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Review

A Palette of Efficient and Stable Far-Red and NIR Dye Lasers

by
Edurne Avellanal-Zaballa
1,
Leire Gartzia-Rivero
1,
Jorge Bañuelos
1,*,
Inmaculada García-Moreno
2,
Antonia R. Agarrabeitia
3,
Eduardo Peña-Cabrera
4 and
Maria Jose Ortiz
3
1
Dpto. Química Física, Universidad del País Vasco (UPV/EHU), Aptdo. 644, 48080 Bilbao, Spain
2
Dpto. Sistemas de Baja Dimensionalidad, Superficies y Materia Condensada, Instituto Química-Física “Rocasolano”, IQFR-CSIC, Serrano 119, 28006 Madrid, Spain
3
Dpto. Química Orgánica, Universidad Complutense, Ciudad Universitaria s/n, 28006 Madrid, Spain
4
Dpto. Química, Universidad de Guanajuato, Noria Alta S/N, Guanajuato 36050, Mexico
*
Author to whom correspondence should be addressed.
Appl. Sci. 2020, 10(18), 6206; https://doi.org/10.3390/app10186206
Submission received: 17 August 2020 / Revised: 3 September 2020 / Accepted: 4 September 2020 / Published: 7 September 2020
(This article belongs to the Special Issue 10th Anniversary of Applied Sciences: Invited Papers in Materials)
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Abstract

:

Featured Application

Organic lasers active in the red–near-infrared spectral regions endowed with efficient and long-lasting emission.

Abstract

The disposal of long-wavelength-emitting sources is of paramount relevance in technology and biophotonics due to the low interference with the surroundings that these kinds of far-red and near-infrared radiations hold. As a result of the continued efforts carried out during the last few years by our research group to design new boron-dipyrromethene (BODIPY) dyes with improved photonic performance, two approaches were tested to develop a new generation of organic dyes able to display efficient and long-lasting laser emission in both target spectral regions. On the one hand, the annulation of aromatic benzofuran at the dipyrrin backbone leads to conformationally restricted dyes yielding photostable and bright laser emission beyond 600 nm at the far-red spectral region. On the other hand, a more pronounced shift to longer wavelengths reaching 725 nm at the near-infrared region is feasible, while keeping a reasonably high laser efficiency and tolerance to prolonged and intense pumping, based on aza-BODIPYs bearing peripheral aryl rings. These two complementary strategies yield a library of laser-emitting compounds comprising the 600–725 nm spectral region. Moreover, their laser performance is better than the commercially available dye lasers active in this spectral window.

1. Introduction

The design of stable and bright photoactive systems able to emit in the far-red (within 600–700 nm spectral window) and especially in the near-infrared (NIR, beyond 700 nm) spectral regions is an actively sought task in photonics [1,2,3,4,5,6]. This kind of long-wavelength emission is an attractive radiation source for telecommunications, as well as for optics and electronics (diodes, filters, logic gates, and optoelectronic devices in general) [7,8,9,10], owing to its low background interference with the surroundings which allows the light to travel long distances. They are also appealing as photosensitizers for solar cells because thegap between the highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO) matches the valence and conduction band gaps of semiconductors [11,12]. It is noteworthy that, in the last few years, NIR luminophores were intensively and successfully applied in biotechnology and biomedicine [13,14,15,16]. This kind of NIR radiation allows a deep penetration into tissues (up to 2–5 cm within the biological window, λ > 650 nm), avoids autofluorescence of the surrounding biomolecules, and has lower toxicity. These features are ideal to apply high-resolution fluorescence imaging (such as super-resolution microscopy) for non-invasive diagnosis, sensing, and therapeutic purposes. In this regard, dye chemistry is a suitable tool to develop NIR absorbers and emitters thanks to the chemical versatility afforded by the highly accessible organic synthetic routes [17,18,19,20]. In particular, cyanines [21,22], porphyrines [23], and pthalocyanines [24], all of them featuring highly conjugated π-systems, are the most tested organic fluorophores for this aim (Figure 1). However, these fluorophores feature some drawbacks for their optimal performance. They require tedious synthetic and purification procedures. They display low fluorescence efficiency, mainly in the cyanine-based dyes, owing to the non-radiative deactivation channels afforded by their conformationally flexible structures and push–pull character. Moreover, they usually show poor photostability owing to photobleaching processes [25], likely related to the low energy gap between the excited and ground state. Finally, the chemical versatility for postfunctionalization is limited in these molecular skeletons.
To overcome such limitations, the design of a new generation of organic dyes endowed with absorption and emission bands within the biological window, easily accessed and derivatized, and displaying bright and long-lasting emissions is a highly demanded issue. In this regard, the renowned boron-dipyrromethene (BODIPY) dyes, which can be considered as the little sister of porphyrins or cyclic cyanines, drew the attention of researchers. Their boron-dipyrrin core is robust and stable (both chemically and photochemically) [26], and their photophysical signatures can be modulated by the substitution pattern [27]. Furthermore, BODIPYs can be easily accessed through many synthetic routes and straightforwardly functionalized to deeply shift their spectral bands toward the red edge of the electromagnetic spectrum [28]. In the literature, several chemical modifications were reported to this aim [29]. The main strategies are the following:
(1)
The induction of intramolecular charge transfer (ICT) phenomena in BODIPYs via the grafting of electron donor and acceptor moieties (push–pull dyes) [30,31]. The emission from the ICT is strongly shifted to longer wavelengths. However, it is usually very weak and very sensitive to the environmental conditions.
(2)
The extension of the delocalized π-system through aromatic frameworks. To this aim, aromatic rings are annulated at the dipyrrin core, leading to conformationally restricted BODIPYs [32,33] or directly connected to the core via single bonds [34,35]. Moreover, according to this last procedure, two (bis-BODIPYs) [36] or several BODIPY units (oligomers) [37] can be linked through spacers allowing electronic coupling or directly fused through aromatic rings (fused bis-BODIPYs) [38,39,40]. In this way, NIR absorbers are achieved. However, the electronic rearrangement upon resonant interactions between the electronic clouds of the BODIPYs usually leads to poorly emissive compounds.
(3)
The replacement of the meso carbon by an aza group (aza-BODIPY) [41,42,43]. Such simple modification induces pronounced bathocromic shifts [44], which can be enlarged spanning the delocalize π-system, as in the preceding point. Indeed, the aza-BODIPY dye family stands out as a promising alternative to design brighter, more stable, and compact NIR emitters than the classic phtalocyanines.
Against this background, in the last few years, we intensively explored the rich chemistry of BODIPY dyes. As a result, we designed, synthesized, and characterized a library of BODIPY-based far-red and NIR emitting dyes, covering the spectral region ranging from 650 to 750 nm, and applied them as lasers. The benefits of these kinds of coherent and powerful radiation holds are well known. As a matter of fact, many laser-based devices and technologies are applied intensively and successfully in industry, communications, surgery, and daily life. Among the different kinds of available lasers, those based on organic molecules as active media are in the spotlight [45,46]. The main advantage of dye lasers or organic lasers is the chemical versatility afforded by synthetic tools. Thus, there are a wide chart of commercially available laser dyes across the ultraviolet, visible, and NIR spectral regions. Moreover, they display a broad band enabling a certain sintonization range, not usually available in those lasers based on inorganic photoactive media, along with the generation of ultrashort pulses (in the femtosecond scale). This last property is appealing to study fast molecular dynamics in the excited state by advanced spectroscopic techniques. On the other hand, the main drawback of organic lasers is their limited photostability. To circumvent such restriction, complex and bulky experimental set-ups are required. Therefore, to offset this deficiency, we developed red and NIR dye lasers with improved photonic performance, particularly focused on enhancing the photostability, i.e., benzofuran-fused BODIPYs (Section 2) as laser dyes emitting in the far-red region of the visible spectral region [47] and polyarylated aza-BODIPYs (Section 3) for the NIR spectral region (Figure 2) [48]. Hereafter, we overview the photophysical and laser properties of these novel BODIPYs designed in our laboratories and compare their photonic performance with commercially available laser dyes working in the same spectral region.

2. Red-Emitting Benzofuran-Fused BODIPYs

The laser dyes designed to cover the far-red region of the visible spectrum are based on a BODIPY core bearing fused benzofuran rings with different substitution patterns (fluorine, alkyls, linear alcoxys, or additional fused rings) [47]. The corresponding molecular structures and main photophysical and laser data are summarized in Figure 3.
The fusion of benzofuran rings at chromophoric positions 2 and 3 and their symmetrical positions 5 and 6 induces the expected bathochromic shift. In fact, the theoretically predicted molecular orbitals show that the π-system is extended through the whole molecule (Figure 4). The exception is the 8-aryl group, not taking part in the delocalized π-system owing to its twisted disposition [26]. The presence of electron donor moieties (RED7, RED9, and RED11) and mainly the further fusion of more aromatic groups (RED8) induce a more pronounced shift to the red edge, from 575 to 610 nm (Figure 3 and Figure 4). Such spanning of the aromaticity is reflected in a remarkable enhancement of the absorption probability (molar absorption coefficient), being twice that recorded for simpler BODIPYs, and reaching values approaching 200,000 M−1·cm−1 (Figure 3 and Figure 4) [47]. The corresponding fluorescence bands are located in a spectral window ranging from 595 to 625 nm. The spectral proximity between the absorption and fluorescence spectra (low Stokes shift) suggests a low geometrical rearrangement upon excitation (Figure 4). The cyclization of the substituents limits the conformational freedom, and these constrained geometries hinder non-radiative relaxation processes [49]. As a result, the recorded fluorescence efficiencies are high, surpassing 80% in most cases (regardless of the applied substitution pattern) and even approaching 100% in some cases (Figure 3). The exceptions to this behavior are due to an increase in the non-radiative deactivation processes induced by the substitution pattern. For instance, in RED5, the combination of electron donor benzofuran with electron formaldehyde at the para-8-aryl favors charge separation and reduces the emission capability [47]. In RED8 and RED11, the geometrical tensions induced by the additional fused phenyls could promote the bending of the chromophore, thereby distorting the planarity and increasing the internal conversion [47].
The excellent photophysical properties of these dyes led to an outstanding laser performance in the far-red region. Strong laser emissions were recorded spanning the spectral region from 615 nm to 660 nm (Figure 4) with efficiencies approaching 50% (see RED1–4, RED6–7, and RED9–10 in Figure 3). The lasing properties followed the photophysical trends. The bathochromic shift of the laser wavelength correlated with a shift of the fluorescence band with the substitution pattern (see RED8 in Figure 3). Moreover, those dyes showing the lowest fluorescence efficiency displayed the poorest laser efficiency (see RED5 and RED8 in Figure 3). It is noteworthy that those dyes with flat molecular geometries are prone to stacking with each other, leading to the formation of aggregates [50]. This phenomenon is active at the high optical densities required to record the laser action. Indeed, we detected dual laser emissions. Thus, at high pump energies, a long wavelength emission is registered flanking that recorded at lower pump energies. The latter emission is the expected one, but the former emission is assigned to the presence of aggregates (photoinduced excimers or superexciplexes). These molecular entities are only detected under strong pumping, but not under standard excitation as in photophysical measurements [51]. These aggregates are able to lase and increase the sintonization range of the laser emission.
Photostability is a key parameter ruling the operative lifetime of dyes and light-driven devices [25]. This signature was estimated as the amount of energy required to reduce 10% of the laser-induced fluorescence (that is, to retain 90% of the initial emission; see inset of Figure 4). All the dyes showed a reasonable tolerance to a continuous and strong irradiation regime. In some cases, the photostability was exceptional (reaching 7 GJ/mol in RED6, likely owing to the stability provided by the strongly bounded fluorine atoms [52]), yielding extremely long-lasting emission. It is noteworthy that the lowest photostabilities correspond to the dyes bearing the 8-phenyl para-substituted (Figure 4), with a metoxy group in RED4 and a formaldehyde moiety in RED5. On the other hand, the highest photostabilities were attained in dyes where the benzofuran moiety was functionalized (with fluorine, tert-butyl or aliphatic alcoxy chains, RED6–7 and RED9, respectively).
To highlight the notable photonic performance of these laser dyes, we compared the laser behavior of the benzofuran-fused BODIPYs with a commercially available BODIPY working in the same spectral region (PM650, where the number accounts for the laser emission wavelength) [53]. The photostability of PM650 (6.3 GJ/mol) is of the same order (up to 7.4 in RED6) owing to the robustness of the BODIPY chromophore, but the efficiency is clearly enhanced (from 31% in PM650 to 48% in RED3). Therefore, we were able to improve the light-harvesting ability and retain the long-lasting emission efficiency typical of the BODIPYs while pushing it into the far-red edge of the visible spectrum.

3. NIR-Emitting Polyarylated Aza-BODIPYs

To induce a more pronounced shift of the laser emission to longer wavelengths, we focused on aza-BODIPYs bearing a π-extended delocalize framework through peripheral aromatic substitutions at the dipyrrin core (Table 1) [48].
The replacement of the carbon at position 8 by an aza group is a simple but effective way to induce the desired bathochromic shift without enlarging the molecular size. The electronegativity of the nitrogen at such a chromophoric position induces a preferred stabilization of the LUMO state, reducing the energy gap [44]. Such a red shift can be reinforced through peripheral substitutions with aryl groups and electron-rich moieties to extend the π-system and reach emission in the NIR region. In fact, in F-aza-BODIPYs, the spectral bands, both absorption and fluorescence, shift progressively to longer wavelengths (Table 1 and Figure 5) as the number of appended unrestricted phenyls increases (from NIR1, with two peripheral phenyls, to NIR2 with four rings), and even further upon functionalization of the peripheral aryls with electron donor groups (like methoxy in NIR4).
The fluorescence response of the F-aza-BODIPYs was lower (around 45%, Table 1) than that recorded for the conformationally restricted BODIPYs (see section with values up to 95% in Figure 3). This was expected in terms of the energy gap law [54]. A lowering of the energy gap enhances the vibrational coupling of the involved electronic states and, hence, the internal conversion probability. Nevertheless, fluorescence efficiencies of around 45% are notable in the NIR region. Such emission depends mainly on the conformational freedom of the aryls at positions 1 and 7 of the chromophoric core. Thus, the fluorescence of NIR2 and NIR3 decreased to 12%, whereas the locking of the free motion of such 1,7-rings (sterically hindered mesityl group instead of phenyl) implied a recovery of the fluorescence signal (up to 46% in NIR4, Table 1). In this regard, NIR4 is the most appealing dye among the tested ones owing to its high fluorescence efficiency at longer wavelength [48].
All these dyes showed laser bands tunable from 650 to 700 nm, in good correlation with the evolution of the fluorescence band position depending on molecular structure (Figure 5). The laser efficiencies ranged from 13% to 23%, with NIR4 again being the dye with the best laser performance in agreement with the photophysical signatures. Nevertheless, the most outstanding result was the excellent photostability shown by these dyes (up to 44 GJ/mol, Figure 6). These F-aza-BODIPYs showed a noticeable four-fold enhancement with respect to commercial laser dyes emitting in the same spectral region, such as the oxazine dye called Nile Blue [55], while retaining similar laser efficiencies (around 30% in Nile Blue). In other words, these F-aza-BODIPYs display efficient and long-lasting laser signals, drastically improving the photostability of commercially available NIR laser dyes.
Trying to ameliorate both laser parameters, efficiency and photostability, we carried out structural modifications at the boron atom rendering the corresponding C- and O-aza-BODIPYs (Table 1). As a common rule in BODIPYs, the replacement of fluorine atoms (F-BODIPYs) by alcoxys (O-BODIPYs) or alkyls (C-BODIPYs) improved the photonic response [56,57,58]. Thus, we developed the corresponding O- and C-aza-BODIPYs, replacing the fluorine atoms at the boron center with electron acceptor trifluoroacetoxy and cyane moieties [48], respectively (Table 1). According to previous results in simpler BODIPYs, both substituents were the most suitable to improve the photonic performance [56,57]. Such chemical modification has a minor impact on the spectral band positions (overall a slight bathochromic shift) since the boron atom does not take part in the dipyrrin aromatic framework [48]. However, such substitution has a marked impact on the fluorescence efficiency, and it depends on the peripheral substitution pattern of the dipyrrin (Table 1). Thus, in the O-aza-BODIPYs derived from NIR2 and NIR3, a clear enhancement (four-fold) of the fluorescence response was recorded. The fluorescence response of the O-aza-BODIPY derived from NIR4 remained almost the same as that of the corresponding F-aza-BODIPYs. Moreover, the C-aza-BODIPYs did not improve the fluorescence response shown by the O-aza-BODIPYs, and NIR2 was better than the corresponding F-aza-BODIPY. Conversely, such improved fluorescence was not reflected in a marked increase of the lasing efficiency. Improved laser efficiencies were only recorded in the derivatives of NIR2 and NIR4. Additionally, the photostability of the O- and C-aza-BODIPYs clearly dropped (two- or three-fold depending of the dye, Figure 6) with regard to the parent F-aza-BODIPYs. Moreover, we observed that the C-aza-BODIPYs and especially the O-aza-BODIPYs were chemically unstable, and the solution lost its color with aging time. Likely, these two factors, low chemical and photochemical stability, could explain the existing mismatch between the fluorescence and laser efficiencies. Such low stability was strengthened under strong pumping in the laser resonator cavity.

4. Conclusions

The rich and versatile chemistry of BODIPYs is a suitable tool to design a chart of photoactive dyes as efficient and stable tunable lasers within the spectral window ranging from 600 to 725 nm. Within the far-red region of the visible spectrum, conformationally restricted benzofuran-fused BODIPYs are a suitable option. Their flat and rigid aromatic framework allows a huge absorption of the pumping light and avoids non-radiative deactivation funnels. Therefore, these dyes yield efficient (approaching the 50%) and stable laser signals ranging from 600 to 650 nm. To further push the laser emission toward the NIR region, polyarylated aza-BODIPYs are more suitable. Strikingly, the chemical modification at the boron atom is not a recommended strategy because the chemical and photochemical stability of the dye is reduced. Therefore, F-aza-BODIPYs are the best design to record notable laser emission from 650 to 725 nm, which is outstanding, mainly due to their high photostabilities.
Both set of dyes surpass the laser performance of commercially available laser dyes working in the same spectral region. On the one hand, the benzofuran-fused BODIPYs markedly improve the brightness of the laser emission in the far-red region. On the other hand, the aza-BODIPYs greatly increase the photostability, leading to long-lasting tunable laser emissions in the NIR region.
Furthermore, these molecular scaffolds might be envisaged as promising fluorescent probes for bioimaging purposes owing to their efficient light absorption within the biological window and ulterior display of bright fluorescent images over long exposure periods.

Author Contributions

Synthesis of benzofuran-fused BODIPYs, E.P.-C.; synthesis of aza-BODIPYs, A.R.A. and M.J.O.; photophysical and laser measurements, E.A.-Z., supervision of laser experiments, I.G.-M.; supervision of photophysical experiments, writing—original draft preparation, and editing, J.B.; writing—review, L.G.-R. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Spanish Ministerio de Economia y Competitividad (MINECO), grant number MAT2017-83856-C3-1-P, 2-P and 3-P, and Gobierno Vasco, grant number IT912-16.

Acknowledgments

E.A.Z. thanks Gobierno Vasco for a predoctoral fellowship.

Conflicts of Interest

The authors declare no conflict of interest.

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Applsci 10 06206 g001 550
Figure 1. Molecular structures of the most commonly tested red and near-infrared (NIR) dyes based on cyanine backbones.
Figure 1. Molecular structures of the most commonly tested red and near-infrared (NIR) dyes based on cyanine backbones.
Applsci 10 06206 g001
Applsci 10 06206 g002 550
Figure 2. Molecular structure of the renowned boron-dipyrromethene (BODIPY) chromophore and the chemical modification carried out to push the spectral bands toward the red edge of the visible spectrum and NIR region.
Figure 2. Molecular structure of the renowned boron-dipyrromethene (BODIPY) chromophore and the chemical modification carried out to push the spectral bands toward the red edge of the visible spectrum and NIR region.
Applsci 10 06206 g002
Applsci 10 06206 g003 550
Figure 3. Molecular structures of the benzofuran-fused BODIPYs and their corresponding main photophysical (at diluted solutions of 2 μM) and laser (at the optimal dye concentration ranging from 0.5 to 1.2 mM) data in ethyl acetate: absorption wavelength (λab, in nm), molar absorption coefficient (εmax, in 104 M−1·cm−1), fluorescence wavelength (λfl, in nm), quantum yield (φ), laser wavelength (λla, in nm), and efficiency (% Eff). The laser emission of RED11 could not be recorded due to lack of solubility at the required high concentration.
Figure 3. Molecular structures of the benzofuran-fused BODIPYs and their corresponding main photophysical (at diluted solutions of 2 μM) and laser (at the optimal dye concentration ranging from 0.5 to 1.2 mM) data in ethyl acetate: absorption wavelength (λab, in nm), molar absorption coefficient (εmax, in 104 M−1·cm−1), fluorescence wavelength (λfl, in nm), quantum yield (φ), laser wavelength (λla, in nm), and efficiency (% Eff). The laser emission of RED11 could not be recorded due to lack of solubility at the required high concentration.
Applsci 10 06206 g003
Applsci 10 06206 g004 550
Figure 4. Absorption, fluorescence and laser spectra of representative benzofuran-fused BODIPYs (RED3 and the more π-extended RED8) in ethyl acetate. Inset: top, contour maps (HOMO and LUMO) of the frontier orbitals involved in the electronic transition; bottom, photostability calculated as the energy dose required to decrease 10% of the laser-induced fluorescence (Edose90%).
Figure 4. Absorption, fluorescence and laser spectra of representative benzofuran-fused BODIPYs (RED3 and the more π-extended RED8) in ethyl acetate. Inset: top, contour maps (HOMO and LUMO) of the frontier orbitals involved in the electronic transition; bottom, photostability calculated as the energy dose required to decrease 10% of the laser-induced fluorescence (Edose90%).
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Figure 5. Absorption, fluorescence, and laser (filled) spectra of two representative F-aza-BODIPYs (NIR1 and NIR4) in ethyl acetate. Inset: corresponding contour maps (HOMO and LUMO) of the frontier orbitals involved in the electronic transition.
Figure 5. Absorption, fluorescence, and laser (filled) spectra of two representative F-aza-BODIPYs (NIR1 and NIR4) in ethyl acetate. Inset: corresponding contour maps (HOMO and LUMO) of the frontier orbitals involved in the electronic transition.
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Figure 6. Photostability (energy dose required to decrease 10% of the laser-induced fluorescence Edose90%) of the F-, C-, and O-aza-BODIPYs in ethyl acetate.
Figure 6. Photostability (energy dose required to decrease 10% of the laser-induced fluorescence Edose90%) of the F-, C-, and O-aza-BODIPYs in ethyl acetate.
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Table
Table 1. Molecular structure of the NIR aza-BODIPYs and their corresponding main photophysical (at diluted solutions of 2 μM) and laser (at the optimal dye concentration ranging from 0.25 mM to 1 mM) data in ethyl acetate: absorption wavelength (λab), molar absorption coefficient (εmax), fluorescence wavelength (λfl), quantum yield (φ), laser wavelength (λla), and efficiency (% Eff). The corresponding O-aza-BODIPY in NIR1 could not be isolated owing to its chemical instability.
Table 1. Molecular structure of the NIR aza-BODIPYs and their corresponding main photophysical (at diluted solutions of 2 μM) and laser (at the optimal dye concentration ranging from 0.25 mM to 1 mM) data in ethyl acetate: absorption wavelength (λab), molar absorption coefficient (εmax), fluorescence wavelength (λfl), quantum yield (φ), laser wavelength (λla), and efficiency (% Eff). The corresponding O-aza-BODIPY in NIR1 could not be isolated owing to its chemical instability.
Rλab
(nm)		εmax·10−4
(M−1·cm−1)		λfl
(nm)		φλla
(nm)		% Eff
Applsci 10 06206 i001
F6143.26390.3264713
CN6045.56380.2264413
Applsci 10 06206 i002F6458.66680.1268116
OCOCF36465.66710.4768919
CN6527.36700.4668612
Applsci 10 06206 i003F6548.66820.1569020
OCOCF36556.76870.4469616
CN6547.36770.1269216
Applsci 10 06206 i004F6697.86960.4670823
OCOCF36787.97080.4972033
CN6675.67030.3171729

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Avellanal-Zaballa, E.; Gartzia-Rivero, L.; Bañuelos, J.; García-Moreno, I.; R. Agarrabeitia, A.; Peña-Cabrera, E.; Ortiz, M.J. A Palette of Efficient and Stable Far-Red and NIR Dye Lasers. Appl. Sci. 2020, 10, 6206. https://doi.org/10.3390/app10186206

AMA Style

Avellanal-Zaballa E, Gartzia-Rivero L, Bañuelos J, García-Moreno I, R. Agarrabeitia A, Peña-Cabrera E, Ortiz MJ. A Palette of Efficient and Stable Far-Red and NIR Dye Lasers. Applied Sciences. 2020; 10(18):6206. https://doi.org/10.3390/app10186206

Chicago/Turabian Style

Avellanal-Zaballa, Edurne, Leire Gartzia-Rivero, Jorge Bañuelos, Inmaculada García-Moreno, Antonia R. Agarrabeitia, Eduardo Peña-Cabrera, and Maria Jose Ortiz. 2020. "A Palette of Efficient and Stable Far-Red and NIR Dye Lasers" Applied Sciences 10, no. 18: 6206. https://doi.org/10.3390/app10186206

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