is neglected. One can expect that endless light-matter interactions are possible, thus, causing significantly boosted chiroptical signals in the ground and photoexcited states.
When open-flow, µm-size colloidal polymers with a smooth surface adaptable to the external physical and chemical biases are surrounded by an optofluidic medium, subtle chiral physical forces and chiral chemical sources are enhanceable by huge numbers of recycling times (N) in the optofluidic colloidal polymers, in line with the scheme of WGM. This means that a subtle left-right imbalance interior of the colloid, e.g., 10 −6 % ee, is boostable by 10 −6 × N. This scenario is contrast to a conventional stereochemistry, photochemistry, and photophysics in homogeneous solution systems, in which the lightmatter interaction occurs one chance (N = 1) only. When aggregation-induced emission systems chiroptically fulfil the resonance condition, one can anticipate the significant enhancements in CPL and CD signals.
The recycling light should occur even at the µm-size colloidal polymers that fulfil the resonant condition with relative RI values, between the polymers and fluidic medium. However, practically, the colloidal shape may not be an ideal sphere with an optically smooth surface, and an irregular shape with an optically rough surface diminishes this booster effect. The concept of WGM at the colloid-liquid interface, satisfying a resonance condition, along with specific RI values is applicable to boost chiral light-matter, lightchiral matter, and chiral light-chiral matter interactions.
To design the light recycling at the colloid-liquid interface, fine tuning RI at the specific wavelengths of the liquid medium is essential. It should be noted that RI values vary as a function of wavelength in a vacuum. This unique idea is valid for any optically opaque system, of chromophores and luminophores, in a heterogeneous medium, but is not applicable to optically transparent, homogeneous solutions. If the RIs between the colloid and surrounding medium are, by chance identical, any refraction, any reflection, and any scattering at the colloid-liquid interface do not occur. One can say that the colloidal mixture is optically transparent. The representative example is optically transparent pellet of poly(4-methyl-1-penetene (TPX ® , Mitsui Chemicals (Tokyo, Japan)). This transparency arises from the nearly identical RIs of crystalline and non-crystalline phases of TPX ® .
The traveling light speeds of land r-CP in the colloidal polysilanes at 317 nm slow down to 1.67 × 10 8 ms −1 and 1.88 × 10 8 ms −1 , respectively. However, the wavelengths of the incident land r-CP light in a vacuum shorten to 176 and 198 nm in the colloid, respectively. As a result, the incident 317 nm l-CP light results in a greatly shortened l-CP light of 176 nm. Similarly, the incident 317 nm r-CP light becomes a slightly shortened light of 198 nm. If the 176 nm slow-down l-CP light was employed, multiple total internal reflections occurred efficiently (for example, 12 times) in the colloids compared to that of the slow-down 198 nm r-CP light. Increasing the number of total internal reflection (TIR) of CP light at the colloid-liquid interface meets the greater opportunity of chiral light-matter interactions. The recurring multiple TIR process at the colloid-liquid interface is an important step.
The slow-down 317 nm l-CP light relaxes to the 330 nm r-CP light along with a change in CD sign within the colloids. The faster 317 nm r-CP light migrates to the 330 nm r-CP light without significant change in the CD sign. Owing to a great suppression of the 325 nm l-CP light, the slow-down 330 nm r-CP light emits dominantly from the S 1 state with an apparent minimal Stokes' shift. This explanation is verified by the ORD spectrum in the fluidic medium with the tuned n D (Figure 3c). The ORD spectrum, as a function of the incident wavelength of land r-CP light, can detect differences in traveling light speed between land r-CP in an optically active colloidal particle.

Controlled Chirogenesis from Optically Inactive Helical Polysilanes Endowed with Limonene Chirality
Optically active, colloidal helical polysilanes are instantly generated by solely adding poor solvent to a homogeneous solution of optically active helical polysilanes carrying chiral substituents [219]. This approach is, however, inevitably needed to use expensive chiral biomolecular and artificial sources and multiple synthetic steps when we intend to introduce chiral substituents to Si-Si backbone [219][220][221][222][223]. Herein, we showcase a facile, inexpensive, environmentally-friendly approach to instantly generate CIE-CPL and CIE-CD signals of colloidal polysilanes from optically inactive helical polysilanes in a minute (Figure 4) [200,226]. Herein, the authors used artificial chiral alcohols and biomolecular chiral solvents for chirogenesis of colloidal σand π-conjugated polymers ( Figure 5) [198][199][200][201][202][203][204][205][206][207]212].  Previously, we reported that optically inactive colloidal helical 6 exhibits couplet-like CIE-CD by transferring molecular chirality of (S)-and (R)-1-phenylethyl alcohols and other chiral alkyl alcohols when these chiral alcohols were used as solvent quantities [226]. It should be noted that 6 homogeneously dissolved in the alcohol solutions, adopting a CD-silent racemic helical state arising from a dynamic twisting between the left-and right-helices in a low energy barrier height in a double-well. By adding a poor solvent (methanol), CD-silent 5 generates CIE-CD effect from the colloidal 6 arising from mirror symmetry breaking (MSB). In this case, the resulting CD sign is determined solely by the chirality of alcohols used. It was driven by solvent molecules. The handed chiral CH/O interaction is responsible for the CIE-CD (Figure 4) [226]. We, at that time, however, were not aware of the RI dependency of the chiral alcoholic solvents because any ideas of optofluidics, optical resonator, confinement of chiral light, and chiral optofluidics were lacking.
The CIE-CD and the corresponding UV spectra of the colloidal 7 and 8 are shown in Figure 6a,b. In the 7, dispersed in 10R-based tersolvent, the g CD amplitudes at the bisignate CD spectra boosted to +0.022 at 327 nm and −0.031 at 309 nm, respectively [200]. As expected, the 7 in 10S-based tersolvent gave the mirror-symmetric g CD amplitudes with −0.021 at 327 nm and −0.033 at 309 nm, respectively [200]. The CIE-CD values of the 7 are comparable to those of the 9, but those in the 8 decreased by the magnitude of one-third. The bisigned g CD values of the 8 in 10R-based tersolvent were −0.007 at 331 nm and +0.010 at 317 nm, respectively. Conversely, the 8 in 10S-based tersolvent gave the mirror-symmetrical g CD values of +0.005 at 331 nm and −0.007 at 317 nm, respectively. The degree of circular polarization of the 7, 8, and 9 was, however, not intense on the order of 1.0-1.5%. The absolute magnitudes of the CIE-CD values of the 7, 8, and 9 are greatly dependent of M w . A representative M w dependent g CD values from the 7 is given in Figure  6c. The specific 7 with M w = 2.7 × 10 4 afforded the greatest g CD value; 8 and 9 had similar M w -dependency of the CIE-CD effects [200].  [200] and the book chapter [212]. 7, 8, and 9 showing weaker g CD values, only the 8 and 9 revealed weaker CIE-CPL associated with the absolute value of g CPL , |g CPL | ≈ 0.005 (Figure 6d) [200]. The 7 did not emit any PL due to unresolved reasons, thereby, revealed no detectable CPL signals. From Figure 6a,b, the CD sign of the 7 is opposite of that of the 8 when the same limonene chirality was applied. However, the CD sign of the 7 inverted at the specific n D = 1.35 of the 10R-and 10S-based tersolvents (Figure 6e). The unchanged CD sign of the 8 showed an abrupt increment at n D = 1.41 (Figure 6f). Thus, subtle structural alterations in achiral alkyl side chains of helical polysilanes significantly affect the amplitudes and chiroptical sign of CD and CPL signals.
The g CD value of the 11 is resonantly boosted at n D = 1.44 of the limonene-containing tersolvent (Figure 8d). Notably, the g CD value varies extraordinary in response to the ee value of limonene, exhibiting the so-called, negative cooperative effect (Figure 8e). The negative cooperativity indicates that enantiomerically pure limonene chirality is needed to attain the highest g CD value. Moreover, we are aware that the g CD value increases as the colloidal size increases (Figure 8f) [198]. A larger size of the colloidal particles fulfils morphology-dependent resonance condition in the WGM-origin chiroptical resonators known as cavity quality, indicated by theories [227,228] and experiments [229,230].

Fully Controlled Absolute Photochirogenesis from Achiral π-Conjugated Polymers Endowed with Excitation Wavelength Dependent Circularly Polarized Light Chirality
The colloids exhibiting significantly boosted CIE-CD and CIE-CPL signals are instantly generated at room temperature with help from limonene with (S)-and (R)-chirality from optically inactive σ-/π-conjugated polymers. The g CD and g CPL signals are resonantly boosted at the specific RI of the optofluidic media. These results encourage us to further investigate a possibility of AAS with light or APC from two optically inactive colloidal 13 [55] and 11 [54] by dispersing to achiral solvents with a very specific RI endowed with CP light chirality (Figure 9). Recently, we demonstrated that the controlled APC with CP light (CAPC) from achiral colloidal polymethacrylate carrying azobenzene 21 in a tuned achiral cosolvent is possible by CP light, with wavelength and sense as purely chiral physical force [56] (Figure 8). We had confidence that, in the colloidal systems of 11, 13, and 21, a hand of CP light is not a deterministic factor for their product chirality and that both a hand and an excitation wavelength of CP light are subject for the CAPC with CP light.

Achiral π-Conjugated Polymer Containing Azobenzene Unit as a Backbone Endowed with Circularly Polarized Light Chirality
In this section, we demonstrate that CAPC operated in the RI-tuned optofluidic medium is efficiently realized when wavelength-controlled rand l-CP light is employed as chiral electromagnetic force. The CAPC conducted by achiral optofluidic medium enables all chiroptical polarization (chirogenesis), depolarization (racemization or chiroptical erase), inversion (anti-chirogenesis), retention (memory), and switching in the µm-size colloidal 11, 13, and 21 (see, later Section 4.5.3), as evidenced by their CIE-CD and CIE-CPL spectral characteristics.
As mentioned in Section 1.2.1, LeBel and 1894, van't Hoff proposed AAS with rand l-CP light. Kuhn and Broun proved their idea as a photodestruction mode of AAS [46]. Their works prompted researchers to catalyze AAS study for a century because expensive chiral chemical substances are no longer needed [47][48][49][231][232][233]. Possibly, most researchers might concur that l-CP light produces left-hand (or right-hand) molecules preferentially, or vice versa, because the product chirality is determined solely by the hand of CP light. The author was one of the researchers.
In Figure 10a,b, the CIE-CD, CIE-ORD, and UV spectra of the colloidal 13 are displayed when rand l-CP light source is excited at 436 nm [54]. The bisignate g CD values at the first and second Cotton bands are −0.025 at 500 nm and +0.021 at 367 nm for r-CP light, respectively [54]. Conversely, they are +0.025 at 509 nm and −0.027 at 364 nm for l-CP light, respectively. The 13 with negative-couplet CIE-CD upon excitation of r-CP light at 436 nm results in nearly zero CIE-CD signals upon excitation of l-CP light at 436 nm for 5-10 min (Figure 10c). A prolonged excitation of l-CP light for 51 min led to an ideal, mirror-symmetric, positive-couplet CIE-CD signal (Figure 10c). An alternative excitation between rand l-CP light sources enables chiroptical inversion and switching between the positive-and negative-couplet CIE-CD signals [54]. It should be noted that 13 and unsubstituted azobenzene dissolved in dilute homogeneous CHCl 3 solutions are weakly emissive. The 13, however, does not reveal any detectable CIE-CPL and PL spectra due to aggregation-caused quenching mechanism [187]. We are aware of an anomaly of an apparent chiroptical inversion for the product chirality of 13 when excited at 313 nm with the same l-CP light source; the positive-sign, weak CD signals excited at 313 nm only, while the negative-sign, intense CD signals upon excited at 365 nm, 405 nm, 436 nm, 549 nm, and 577 nm (Figure 10d). Likewise, under the same r-CP light excitation, the product chirality at 313 nm is opposite to that at 365 nm, 405 nm, 436 nm, 549 nm, and 577 nm.
The Arrhenius plots of the colloidal 13 and unsubstituted azobenzene during cis-trans thermal isomerization indicates that the activation energy (E a ) from cis-13 to trans-13 in a CHCl 3 -methanol cosolvent is E a ≈ 22 kcal mol −1 [54,121], which is slightly higher than that of the unsubstituted azobenzene of E a ≈ 18 kcal mol −1 (Figure 10e). The higher E a value of the 13 contributes to the long-term chiroptical retention memory at ambient temperature. Likewise, from the Eyring plot that indicates the activation enthalpy (∆H ‡ )-activation entropy (∆S ‡ ) relationship, the thermally excited cis-trans isomerization of azobenzene moieties in the 13 should obey the rotation mechanism rather than the inversion one [54,234]. The rotation mechanism arises from restricted rotational freedom of azobenzene moieties in the colloids. Thus, the chirality of rand l-CP light can efficiently drive all of the chiroptical modes; generation, inversion, erase, switching, and short-term/long-term memory.
The thermal chiroptical stability of the 13 largely depends on the structure of the alcoholic solvents used (Figure 9). The g CD value of the 13 in methanol gives the shortest lifetime of 4-5 h. The g CD values in other non-branched alcohols and isopropanol diminishes in two days (Figure 10f). Notably, the g CD value in isobutanol remains unchanged for at least two days. The proper choice of alcohols allows for the efficient generation and desired retention times of the chiroptical properties.
In the 13 systems, we re-emphasize that the precisely controlled RI in the alcohol-CHCl 3 cosolvents is key for the CIE-CD signals disregard of the non-branched and branched alcohols (Figure 10g,h). Using either ror l-CP light as a chiral electromagnetic force, the absolute g CD values, |g CD |, of the 13 are resonantly enhanced at a specific n F value-that is, RI at 486.1 nm; n F = 1.382 for methanol, 1.404 for ethanol, 1.410-1.412 for n-propanol, 1.418 for n-butanol, 1.426 for n-pentanol, 1.405-1.411 for isopropanol, and 1.415 for isobutanol.

Achiral Luminescent π-Conjugated Polymer Endowed with Excitation Wavelength Dependent Circularly Polarized Light Chirality
The knowledge of the non-emissive colloidal 13 with azobenzene moiety led us to design the CAPC of the colloidal polymer made of highly luminescent 11 lacking photochromic moieties upon excitation of rand l-CP light sources at six different wavelengths (313 nm, 365 nm, 405 nm, 436 nm, 549 nm, and 577 nm). The CAPC behaviors are readily characterized by the CIE-CPL and CIE-CD spectra. Figure 11a,b displays the CIE-CD and UV spectra of the colloidal 11 by exciting the two different l-CP light sources at 546 and 365 nm and by the two different r-CP light sources at 546 and 365 nm, respectively. Unexpectedly, it is obvious that the positive-couplet CD spectrum endowed with the 546 nm l-CP light source inverts to negative-couplet CD of the 365 nm l-CP light source. Likewise, the negative-couplet CD spectrum induced by the 546 nm r-CP light source becomes positive-couplet CD when the 365 nm r-CP light source is applied. An excitation of CP light at 313 and 405 nm shows a similar tendency as the 365 nm excitation, while an excitation of CP light at 436 nm and 577 nm reveals a similar tendency as the 546 nm excitation. Upon excitation of the same l-CP (or r-CP) light, the choice of shorter (UV) and longer (visible) wavelengths of CP light causes an inversion of chiroptical sign of the 11. Thus, we conclude that, the hand of CP-light, whether left or right, is not a deterministic factor for the CIE-CD sign of the 11. Figure 11c displays a comparison between the CIE-CPL and PL spectra of the 11 upon excitation of the 546 nm land r-CP light sources. A positive couplet-like CPL spectrum led by the 546 nm r-CP light source and negative-couplet-like CPL spectrum induced by the 546 nm l-CP light source is obvious. The absolute magnitude of g CPL , |g CPL |, is approximately 10 −3 . Upon excitation of r-CP light, the colloidal 11 reveals weak (+)-CPL at 570 nm arising from the 540 nm (+)-CD band, while the colloids showed a weak (−)-CPL signal at 518 nm, originating from the 380 nm (−)-broad CD signal. A tandem controlling hand and photoexcited wavelength of the CP light source allowed for the production of CPL-functioned 11 with φ = 8% and |g CPL | = (2 − 4) × 10 −3 at 540 nm. The (+)-CIE-CD of the 11 generated by the 546 nm r-CP light for 30 nm irradiation completely inverted to negative-couplets solely by the 54 nm l-CP light for a prolonged irradiation of 120 nm, as shown in Figure 11d. In other word, angular momentum (±h) of massless photon chirality enables to non-photochromic colloidal substances, resulting in induction and inversion of chemical chirality from achiral substances at ambient temperatures. Evidently, by optofluidically tuned RI of the achiral cosolvents, the CP light-driven CIE-CD signals of the 11 resonantly boosted at n D = 1.412 disregard of rand l-CP light as excitation sources (Figure 11e).  [55] and the book chapter [212].
The CIE-CD spectra of the 11 are thermally stable and remain unchanged at 25 • C for at least seven days (Figure 11f). For comparison, non-colloidal 11 homogeneously dissolved in CHCl 3 solution does not provide any detectable CD signals before and after prolonged irradiation of the 546 nm r-CP light. The largely restricted rotational freedom associated with efficient confinement of the CP light source in the colloid as the optical resonator is essential in conducting CP light-driven CAPC experiments.
According to a theoretical study [235], chiroptical enhancement is possible when an ideal chiral sphere efficiently interacts with the surrounding chiral molecules. This means that the CIE-CPL and CIE-CD signals from the colloids are further enhanceable by tuning chiral fluidic medium. CP light is key in the migration and delocalization of photoexcited energy in optically active macro-colloids containing ∼10 8 of chlorophyll upon excitation of unpolarized sunlight [171][172][173][174]. Note that chlorophylls contain three stereogenic centers at the peripheral positions of chlorophyll rings and two stereogenic centers in the alkyl chain tail.

Achiral Polymethacrylate Carrying Azobenzene Pendants Endowed with Excitation Wavelength Dependent Circularly Polarized Light Chirality
The concept of CAPC with light covers absolute asymmetric photosynthesis, photodestruction, and photoresolution. In the 1970s, Calvin et al. reported an anomaly of an excitation wavelength dependent CP light-driven photosynthesis-mode AAS recognized as switching product chirality of [8]-helicene in homogeneous toluene solution [52]. In 2014, Meinert et al. reported the wavelength dependent CP light-driven photodestruction-mode AAS revealing switching chirality when rac-alanine film is decomposed upon irradiation of two vacuum-UV light sources (184 and 200 nm) [53]. Our results of CAPC from the 14 and the 11 as their colloidal states prompted to address an apt question, as to whether the excitation wavelength dependent switching chirality conducted by CP light-driven photoresolution mode AAS is generalizable; whether restricted rotational modes are crucial for CP-light driven CAPC [56].
We chose the colloidal 21 bearing achiral azobenzene moieties as pendants to test the excitation wavelength dependent CP light-driven photoresolution mode AAS ( Figure 12). The experiment of CAPC with light was designed to use three wavelengths (313 nm, 365 nm, 436 nm) for rand l-CP light sources to efficiently excite π-π* and/or n-π* transitions of azobenzene moieties in restricted rotational states in the 21. Contrarily, the azobenzene moieties are non-restricted, free rotational states in homogeneous solution. Similarly, restricted rotations along C-C single bonds in the main chain of 21 are possible in the colloids, while non-restricted rotations of those C-C single bonds occur in homogeneous solutions. In Figure 13a, we show the values of CD ellipticity at 313 nm (in mdeg, left ordinate) and g CD at 313 nm (right ordinate) of the spherical shape colloidal 21 (125- Figure 13b, the 365 nm r-CP light source induces bisignate negative-couplet-like CD profile at 310 nm and 360-390 nm, conversely, the 365 nm l-CP light induces bisignate positive-couplet-like CD profile. Likewise, the 436 nm r-CP light source induces similar bisignate negative-couplet-like CD profile, as shown in Figure 13d. Conversely, the 365 nm l-CP and the 436 nm l-CP light sources induce bisignate positive-couplet-like CD spectra (Figure 13b,d). On the other hand, it is evident from Figure 13c that the 313 nm r-CP and l-CP light sources induce bisignate positive and negative couplet-like CD profiles at 310 nm and 360-390 nm, respectively. For comparison, the 436 nm r-CP light-driven CAPC experiments to the colloids made of the starting monomer of 21 in MCH-DCE and 21 in homogeneous DCE solution did not induce any detectable CD signals [56].
These excitation-wavelength dependent CAPC experiments allow to verify a possibility of all chiroptical generation, erase, inversion, multiple switching, and a long-term memory characteristics of the 21 in the optofluidic medium with the n D = 1.425 using land r-CP light sources at 313 nm (Figure 13e We re-confirmed that an alternative excitation of the 313 nm l-CP and 436 nm l-CP light sources to the 21 enables conducting all of the chiroptical modes. Likewise, the alternative excitation of the 313 nm r-CP and 436 nm r-CP light causes the opposite characteristics of the dual l-CP light sources. The resulting optically active 21 endowed with the 365 nm r-CP and l-CP light sources had long-term memory effects in the dark for at least seven days (Figure 13i). This uniqueness arises from the very restricted rotations of the azobenzene moieties and the C-C single bonds in the main chain of the 21 in the dark (Figure 12, left). The 16 in the ground state is a closed system that endures thermally activated energy at room temperature. Conversely, the 16 in the photoexcited state during CP-light irradiation works as the open-flow, soft-matter-based photonic resonator adaptable to the external CP-light energy by confining into the resonator with the help of the tuned RI fluidic medium.
From the spectra shifts at the three major bands of the 21, which includes υ(C-H) at 3000 cm −1 , υ(C = O) at~1730 cm −1 , and υ(C-O-C) at~1250/~1150 cm −1 , a prolonged photoirradiation with r-CP at 365 nm for 10 min leads the 21 with trans-azobenzene pendants to cis-azobenzene 21 colloids. As a result, the cis-colloidal 21 prevents an efficient π-π stacking of azobenzene pendants, followed by production of an ill-organized, smaller size colloids due to a bent structure of cis-azobenzene. The cis-21 colloids in the cosolvents were transparent by the naked eye. The small size colloids, less than~100 nm, appear inconvenient to efficiently confine a traveling light at the colloid-liquid interface and prevent the multiple reflection mode of WGM.
In Figure 13j, we propose a hypothesis of the anti-Kasha rule that, by combining exciton couplet theory, Kasha's rule, Jablonski diagram, and x-y directions of azobenzene at the photoexcited state, two pathways as a spontaneous relaxation process from α-state (y-axis of azobenzene) with the lowest energy (~365 nm) and the β-state (x-axis of azobenzene) with higher energy (~313 nm) are possible. The r-CP light sources at 365 nm and 313 nm would make y-and x-axes of azobenzene twist CCW and CW, respectively. Likewise, l-CP light sources at 365 and 313 nm oppositely twist y-and x-axes of azobenzene CW and CCW, respectively [56]. The anti-Kasha rule is prominent to CP-light driven CAPC of colloidal 21, 11, and 14 in the RI-tuned optofluidic media. The anti-Kasha rule is applicable to characterize CIE-CD and CIE-CPL spectra in the controlled chirogenesis, as given in a Section 4.7.

Changes in Colloidal Sizes of Diaryl Polysilane with Propagation Time
In this section, we highlight two topics: (a) multiple resonance effects in the g CD value of the colloidal 21 in the 10R/CHCl 3 /MeOH and 10S/CHCl 3 /MeOH tersolvents among the colloidal diaryl polysilanes 21-24 ( Figure 14); and (b) tempo-spatial chirogenesis, including changes in colloidal sizes and CIE-CD signals at several volume fractions of 10R and 10S in the tersolvents with propagation time [207]. According to the polymer consistent force-field (PCFF), diaryl polysilane 21 has four local minima from the potential energy surface due to phenyl-phenyl interaction (Figure 15a). Thus, 21 in a homogeneous solution reveals a CD-silent spectrum in the ground state (Figure 15b), and possibly a CPL-silent spectrum in the photoexcited state due to equal populations between two P-screw and two M-screw Si-Si backbones.
The g CD values of the colloidal 21 show two and three extrema at the specific volume fractions of 10R/CHCl 3 /MeOH and 10S/CHCl 3 /MeOH tersolvents (Figure 15e,f). This anomaly appears not unique for the 21 because a similar tendency in the g CD -n D relations can be seen in the colloidal 14 ( Figure 8d) and the colloidal 7 and 8 in the limonenecontaining tersolvents (Figure 6e,f). The 21 at the optimized volume fraction of 10R and 10S in the tersolvents reveal clear bisignate CIE-CD spectra around 400 nm ( Figure 15c) associated with mono-signate CIE-CPL spectra at 410 nm ( Figure 15d). The (+)-sign CIE-CPL led by 10R is identical to th (+)-sign of couplet-like CIE-CD at the first Cotton band of 408 nm, conversely, the (−)-sign CIE-CPL with 10S is the same of (−)-sign of CIE-CD with 10S at 408 nm. The relaxation scenario from the S 1 to S 0 states of the 21 obeys the Kasha rule [216,217].
The reasons for two and/or three extrema in the g CD values at the specific volume fractions of 10R and 10S is ascribed to three rotamers of 10R (and 10S) [236,237]. Nonrigid chiral monocyclic terpene 10R consisting of isopropenyl group and cyclohexene ring has one freely rotable C-C bond between the moieties. The rotable C-C bond generates three equatorial rotamers of 10R (equatorial 1 (Eq1), equatorial 2 (Eq2), equatorial 3 (Eq3), Figure 16) with nearly equal populations with different ORD spectra with different signs in the range of 200-589 nm (Eq1; 0.39 with an intense (+)-ORD, Eq2; 0.31 with an intense (−)-ORD, Eq3; 0.30 with a weak (−)-ORD) along with a small fraction of energetically unstable axial rotamers [236,237]. We assume that the packing structure of 21 in the colloids is reorganizing in response to a preferential rotamer of 5R and 5S, whose fractions depend on a volume fraction of limonene in the tersolvents [207].  In Figure 15g,h, the tempo-spatial behaviors in the colloidal size of 21 at several volume fractions of 10R and 10S in their tersolvents are given by means of dynamic light scattering measurements. We can see the marked alteration in the colloidal sizes (200-900 nm) of 21 in the 10R and 10S tersolvents; the colloid sizes at two specific volume fractions (0.40 and 0.75 mL for 10R; 0.75 and 0.85 mL for 10S) appear unchanged with time, while those at other volume fractions seem to fluctuate and/or grow gradually with time. The resonant volume fractions in Figure 15e,f) are possibly connected to the tempo-spatial behaviors of the colloidal sizes, followed by the maximizing g CD values.

Time-Dependent Evolution of CIE-CD and CIE-CPL in Co-Colloids of Achiral π-Conjugated Polymer and Helical Dialkyl Polysilanes
Based on the tempo-spatial behaviors of the colloidal 21 endowed with 10R and 10S, we designed co-colloids comprising achiral π-conjugated 20 ( Figure 7) and rod-like helical dialkyl polysilanes, 5S and 5R (Figure 2). The optimized molar ratio as repeating units of 20 and 5R (or 5S) is found to be 1:1 (Figure 16h). The optimized n D value in the CHCl 3 -MeOH cosolvents enabling the largest RI value of the co-colloid is found to be n D = 1.405 in a cosolvent of CHCl 3 /MeOH = 1/2 (v/v) (Figure 17h). Note that the rigid rod-like helical 5R and 5S act as helical scaffolding to non-helical π-conjugated polymers.
The alterations of the CIE-CD/UV-visible-NIR spectra and the CIE-CPL/PL spectra of the 1:1 co-colloids of 20 and 5R as a function of propagation time are displayed in Figure  17a,b. Likewise, the changes in the CIE-CD/UV-visible-NIR spectra and the CIE-CPL/PL spectra of the 1:1 co-colloids of 20 and 5S with propagation time are given in Figure 17a,b. Obviously, the absolute magnitudes in CIE-CD and CIE-CPL increase and tend to level-off for a prolonged time of 24 h, regardless of 5R and 5S. The 20/5S and 20/5R co-colloids generate CD-activity and CPL-activity from optically inactive 20 with help from main chain helicity and/or side chain chirality of 5S and 5R. Time-dependent reorganization of 20, with help from 5R/5S in fluidic media occurs on the order of hours at room temperature.
To associate the g CD /g CPL values with the colloidal size, we characterized the timedependent co-colloidal sizes using a dynamic light scattering (DLS) method, as shown in Figure 17f,g. An approximately 650 nm size of the 20-5S co-colloids progressively reach 2000 nm within 24 h (Figure 17f). Likewise, an approximately 400 nm size of the 20-5R co-colloids in the beginning attains~1800 nm within 24 h (Figure 17e). The larger sizes of the co-colloids after prolonged propagation times are responsible for the increases in the larger g CD and g CPL values of the 20-5R and 20-5S co-colloids associated with a significant red-shift in CIE-CD and CIE-CPL spectra. It takes several hours to re-organize 20 with help from the Si-Si main chain helicity and/or side chain chirality of 5R and 5S. Figure 17. Alteration in the (a) CIE-CD and UV-visible-NIR spectra and (b) CIE-CPL and PL spectra excited at 400 nm for the 5S-20 co-colloids (1-to-1 molar ratio). Alteration in the (c) CIE-CD and UVvisible-NIR spectra and (d) CIE-CPL and PL spectra excited at 400 nm for the 5R-20 co-colloids (1-to-1 molar ratio). These co-colloids were produced in CHCl 3 -MeOH (2/1 (v/v)). The hydrodynamic sizes of (e) 5S-20 and (b) 5R-20 co-colloids with the propagation time; (g) the g CD value around 600 nm of the 20-5S co-colloid (1:1) as a function of n D in the CHCl 3 -MeOH cosolvent; (h) the g CD value of the 20-5S co-colloid as a function of the 5S-to-20 ratio generated in the CHCl 3 -MeOH (2:1) cosolvent. Modified from an original article [210].

Unveiling Anti-Kasha's Rule from CIE-CPL, CIE-CPLE, and CIE-CD in Co-Colloids of Achiral π-Conjugated Polymer and Helical Polysilanes
In this section, we deal with the origin of bisignate CIE-CPL associated with bisignate CIE-CD spectra characteristic of the co-colloids comprising 11 with 5R (1:1 mol ratio) and 11 with 5S (1:1 mol ratio) by connecting to the corresponding CIE-CPLE spectra based on a hypothesis of anti-Kasha's rule to explain the origin of dual CPL emission behaviors. Note that 5R and 5S can work as P-screw and M-screw helical scaffoldings in the range of 280-325 nm to achiral 11 in the range of 350-650 nm. Prior to a series of chiroptical experiments, the n D value of the CHCl 3 -MeOH cosolvents is optimized (Figure 18e); n D = 1.410 of the CHCl 3 /MeOH (2.1/0.9 (v/v)) cosolvent for 11/5R = 1:1 in mole ratio and n D = 1.415 of the CHCl 3 -MeOH cosolvent (2.2/0.8 (v/v)) cosolvent for 11/5S = 1:1 in mole ratio, respectively. Figure 18. (a) The CIE-CD and UV-visible spectra and (b) the CIE-CPL and PL spectra excited at 420 nm of the co-colloids of 11 with 5S and 5R in a 1-to-1 molar ratio; (c) The CIE-CPLE and PLE spectra of the co-colloids of 11 with 5S and 5R monitored at (d) 575 nm and (e) 490 nm (5R) in the CHCl 3 -MeOH cosolvent (2.2/0.8 (v/v)) and (d) 575 nm and (e) 495 nm (5S) in the CHCl 3 -MeOH (2.1/0.9 (v/v)); (e) the g CD value at 500 nm of the co-colloidal 11-5S (1:1) as a function of n D in the CHCl 3 -MeOH cosolvent; (f) A hypothesis of anti-Kasha's rule and Jablonski diagram to explain bisignate CIE-CD, CIE-CPL, and CIE-CPLE spectra of the colloidal 11 endowed with 5S. Modified from an original article [209]. Figure 18a,b depicts the CIE-CD/UV-visible and CIE-CPL/UV-PL spectra excited at 420 nm of the co-colloids consisting of 11/5R (1:1) and 11/5S (1:1), respectively. In Figure  18a, the weaker bisignate CIE-CD/UV spectra around 300 nm are attributed to Siσ-Siσ* transitions of 5R and 5S. In Figure 18a, it is obvious that the intense bisignate CIE-CD/UVvisible spectra at 400 and 500 nm are attributed to π-π* transitions of 11 led by 5R and 11 led by 5S, respectively. However, from Figure 18b, the intense bisignate, dual CIE-CPL bands associated with PL band located at 490 nm and 510-580 nm are assumed to originate from π-π* transitions of the colloidal 11 with 5R and 5S. One question is whether the bisignate CPL, not obvious from PL, arises from π-π* transitions at 400 nm and 500 nm from the colloidal 11. To answer this query, we obtained the first CIE-CPLE/PLE spectra monitored at 575 nm and at 480-480 nm (Figure 15c,d). The (+)-sign CIE-CPLE/PLE spectra of the 11-5R monitored at 575 nm are nearly identical to (+)-sign CD spectra of the π-π* transitions of the 11-5R in the range of 300-500 nm and vice versa (Figure 15c). Conversely, the (−)-sign CIE-CPLE/PLE spectra of the 11-5R monitored at 480-490 nm are nearly identical to (−)-sign CD spectra of the π-π* transitions of the 11-5R in the range of 300-450 nm and vice versa (Figure 15d).
These spectral results allow us to propose the anti-Kasha's rule, similar to Section 4.5.3. Two pathways of spontaneous relaxation processes from the β-state in higher energy (~400 nm) and the α-state with lower energy (~500 nm) are possible. The r-CP light in the range of 350 and 500 nm photoexcited the 11-5S (and 11-5R), followed by relaxation to the β-and α-states that emit r-CPL and l-CPL, respectively. On the other hand, the r-CP light at 500 nm photoexcited the 11-5S (and 11-5R), followed by relaxation to the α-states that emit l-CPL only. The photoexcited β-state with r-CP light has two relaxation pathways; from β-state with r-CP light and from α-state with l-CP light.
The rand l-CP light excitation processes, followed by spontaneous radiation processes, may not obey the conventional Kasha's rule, rather obey anti-Kasha's rule because dual CP luminescence characteristics are obvious. In recent years, anti-Kasha's rule became popular and is now a hot topic in the realm of photophysics and photochemistry when dual and multiple photoluminescence characteristics are observed [238][239][240][241]. Monitorwavelength dependent CPLE spectroscopy associated with the corresponding CPL and CD spectroscopy is helpful to investigate the anti-Kasha's rule in solutions and in the solid film, and as solid powders.

Perspectives-Colloids Connecting to Light, Helix, Coacervate, Panspermia, Microoptics, Chiroptics, Radioisotopes, Nuclear Physics, Biology, Homochirality Question, and Cosmology
With assumptions based on the coacervate and Panspermia hypotheses, and WGM in µm-size colloidal polymers adaptable to external chemical and physical stimuli in a tuned optofluidic media, one remaining issue should be to address the effects of chiral physical sources and particles existing in the interstellar universe and on Earth, possibly causing the biomolecular handedness on Earth.
First, the author wishes to mention personal experience in my graduate school four decades ago. In 1977, Kunitake and Okahata found that didodecyldimethylammonium bromide in water, the simplest amphiphilic synthetic molecule ( Figure 19, top left), spontaneously generates multilayer spherical colloids of~100 nm in diameter from observation of TEM [242]. Under supervision of Kunitake and his three lab staffers (Takarabe, Okahata, and Shinkai), the author designed four new achiral, amphiphilic acrylic monomers ( Figure 19, top right), polymerizable under influence of the β − -decay process from 60 Co→ 60 Ni nuclear fission reaction [243].
Among the four amphiphiles, AcC 10 C 12 N + 2C 1 Br in water, showing two phase-transition temperatures (T c s) at −16 • C and −9 • C, formed structureless colloids with no obvious multilayers, ranging from~10 nm to~100 nm in diameter (Figure 19a). Followed by polymerization of the colloids embedded to ice in the range of −30 • C and −50 • C with help from the β − -decay nuclear reaction, the author serendipitously observed that the spiral fibers of amphiphilic polyacrylate (~10 nm in diameter) are formed in many places. Possibly, handedness of spiral fibers was left-handed (Figure 19b-d). Polymerization was confirmed by significant shifts in IR frequency in υ (C=O) from 1715 cm −1 (monomer) and 1725-1730 cm −1 (polymer). Likewise, AcC 10 C 18 N + 2C 1 Br in water exhibited two phase-transition temperatures (T c s) at 28 • C and 41 • C. Colloidal AcC 10 C 18 N + 2C 1 Br polymerized at 45 • C influenced by the β − -decay reaction formed clearly loop-like structures (ca. 40-60 nm) made of spiral fiber (Figure 19e,f). The handed spiral loops from the polymerizable colloids by dosing handed electron, γ-rays, and anti-neutrino have very reminiscent circular DNAs and proteins/polypeptides influenced by high-energy cosmic rays under extraterrestrial and terrestrial conditions of primordial eons. Figure 19. (Top, left) Chemical structures of the first amphiphilic didodecyldimethylammonium bromide to spontaneously form spherical shape colloids (~100 nm) with multilayer membrane [242]. (Top, right) Four amphiphilic acrylic monomers synthesized by the author (1978) (unpublished as and English paper, disclosed only as his Master thesis [243]. A TEM image (negative statue) of (a) colloidal AcC 10 C 12 N + 2C1Br − (20 mM) (negative statue) dispersed in pure water; (b-d) TEM images (positive statue) for the colloidal particles polymerized in the range of −30 • C and −50 • C endowed with β-decay of 60 Co→ 60 Ni nuclear fission reaction; dose rate: 20 R (5.2 × 10 −3 C kg −1 ) per s for 50 h, corresponding to 3.6 × 10 6 R (9.3 × 10 2 C kg −1 ); (e,f) TEM images (positive statue) for closed loop shape structures from colloidal AcC 10 C 18 N + 2C1Br − polymerized at 45 • C led by β-decay of 60 Co→ 60 Ni nuclear reaction; dose rate: 20 R (5.2 × 10 −3 C kg −1 ) per s for 3.5 h, corresponding to 2.6 × 10 5 R (0.6 × 10 2 C kg −1 ). These TEM images suggested spiral fibers dispatching from the colloidal polymers [243]. A Hitachi (Ibaraki, Japan) model H-500 TEM instrument was employed with an accelerating voltage of 100 kV at lab of Motoo Takayanagi (Kyushu University). All figures (a-f) were scanned from the Master thesis [243].
The author conjectured at that time that handed spiral from the colloids in the ultracold and hot conditions is a model of the cometary coacervates hypothesis in comets [123]. Three chiral physical sources are possible to connect to the spiral rings because the β − -decay process from 60 Co radiates l-hand spinning β-electron, r-hand γ-ray (high-energy circularly polarized light), and l-hand anti-neutrino simultaneously from the source [69][70][71][72][73][74][75][76].
Amphiphilic colloidal particles in water may feel the forces led by these handed radioactive physical sources because atmospheric thundering and radioactive materials in Earth's crust and mantle might be ubiquitous in primordial eons, as well as the present days. Similarly, microdroplets in aqueous solution and aqueous aerosols in the atmosphere may be susceptible to these handed physical sources, leading to accelerated chemical reactions led by optofluidic WGM scenarios.
In recent years, several review papers on terrestrial and extraterrestrial life, chemical evolution, the origin of life, and the origin of chirality on Earth have been disclosed [11][12][13][14][15][16][17][18][19][20][21][244][245][246][247]. These papers comprehensively cover curious topics in the realms of astrochemistry, astrobiology, geoscience, space life science, synthetic biology, origin of life, central dogma, natural science, and materials science. The reviews should provide new insights in the realms of helical polymer chemistry [248], supramolecular chemistry [249], flow chemistry with light [250], natural product chemistry [251], and chiroptical polymer chemistry [252]. However, possible connections of these topics with nonequilibrium open-flow colloidal systems seem to be rare. An importance of (chir)optical characteristics of surrounding media, degree of smooth interfaces, micro-optics and optofluidics, photon confinement, resonance condition, WGM, and nature of light-matter interactions in the presence and absence of static electric field and static magnetic field are not well recognized. In my view, when one can setup open-flow, cell-wall-free µm-size colloidal polymers with a smooth surface dispersed in aqueous conditions with tuned RIs, any mirror-symmetrical physical forces and non-mirror-symmetrical inherently chiral particles, such as solar neutrinos and anti-neutrinos, are possible to induce and boost the left-right imbalance disregard of terrestrial and extraterrestrial conditions, even at cryogenic temperatures. The concept of the open-flow, non-equilibrium optofluidic colloidal and co-colloidal systems shed light at opening new science and engineering opportunities in chirogenesis and photochirogenesis, in addition to conventional stereochemistry, photochemistry, and photophysics in homogeneous solutions. The ideas are applicable to chirogenesis and photochirogenesis in µm-size water-based aerosols and microdroplets to address plausible scenarios for the homochirality questions on Earth.

Conclusions
Colloids and co-colloids with higher RI dispersed in optofluidic mediums with lower RI are capable of chiroptical resonators susceptible of external chiral chemical and CP light sources. Concerning µm-size colloids, made of π-/σ-conjugated polymers in optofluidic medium, with a tuned RI, several resonance effects cause efficient chirogenesis and photochirogenesis, revealed by gigantic, enhanced CD, ORD, CPL, and CPLE spectral datasets. The chirogenesis is susceptible to the nature of optofluidic medium, including chiral chemical substances and a ratio of πand σ-conjugated polymers. Moreover, a fully controlled absolute photochirogenesis upon excitation of leftand right-CP light sources at several wavelengths is a possible disregard of photochromic and non-photochromic polymers at specific refractive indices of optofluidic media. The wavelength-dependent CP light source can fully drive all chiroptical generation, inversion, erase, switching, and short-/long-lived memories. New knowledge and deep understanding of CPL, CPLE, CD, and ORD spectroscopy for colloids and co-colloids can shed light on rationally designing elaborate CPL functioned π-/σ-conjugated polymers and metal-coordination polymers in the future. A tandem analysis of CPLE, CPL, and CD spectroscopy helps to discuss Kasha's rule and anti-Kasha's rule of radiation processes from the photoexcited optically active molecules, polymers, colloids, solids, crystals, and thin films. Our comprehensive studies, using artificial polymeric luminophores and chromophores, should provide new insight of the open-flow, non-equilibrium functional colloids, and co-colloids in the photoexcited and ground states in an RI-tuned optofluidic medium. Based on the results shown above, and my personal experiences, any chiral physical forces and particles could induce and boost the left-right imbalance, which is one possible answer to the homochirality question on Earth's disregard of terrestrial and extraterrestrial origin chirality. In particular, when open-flow, µm-size colloidal polymers with smooth surfaces, adaptable to external physical and chemical biases are surrounded by an optofluidic medium, such as an aqueous solution, the capabilities of chiral physical forces and chiral chemical sources are possible, to enhance by huge numbers of recycling times (N) in the optofluidic colloidal polymers, in line with the scheme of WGM. This means that a subtle left-right imbalance interior of the colloid, e.g., 10 −6 % ee, is boostable by 10 −6 × N. This scenario is in contrast to a conventional stereochemistry, photochemistry, and photophysics in a homogeneous solution system, in which the light-matter interaction occurs in one time (N = 1) only by assuming the Beer-Lambert law in homogeneous solutions. When colloid-induced emission systems chiroptically fulfil the resonance condition, one can anticipate the significant enhancements in CPL and CD signals.  Figures 16 and 19, no new data were created or analyzed in this study. Data sharing is not applicable to this article. Figures 16 and 19 are available on request from the corresponding author.