Photoelectrochemical Energy Conversion over 2D Materials

The solar motivated photoelectrochemical (PEC), used in water splitting systems, shows superior talent in converting solar energy in the form of cleaning and in sustaining a chemical energy evolution. PEC systems present by integrating a photoelectrode, which involves light-harvesting to absorb solar energy, thereby introducing an interlayer for the transformation of photogenerated electrons and holes, along with a co-catalyst to trigger oxidation and reduce the chemical reactions. In this review, we describe a variety of two-dimensional (2D) layered photoanodes and photocathodes, such as graphitic carbon nitrides, transition metal dichalcogenides, layered double hydroxides, MXenes, and co-catalysts for the assembly of combined photoelectrodes belonging to oxygen evolution and/or hydrogen evolution chemical reactions. The basic principles of PEC water splitting associated with physicochemical possessions relating to photoelectrodes unified with catalytic chemical reactions have been investigated. Additionally, the mechanisms attributing to a relationship with 2D photoelectrodes have been incorporated as a supplementary discussion. The improvement strategies, which include the construction of heterostructures, surface functionalization, and formations of heterojunctions, have also been discussed. The issues and challenges relevant to the field have been acknowledged for facilitating future research, indicating optimized conversion activity corresponding to PEC water splitting.


Introduction
Renovation for cleaning and renewing solar energy in the form of stored chemical energy has been considered a practicable and viable approach in order to face the main issues resulting from exhausting fossil fuels and using environmentally polluting materials. In 1972, researchers presented cleaning H 2 energy, which might be generated through water splitting by employing a photoelectrochemical (PEC) cell associated with TiO 2 photoanode [1]. Heterogeneously joining photocatalysis and electrochemistry is considered a synergistic strategy for efficiently achieving the conversion of solar energy [2,3]. In an ideal PEC system, the semiconducting photoelectrode becomes a basic counterpart, thereby capturing solar light as well as promoting oxidation and reduction reactions, such as water splitting [4][5][6], efficient CO 2 reduction [7,8], and N 2 specification [9,10].
During light irradiation, a typical semiconducting photoelectrode may be activated through photons possessing the equivalent or higher energy than the bandgap energy. As a result, photogenerated holes reside in the valence band, whereas photogenerated electrons are generated and isolated during picoseconds, afterward jumping toward the conduction  Simultaneously, the interior electric field produced across the nanosheets can improve the charge isolation of the photogenerated electron-hole pairs.

MXenes
Familiar 2D materials also involve metal-free GCNs and TMDCs materials showing a great potential to fabricate superior-quality photoelectrodes, whereas there has been keen interest for the newly introduced layered MXene architectures to be strongly involved in assembling PEC systems for water splitting. Specifically, MXenes are considered a new and talented family member containing nearly 60 varieties of 2D metal carbides, nitrides, or carbonitrides, which are exploited to construct a variety of electrodes for supercapacitors, photoelectrocatalysis, and photovoltaics [62][63][64].
To date, MXenes have been demonstrated to possess various exceptional compensations for improving PEC efficiency. For example, various unsaturated metal locations (e.g., Ti, V, or Nb) have been explored to form 2D layer architectures, thereby resulting in higher redox reactivity than single-elemental carbon species. Additionally, hydrophilic functional groups, such as -OH and -O, reside in the form of dangling bonds over the MXene's surface, becoming advantageous for bonding with the diverting semiconductors and stabilizing 2D MXenes in an aqueous media for a prolonged term. In contrast, MXenes exhibit outstanding metallic conductivity analogous to graphene, thereby facilitating the confirmation toward efficient charge transfers. Occupying excellent properties, the 2D MXenes present as a promising candidate for constructing photoelectrodes [12][13][14][15][16][65][66][67]. Similar to graphene, monolayer MXenes occupy a hexagonal lattice associated with the rhombohedral unit cell. Whereas the side view depicts as tri-layer sheets unified with monolayer MXenes, containing two TM layers sandwiched with one X layer, caused by the function in the form of active catalytic sites toward the HER; however, MXenes resources as HER electrodes need a greater overpotential water splitting [68]. Hence, incorporating MXene's photoelectrodes as newly activated constituents have become a feasible strategy to overcome the above shortcomings.
Currently, nanocarbons are encapsulated in MXenes-based systems, which can promote robust interfacial coupling with an improvement in separation and injection performance in favor of photogenerated charge carriers [69][70][71][72][73][74]. For instance, Qiu et al. have reported a carbon encapsulation approach for stabilizing 2D Ti 3 C 2 -MXenes and constructed a ranked MoS 2 /Ti 3 C 2 -MXenes with the association of a C heterojunction, thereby exhibiting exceptional HER efficiency with high structural stability [75]. MoS 2 /Ti 3 C 2 -MXene@C showed a low overpotential of 135 mV with 10 mA cm −2 in a 0.5 M H 2 SO 4 solution, Figure 1a,b. The onset potential at −20 mV toward the HER was close to commercial Pt/C, and the Tafel slope was reduced to 45 mV dec −1 compared with bare Ti 3 C 2 -MXene, Figure 1c. Figure 1d shows the MoS 2 /Ti 3 C 2 -MXene@C exhibited a steady current density associated with a constant potential (130 mV) during a prolonged time of 20 h [76]. Further, Zhang et al. have prepared cobalt-topped carbon nanotube (CNT)/Ti3C2 nanosheets using ZIF-67 as a precursor [77]. ZIF-67 was converted into Co-CNTs by a pyrolysis procedure in the presence of layered Ti3C2 conductive supports. Co-CNT/Ti3C2 nanosheets displayed an efficient electrocatalytic performance allied with enhancing stability related to commercial Pt/C in HER, which is attributed to the richer Co-N/C active sites, graphitization, and high surface area. The observed results indicate that 2D MXene/nanocarbons are undoubtedly considered as candidates for photocathodes in PEC systems toward efficient renewable energy resources.

Transition Metal Dichalcogenides
Layered TMDCs offer much more active centers and thickness-relied electronic structures, which favors the conversion of solar energy to produce hydrogen energy. Normally, TMDC structures, denoted as MX2 (M: transition metals, X: S, Se, and Te), have more than 40 varieties of stabilized 2D materials with similar structures [78], which are usually made of X-M-X layers connected via van der Waals forces. Nevertheless, the atomic compositions have a great influence on the electronic properties of TMDC materials. For example, MoS2 and MoSe2 show semiconducting behaviors, WTe2 and VS2 belong to the semimetals, and TaS2 and NbS2 are metals. Meanwhile, the optoelectronic properties of TMDCs mate- Further, Zhang et al. have prepared cobalt-topped carbon nanotube (CNT)/Ti 3 C 2 nanosheets using ZIF-67 as a precursor [77]. ZIF-67 was converted into Co-CNTs by a pyrolysis procedure in the presence of layered Ti 3 C 2 conductive supports. Co-CNT/Ti 3 C 2 nanosheets displayed an efficient electrocatalytic performance allied with enhancing stability related to commercial Pt/C in HER, which is attributed to the richer Co-N/C active sites, graphitization, and high surface area. The observed results indicate that 2D MXene/nanocarbons are undoubtedly considered as candidates for photocathodes in PEC systems toward efficient renewable energy resources.

Transition Metal Dichalcogenides
Layered TMDCs offer much more active centers and thickness-relied electronic structures, which favors the conversion of solar energy to produce hydrogen energy. Normally, TMDC structures, denoted as MX 2 (M: transition metals, X: S, Se, and Te), have more than Photochem 2022, 2 278 40 varieties of stabilized 2D materials with similar structures [78], which are usually made of X-M-X layers connected via van der Waals forces. Nevertheless, the atomic compositions have a great influence on the electronic properties of TMDC materials. For example, MoS 2 and MoSe 2 show semiconducting behaviors, WTe 2 and VS 2 belong to the semimetals, and TaS 2 and NbS 2 are metals. Meanwhile, the optoelectronic properties of TMDCs materials are also strongly affected by their atomic layer numbers. For example, the monolayer MoS 2 has a direct bandgap of 1.9 eV, and the corresponding bulk structure has an indirect bandgap of 1.3 eV [79]. Moreover, the semiconducting 2H-MoS 2 transforms to metallic 1T-MoS 2 with a decreasing atomic layer number that has been verified, which is availed for accelerating the motivation of photogenerated charge carriers. Chen et al. reported that nanostructured MoS 2 possessed a higher photocurrent density than bulk MoS 2 for PEC-HER [80]. The surface defects of nanostructured MoS 2 also play an important role in determining the whole activity of the water splitting reaction with photoelectrodes. By the method of in situ corrosion with bulk MoS 2 , the formation of surface defects resulted in decreasing photocatalytic activity, but these produced edge sites that could enhance the performance of electrocatalytic HER. The coordination number of S atoms has an obvious influence on catalytic activity; mono-coordinated S atoms exhibited higher activity than double-coordinated S atoms. Note that three-coordinated S atom support showed no photocatalytic activity. With the presence of photogenerated electrons, the H + species was easily reduced to H 2 over the active S atoms, which can vigorously bond to H + in a lactic acid solution [81]. Nanosized MoS 2 with more exposed edges could provide excellent HER activity in a photochemical/PEC reaction system. Therefore, 2D nanostructured TMDCs catalysts have been generally used in recent decades as active components to assemble the integrated photoelectrodes applied in PEC water splitting reactions [82][83][84][85][86].
However, the speed of photoproduced charge carrier transportation is very fast, and the produced electrons and holes would be recombined in a very short time, thus the PEC performance of 2D TMDCs photoelectrodes for water splitting would decrease sharply [87,88]. To improve the PEC activity of 2D TMDC-based photoelectrodes, some carbon nano-materials have been imported to enhance the isolation and transfer of photoproduced charge carriers [89]. As shown in Figure 2a, p-n MoS 2 /N-doped cGO heterojunction has been fabricated through an aerosol process in a furnace with a temperature of 900 • C [90]. The N-doped cGO/MoS 2 hybrid gave a lower overpotential of~100 mV vs. RHE, a higher photocurrent density, and a smaller Tafel slope than a commercial MoS 2 (Figure 2b,c), which was mainly due to the generation of a localized p-n heterojunction in a N-doped cGO/MoS 2 hybrid that could largely promote the separation of photoproduced charge carriers. Then, a RGO/CdS/MoS 2 hybrid was synthesized to investigate the effects of charge transfer behavior and the crystal structure of MoS 2 in a 2D photocathode on a solar-driven HER [91]. Because of intimate contact between the S atoms in CdS/MoS 2 , the intense electronic interaction between MoS 2 and RGO could be enabled, which is available for the isolation of a photogenerated charge, transfer with a higher charge density, and a lower resistance in the location of a solid-solid interface, thus impelling the PEC-HER activity.
Moreover, carbon dots (CDs) with a size less than 10 nm have been used in modifying TMDC-catalyzed photoelectrodes due to their uniquely remarkable π-conjugated system, which can enhance the speed of electron transfer between TMDCs and CDs [91][92][93]. For instance, CDs modified MoS 2 nanosheets have been synthesized via a hydrothermal method [94]. Under visible light irradiation, the CD-modified MoS 2 has an excellent performance (Tafel slope of 45 mV dec −1 and an overpotential of~125 mV at 10 mA cm −2 ) with an enhancing HER capacity, which was ascribed to the decreasing number of S 4+ and an increasing amount with S 2− 2 and S 2− sites that would accelerate the speed of charge carriers shifting between the CDs and MoS 2 . Furthermore, the CDs/MoS 2 exhibited excellent stability in a solution of 0.5 M H 2 SO 4 . Simultaneously, the time of duration with irradiation of visible light also affected the HER activity, which was ascribed to the expansion of number reduction with MoS 2 edges and surface defects. charge carriers. Then, a RGO/CdS/MoS2 hybrid was synthesized to investigate the effects of charge transfer behavior and the crystal structure of MoS2 in a 2D photocathode on a solar-driven HER [91]. Because of intimate contact between the S atoms in CdS/MoS2, the intense electronic interaction between MoS2 and RGO could be enabled, which is available for the isolation of a photogenerated charge, transfer with a higher charge density, and a lower resistance in the location of a solid-solid interface, thus impelling the PEC-HER activity.

Graphitic Carbon Nitride
The layered GCNs have received great attention, being 2D photocatalytic materials because of possessing facile synthesis, a lower cost, and elongated stability. Specifically, the remarkable bandgap of~2.7 eV associated with suitable band locations favors GCNs as an attractive candidate toward water splitting [95][96][97]. Moreover, sunlight aimed toward energy transformation performance for graphitic carbon nitride photocatalysts has been considered unsatisfactory because of a limiting light gain capability, an excessively recombined photogenerated charge carrier, slow charge carrier transportation performance, and slowly interfacial reaction dynamics toward PEC water splitting. To overcome the aforementioned unsuitability, nanocarbons have been introduced in the form of co-catalysts and have been greatly explored in the last era. Being zero-dimensional carbon, CDs were decorated onto the surface of GCN by rendering π-π stacked interactions, thereby resulting in a narrowing bandgap with the enhancement of a light response [98,99], and the heterojunction of CDs/GCN by van der Waals exhibits a high conductivity, thus the separating performance of photogenerated electron-hole pairs at the interfacial contact of heterojunction is largely enhanced [100].
For example, Kang et al. have reported the coupling of CDs with porous GCN collectively with negative surface charges to boost up quantum capabilities moving toward an optimum efficiency of 16% as 420 nm, with the combination of a whole solar energy changing ability of 2.0% with AM 1.5G illuminated solar conversion energy [101]. Next, Guo et al. have prepared a protonated g-C 3 N 4 /CDs (p-CN/CDs) hybrid photoanode through utilizing an electrostatic attraction route. The photoanode has exhibited an enhancing anodic photocurrent density of 38 µA cm −2 with 1.0 V vs. an RHE with incident photon-tocurrent efficiency (IPCE) of 7.0% with 420 nm illuminated with AM 1.5G, that is turned into two and three times greater than that of pure p-CN [102]. The observed CB potential showing a −0.59 eV value for p-CN/CDs demonstrates the remarkable thermodynamical advantage of PEC-HER. On comparing with CDs that may supply merely point-to-point interfacial contact into the heterojunction, the coupling of GCN nanosheets connecting with alternative carbon materials (e.g., 2D graphene) may result in an increment in the contacting area in favor of quick charge transfers and then an enhanced PEC performance.
To date, a layered CN-RGO photoelectrode containing a large porous structure has been prepared [103], which has supplied lengthy electron diffusion touching a 36 µm, greater surface area, and with a higher light-response limit. Due to the aforementioned merits, IPCE for optimizing a CN-RGO photoanode has been impressively considered at 5.3% with 400 nm and a redshift beginning wavelength at 510 nm. Moreover, the photocurrent density belonging to the CN-RGO was valued at 75 µA cm −2 with 1.23 V vs. RHE in the absence of a hole-scavenging-layer, thereby being 20 times higher than that of pristine CN. At the same time, the quantum efficiency externally approached as 5.5% with 400 nm. Being an efficient charge transfer bridge, an active role of the RGO inherited with an outstanding conductivity may facilitate photo-induced electron transfers, extracted by GCN toward the substrate, which enhances the PEC-HER performance.
Further, Leung et al. have presented a RGO-derived g-C 3 N 4 /Ni foamy nature photoanode containing a heterostructure of g-C 3 N 4 and RGO, which showed an improving PEC-HER efficiency [103]. The optimizing photoanode as a g-C 3 N 4 /RGO-Ni with a foamy nature has been explored with a constant transitory photocurrent density of 0.5 mA·cm −2 with 0.4 V vs. an SCE associated with a high H 2 creation rate of 6.0 mmol h −1 cm −2 , which was 2.5 times greater than those of pure g-C 3 N 4 , respectively. Illuminated with a visible light, photo-induced electrons have been created over g-C 3 N 4 , and therefore may migrate quickly toward an RGO with Ni foamy nature toward H 2 evolution depending upon a strong involvement with g-C 3 N 4 and RGO. Further, predictable GCN/RGO systems and a GCN/RGO hybrid heterostructure have also been designed toward efficiently high PEC water splitting. Currently, a g-C 3 N 4 /N-doped graphene/2D MoS 2 (CNNS/NG/MoS 2 ) photoanode has been prepared by employing a superficial sol-gel route [104]. Initially, the CNNS/NG composite was fabricated following one step of urea pyrolysis with GO, therefore, N-contained chemical substances have been unconfined through urea polycondensation, which in turn results from fractional reducing along with N-doped GO.
MoS 2 nanosheets have been offered in the form of a CNNS/NG hybrid through employing a hydrothermal approach for the formation of a CNNS/NG/MoS 2 hybrid. The ideal 2D/2D construction contains NG, which has been carried out in the form of a charge transfer channel to accelerate electron transformation existing among g-C 3 N 4 and MoS 2 , whereas g-C 3 N 4 has been utilized efficiently to harvest sunlight because of its belonging to a reasonable bandgap. During the same period, the layered MoS 2 had an increased light absorbance capability, thereby promoting electron-hole pair parting and transferring corresponding with a NG/MoS 2 interfacial contact, and the provision of exposing active locations owing to the PEC-HER. Hence, the aforementioned PEC system has been offered with a wide harvesting range of light and a shortening charge diffusion length, along with an enlarging affiliated area toward highly effective PEC water splitting.
A CNNS/NG/MoS 2 heterojunction has also presented a substantial improvement in photocurrent density showing 37.6 µA cm −2 with incorporating NG possessing 1.46and 3.43-times greater result as compared to CNNS/MoS 2 (25.7 µA cm −2 ) and CNNS (11 µA cm −2 ) with 0.9 V, respectively. Moreover, an ideal 2D single atomically thick carbon-allotrope as a graphdiyne (GDY) has been introduced as a promising candidate for photo/electrocatalysis, for attractive solar cells with charming batteries, utilizing special sp and sp 2 hybridized carbon atoms, and possessing moderate bandgaps of0.44-1.47 eV, and highly charged carrier dynamics of 10 4 -10 5 cm 2 V −1 s −1 [105]. The GDY performed efficiently as a modifier for enhancing the PEC water splitting efficiency that was already offered in the system of GDY/BiVO 4 [106] and CdSe-quantum dots/GDY [107].
Lu et al. [108] fabricated a g-C 3 N 4 /GDY heterojunction as an exceptional photocathode for PEC-HER, Figure 3a. The stability of the g-C 3 N 4 /GDY heterojunction unified with an ultrathin layered construction (Figure 3b), and a highly charged carrier movement with a high surface has been suggested as being valuable for efficient transformation belonging to photo-induced charge carriers, thereby suppressing the reformation of photogenerated electrons and holes, and significantly revealing various active sites. This may present a greater interfacial contact lying among g-C 3 N 4 and GDY, thereby providing short length channels available for transfer of the photo-induced electron-hole pairs. The layered g-C 3 N 4 associated with the interfacial contact of GDY has been additionally proved through following EDX elemental mapping, Figure 3d-g. Meanwhile, remarkable band alignments owing to g-C 3 N 4 and GDY (Figure 3h), show that photo-induced positive charges emerging from the g-C 3 N 4 may speedily move toward GDY. Consequently, photogenerated charge carriers are effectively isolated caused by an externally applied electric field. In the same dynamics, the g-C 3 N 4 /GDY hybrid was revealed in the form of a seven-graded increment for electron tenure as 610 µs, whereas a three-graded increment was revealed with a photocurrent density of −98 µA cm −2 with 0 V vs. NHE, as compared to pure g-C 3 N 4 of 88 µs and −32 µA cm −2 into a 0.1 Molar Na 2 SO 4 solution, Figure 3i, that in turn revealed a g-C 3 N 4 /GDY photoanode displaying an attractive efficiency in favor of PEC-HER.
LDHs materials possess frequent advantages, such as having a high surface area, plentiful active sites, well-defined layered structures, flexible chemical composition through a variation of the cations ratio, stability in structure, and hierarchy of porosity, proving valuable during the water molecules diffusion process and product formation [127,128]. Furthermore, robust electrostatic exchanges between anion and cation layers offer LDHs materials with an orderly organization for the interlayer classes and tailoring toward oriented active sites, thereby accelerating the dynamics for photogenerated electrons and holes and resulting in enhancement of the OER performance [129]. Further, some researchers have noted that coupling belonging to the LDH nanosheets associated with nanocarbons significantly reduced the commencement potential related to a commercial Ir/C catalyst, which in turn increased catalytic activity through the provision of a powerful electrical route with a higher surface area [130][131][132].
Hou et al. have progressed a N-deficient porous nature C 3 N 4 /N-doped graphene/NiFe-LDHs (DPCN/NG/NiFe-LDHs) aerogel photoanode, employing a superficial hydrothermal approach toward highly efficient PEC-OER, Figure 4a-e [56]. In a hybrid system, 3D NG has functioned in the form of an electron mediator toward shuttling photogenerated electrons and holes lying among N-deficient C 3 N 4 and NiFe-LDHs, thereby leading toward enhanced separation along with transferring effectiveness for photogenerated carriers. Moreover, a DPCN/NG/NiFe-LDHs photoanode exhibited optimal configuration in favor of PEC-OER through having a uniting beneficial relevance with every component inheriting the properties for 3D aerogels. Further, the photocurrent-density owing to the DPCN/NG/NiFe-LDHs moved to 72.9 µA cm −2 with 1.22 V against a RHE of OER irradiated with AM 1.5G, Figure 4f, and an IPCE of 2.5% at 350 nm.
On the other hand, to accelerate quickly for interfacial mass and electron transport toward photoelectrodes while carrying out the PEC-OER process, it is considered necessary that enormous carbon-based systems be developed. For example, Wu et al. fabricated a 2D GDY photoelectrode, with an active electron mediator via an air plasma strategy [133]. Afterward, the super hydrophilic GDY was electrostatically connected with CoAl-LDH nanosheets. The CoAl-LDH/GDY photoelectrode showed an enhancement in PEC-OER performance with an overpotential of 258 mV with 10 mA cm −2 and a TOF of 0.60 s −1 with 300 mV. Meanwhile, the IPCE associated with a photocurrent density owing to a CoAl-LDH/GDY/BiVO 4 hybrid exhibited an optimum value, which was~50% with 420 nm and~3.15 mA cm −2 with 1.23 V against RHE, respectively. The half-cell photoconversion performance of CoAl-LDH/GDY unified with BiVO 4 has been evaluated, significantly exhibiting an increment of 0.63% compared with alternative GDY-free and LDH-derived with BiVO 4 photoanodes, which was due to the drastic development of interfacial electron and mass transportation arising from the utility of a super hydrophilic GDY. The strong interaction between the GDY and CoAl-LDH resulted in an advantageous ability to absorb water molecules lying in a neighbor of catalysts, which in turn boosted up the PEC-OER performance. On the other hand, to accelerate quickly for interfacial mass and electron transp toward photoelectrodes while carrying out the PEC-OER process, it is considered nec sary that enormous carbon-based systems be developed. For example, Wu et al. fabricat a 2D GDY photoelectrode, with an active electron mediator via an air plasma strate [133]. Afterward, the super hydrophilic GDY was electrostatically connected with CoA LDH nanosheets. The CoAl-LDH/GDY photoelectrode showed an enhancement in PE OER performance with an overpotential of 258 mV with 10 mA cm −2 and a TOF of 0.60 with 300 mV. Meanwhile, the IPCE associated with a photocurrent density owing to CoAl-LDH/GDY/BiVO4 hybrid exhibited an optimum value, which was ~50% with 4 nm and ~3.15 mA cm −2 with 1.23 V against RHE, respectively. The half-cell photoconv sion performance of CoAl-LDH/GDY unified with BiVO4 has been evaluated, significan exhibiting an increment of 0.63% compared with alternative GDY-free and LDH-deriv with BiVO4 photoanodes, which was due to the drastic development of interfacial electr and mass transportation arising from the utility of a super hydrophilic GDY. The stro interaction between the GDY and CoAl-LDH resulted in an advantageous ability to a sorb water molecules lying in a neighbor of catalysts, which in turn boosted up the PE OER performance.
Depending upon the optimal PEC configurations, efficient nanocarbons/LDHs s tems also have displayed as energetic components that have been used supplementar for integrating with alternative semiconductors (TiO2, BiVO4, and Cu2O) to construct hig Depending upon the optimal PEC configurations, efficient nanocarbons/LDHs systems also have displayed as energetic components that have been used supplementarily for integrating with alternative semiconductors (TiO 2 , BiVO 4, and Cu 2 O) to construct high-performing three-component photoanodes [134][135][136][137][138][139][140][141]. For instance, Ning et al. presented a more suitable approach for constructing a hybridized PEC system to introduce RGO and NiFe-LDHs over TiO 2 nanorod arrays (NAs). Moreover, this approach not only developed a separation with the transportation belonging to photogenerated electrons and holes but also enhanced the PEC-OER performance, Figure 5e,f [142]. Initially, TiO 2 -NAs were steeply grown over a FTO substrate by employing a tailored hydrothermal strategy, and layered RGO was deposited on TiO 2 -NAs. Further, layered NiFe-LDH is consistently electrodeposited over TiO 2 /RGO NAs for fabricating TiO 2 /RGO/NiFe-LDH photoanodes. Moreover, the collective experimental and computational studies have revealed that with the addition of RGO, they become strongly capable of collecting the photogenerated electrons extracted from TiO 2 because of a large work function associated with high electron mobility, Figure 5d. This electron mobility is improved, and in turn ensures the NiFe-LDH functions effectively for OER electrocatalysts. The hybrid photoanode has offered a significant improvement in the photocurrent density of 1.74 mA cm −2 with 0.6 V and photoconversion activity of 0.58% with 0.13 V, which is considered superior as compared with TiO 2 -based photoanodes due to a synergistic effect Figure 5a. Further, it has been evaluated in support of a charge carrier separation performance of 98% with 0.6 V over TiO 2 /RGO/NiFe-LDH NAs, which have been significantly improved at 66% with 0.6 V over pure TiO 2 NAs. Meanwhile, the charge addition performance has been improved in favor of TiO 2 /RGO/NiFe-LDH, obtaining 95% along with 76% for simple TiO 2 -NAs, respectively, which infers a high efficiency toward PEC-OER activity. Additionally, a ternary hybrid photoanode has been exploited on an average basis for O 2 evolution yielding 15.5 mmol h −1 cm −2 attached with a Faradaic capability of 97%, Figure 5g, which has been determined to be 1.88 times greater as compared with the TiO 2 -NAs. These results have proved to introduce RGO and NiFe-LDH, revealing an apparent enhancement of the PEC-OER efficiency with a remarkable stability when irradiated with sunlight. The photo-induced electrons moved toward a RGO extraction of CB for TiO 2 with holes toward the NiFe-LDH extraction of valence band owing to the TiO 2 .
conversion activity of 0.58% with 0.13 V, which is considered superior as compared with TiO2-based photoanodes due to a synergistic effect Figure 5a. Further, it has been evaluated in support of a charge carrier separation performance of 98% with 0.6 V over TiO2/RGO/NiFe-LDH NAs, which have been significantly improved at 66% with 0.6 V over pure TiO2 NAs. Meanwhile, the charge addition performance has been improved in favor of TiO2/RGO/NiFe-LDH, obtaining 95% along with 76% for simple TiO2-NAs, respectively, which infers a high efficiency toward PEC-OER activity. Additionally, a ternary hybrid photoanode has been exploited on an average basis for O2 evolution yielding 15.5 mmol h −1 cm −2 attached with a Faradaic capability of 97%, Figure 5g, which has been determined to be 1.88 times greater as compared with the TiO2-NAs. These results have proved to introduce RGO and NiFe-LDH, revealing an apparent enhancement of the PEC-OER efficiency with a remarkable stability when irradiated with sunlight. The photo-induced electrons moved toward a RGO extraction of CB for TiO2 with holes toward the NiFe-LDH extraction of valence band owing to the TiO2. Depending upon a synergistic strategy, Xiang et al. integrated rGO-LDH-BiVO4 from assembling a 2D BiVO4 photoanode with CoAl-LDHs and graphene [143]. A good enhancement of the PEC-OER efficiency was achieved by employing the hybrid photoanode. The photocurrent density and IPCE of the rGO-LDH-BiVO4 photoanode were evaluated to be 2.13 mA cm −2 with 1.23 V vs. the RHE and 52% with 400 nm, which were 4.0 and 2.5 Depending upon a synergistic strategy, Xiang et al. integrated rGO-LDH-BiVO 4 from assembling a 2D BiVO 4 photoanode with CoAl-LDHs and graphene [143]. A good enhancement of the PEC-OER efficiency was achieved by employing the hybrid photoanode. The photocurrent density and IPCE of the rGO-LDH-BiVO 4 photoanode were evaluated to be 2.13 mA cm −2 with 1.23 V vs. the RHE and 52% with 400 nm, which were 4.0 and 2.5 times greater than those of the BiVO 4 photoanode, respectively. Consequently, these results revealed an enhancement related to the charging carrier separation performance, whereas water oxidation kinetics may have shown the main focus in favor of RGO with CoAl-LDH. Comparable to the above-mentioned TiO 2 /RGO/NiFe-LDH photoanode, the resulting charge transfer channels expressively abridged the carrier dynamics length with an effective suppression toward carrier recombination. The PEC-OER performance for the photoanode could be significantly progressed through the architecture of a triadic heterostructure. On the contrary, CDs have been utilized for substituting graphene in construction with a carbon-derived NiFe-LDHs@BiVO 4 photoanode [144]. The CDs reduce the charge transfer resistance and lower the overpotential in OER catalysis. To conclude, a ternary hybrid 2D photoanode has been explored with a significant enhancement in photocurrent associated with the IPCE value as that of NiFe-LDH/BiVO 4 . IPCE measurements at 380 nm for BiVO 4 , NiFe-LDH/BiVO 4 , CDs/BiVO 4 , and CDs/NiFe-LDH/BiVO 4 have been shown as being 19.17%, 22.97%, 24.59%, and 40.94%, respectively. During the same tenure, the CDs/NiFe-LDH/BiVO 4 hybrid photoanode showed high transformation activity of 0.58% with 0.82 V, thereby offering an extraordinary performance of the NiFe-LDH/BiVO 4 catalyst of 0.34% with 0.91 V, the CDs/BiVO 4 of 0.17% with 0.99 V, and the BiVO 4 of 0.09% with 0.96 V. Furthermore, despite a charge separation performance of 66.7% with 1.23 V owing to the CDs/NiFe-LDH/BiVO 4 possessing unattractive upgrading as compared with the alternative photoanodes, the charge injection performance was remarkably developed, increasing from 69.2% to 92.8% with 1.23 V. The result has significantly proposed that the reason for improvement in catalytic efficiency was because of a reduction in the OER overpotential as well as enhancing charge transportation kinetics. Meanwhile, the photo-induced holes may have gathered over the LDHs surface, and in turn resulted in overpotential attributed to the OER over solid-liquid interfacial contact that apparently rests on the energy barrier and reaction rate. Additionally, the decrement in OER overpotential may have recovered the PEC-OER efficiency.

Construction of Multicomponent Heterojunctions
For the improvement regarding PEC efficiency for photoelectrodes and to construct a multicomponent 2D-layered bulky heterojunction (BHJ) nature, photoelectrodes have also been reasonably examined [145][146][147]. A hexanoic acid and functionalized perylene-diimide (DHA-PDI) derived composite has been offered for the formation of a hybridized ultrathinfilm type photoelectrode associated with a MoS 2 atomically layered-nature, thereby leading to the form of a valuable type-II band configuration [146]. A TEM indicated the MoS 2 /DHA-PDI hybridized bilayer thin film, Figure 6a. The creation corresponding to an interfacial dipole over a MoS 2 -organic interfacial contact has been significantly exhibited. It has also been proposed that type-II band alignment existing among the MoS2 inorganic layered nature and organic DHA-PDI led toward an efficient charge isolation and an improvement in light absorption, Figure 6b.
The hybridized MoS 2 /DHA-PDI photoelectrode has introduced a six-fold formation into the photocurrent. With the substitution of MoS 2 for the MoSe 2 , thereby introducing a MoSe 2 /DHA-PDI photoelectrode, a slight increment in photocurrent was observed. This may be attributed to a great existing VB corner of the MoSe 2 , thereby creating a barrier to transfer holes toward the MoSe 2 /DHA-PDI interfacial contact (Figure 6b). These observations revealed great performance owing to the band alignment for the efficiency attributed to TMDC-derived heterojunctions, particularly for PEC applications. In the same way, Mattevi et al. prepared TMDCs/TMDCs type-II BHJ transparent photoelectrodes comprising of a WS 2 and MoS 2 atomically layered nature, Figure 6d,e, thereby achieving a 10 times increment in IPCE as compared to that of the sole ingredients [147]. The photocurrent produced through the WS 2 /MoS 2 BHJ has been revealed as being one order of degree greater than of MoS 2 electrodes and two times greater than of WS 2 electrodes, Figure 6f. The previous increment has been ascribed to the spatially charged isolation that occurred at the moment of the WS 2 and MoS 2 layers' interfacial contact to form a type-II junction. Moreover, the exciton was dissociated, and therefore holes were migrated toward the VB owing to the WS 2 layers during the transformation of electrons toward the CB belonging to the MoS 2 layers (Figure 6e). Owing to monolayer TMDCs, the significant occurrence was revealed during a short interval of time as 30-50 fs, that is considered as the shortest as compared to that of the intralayer reduction procedure as ca. 10 ps, belonging to a possibly trapped process through intrinsic defects as 0.6-5 ps, thereby giving a result in the form of an efficiently charged carrier isolation [148,149]. The current time for the interlayer excitons residing in the MoS 2 /WS 2 and MoSe 2 /WSe 2 heterojunctions was forecast along with observations taken to be in nanosecond scaling to confirm the exclusive potential for the construction of TMDCs heterostructures for applications, particularly for solar energy alteration [150]. The hybridized MoS2/DHA-PDI photoelectrode has introduced a six-fold formation into the photocurrent. With the substitution of MoS2 for the MoSe2, thereby introducing a MoSe2/DHA-PDI photoelectrode, a slight increment in photocurrent was observed. This may be attributed to a great existing VB corner of the MoSe2, thereby creating a barrier to transfer holes toward the MoSe2/DHA-PDI interfacial contact (Figure 6b). These observations revealed great performance owing to the band alignment for the efficiency attributed to TMDC-derived heterojunctions, particularly for PEC applications. In the same way Mattevi et al. prepared TMDCs/TMDCs type-II BHJ transparent photoelectrodes comprising of a WS2 and MoS2 atomically layered nature, Figure 6d-e, thereby achieving a 10 times increment in IPCE as compared to that of the sole ingredients [147]. The photocurrent produced through the WS2/MoS2 BHJ has been revealed as being one order of degree greater than of MoS2 electrodes and two times greater than of WS2 electrodes, Figure 6f The previous increment has been ascribed to the spatially charged isolation that occurred at the moment of the WS2 and MoS2 layers' interfacial contact to form a type-II junction Moreover, the exciton was dissociated, and therefore holes were migrated toward the VB owing to the WS2 layers during the transformation of electrons toward the CB belonging Ho et al. have reported an electrostatic and unified 2D hetero-layered-hybridized composite containing an atomically layered nature of MoSe 2 and ZnIn 2 S 4 , which has been observed for improving the visible range of light photoreactivity, and efficiently charged transformation along with close interface connection to create stability in the cycling process [151]. Concerning the band structures of ZnIn 2 S 4 and MoSe 2 , the photogeneration of electrons originating from the exciton for the ZnIn 2 S 4 was thermodynamically excited to transfer toward the MoSe 2 . This indicated that the ZnIn 2 S 4 -MoSe 2 hetero and layered form structure accelerated the charge carrier isolation at the interfacial contact associated with the facilitation of proton drop over the surface of the MoSe 2 , caused by the regular ability of TMDC layers containing visible edge locations toward an effective decrement for activation energy revealing an overpotential concerning the redox reactions. Moreover, time resolving and steady stating PL spectra associated with an electrochemical impedance spectra (EIS), displayed spontaneous PL quenching, along with a lifetime reduction, and a decrement for the charge transfer resistance of the ZnIn 2 S 4 -MoSe 2 layers extracted with a bulky ZnIn 2 S 4 complement. This indicates the formation was relevant with electron transferring channels originating from the ZnIn 2 S 4 toward the MoSe 2 along with a nonradiative quenching channel, caused by the resultant efficiency due to an interface charge transformation and destruction for the charge carrier recombination existing in the ZnIn 2 S 4 -MoSe 2 hetero-layered form. Jointly, the ZnIn 2 S 4 -MoSe 2 composite has revealed nearly a 22fold photocurrent improvement as compared to bulky ZnIn 2 S 4 under a similar environment, confirming the structure along with composition advantages of the ZnIn 2 S 4 -MoSe 2 heterolayers for promoting charge transportation as well as separation.

Surface Functionalization
Associated photosensitizer molecules have been comprehended by merely dropcasting phthalocyanine/porphyrin mixers over TMDC films [152] or dipping TMDC films into solution for 15 to 20 min [153,154]. Choi et al. presented a typically monolayerednature WSe 2 -NiPc (Ni-oriented phthalocyanine) mechanism [153]. PL signals of WSe 2 were steadily quenched onto successive stages for 10 mM NiPc activation. During the same period, normalizing PL intensities were reduced associated with an increment in the partial surface exposure unified with NiPc, by proposing a high surface exposure, thereby leading to an increment in probability owing to the photo-induced charge carrier transport, which in turn revealed PL quenching over the NiPc activation. Additionally, the quenching PL production was totally improved at the time of removal of the NiPc molecules from the WSe 2 surfaces, which could be reactivated in the recycling of repeated times. Additionally, chemical-exfoliation with a large-area of MoS 2 ultrathin films interfaced with various porphyrin types with PEC properties have been examined [154].
It has been evaluated that photocurrents are strictly attached with HOMO and with LUMO altitudes owing to porphyrins. Through MoS 2 surface functionalization with zincoriented protoporphyrin IX, a 10-fold photocurrent increment was achieved. With the selection of phthalocyanine/porphyrin species with the proper band alignment relating to TMDCs, effective isolation occurred for reactive holes toward the OER and electrons toward the HER for SEJ interfacial contact [152]. The achievements exhibited magnitudes and signs owing to photocurrents that may have been anodic or cathodic, that have been explored through the concerning band energies existing among TMDCs, and the HOMO/LUMO stages of zinc protoporphyrin (ZnPP). As an example, the CB and VB edging positions for ZnPP are greater than MoS 2 and WS 2 , generating holes originated by the excitation for MoS 2 and WS 2 . It is supposed to be thermal transportation toward ZnPP and from there photoelectrons traveling from the hind contact toward a counter electrode, which in turn lead prominently to improving the photoanodic effect. Moreover, the anodic photocurrent related with the ZnPP-MoS 2 has been evaluated as being two times greater than the ZnPP-WS 2 , thereby attributed to a greater accelerating force of extraction with a higher variance with respect to the energy levels existing among MoS 2 and ZnPP. Similarly, concerning ZnPP-MoSe 2 and ZnPP-WSe 2 architecture, there is an observed cathodic photocurrent caused by the VBs of MoSe 2 and WSe 2 , reflecting levels greater than that of the HOMO energy levels of ZnPP [152]. This interfacial architecture strategy has offered novelty to improve the PEC efficiency for TMDC-dependent photoelectrodes.

Formation of Heterostructures
The merging of TMDC layers for BHJ photoelectrodes containing graphene derivatives (NG, RGO, and g-C 3 N 4 ) for PEC applications have prominently been described [90,[155][156][157]. Narayanan et al. have displayed the molecular foundation owing to layered ranking/stacking sequentially depending on the PEC activity rendering into a MoS 2 /graphene van der Waals vertical architecture, Figure 7 [156]. Further, they have explored the existence of MoS 2 that may influence p-type doping into graphene, thereby facilitating additional H 2 absorbance over the graphene location rather than that of the MoS 2 location, maximizing the efficiency of the graphene associated with monolayer MoS 2, which is additionally reduced, attributed to bilayers as well as multilayers owing to the MoS 2 . Further, the graphene existence over the monolayer MoS 2 , in the form of a stacking sequence, showing the optimum photocurrent density along with beneath charge transferring resistance toward the HER, has been observed. The observations mentioned above have produced an association for a stacking sequence into PEC efficiency belonging to TMDC/graphene hybridized Van der Waal layers. ranking/stacking sequentially depending on the PEC activity rendering into a MoS2/g phene van der Waals vertical architecture, Figure 7 [156]. Further, they have explored existence of MoS2 that may influence p-type doping into graphene, thereby facilitat additional H2 absorbance over the graphene location rather than that of the MoS2 locati maximizing the efficiency of the graphene associated with monolayer MoS2, which is ditionally reduced, attributed to bilayers as well as multilayers owing to the MoS2. F ther, the graphene existence over the monolayer MoS2, in the form of a stacking sequen showing the optimum photocurrent density along with beneath charge transferring sistance toward the HER, has been observed. The observations mentioned above h produced an association for a stacking sequence into PEC efficiency belonging TMDC/graphene hybridized Van der Waal layers. Shin et al. [157] have examined an ideal hybrid system containing 1T-MoS2/2 MoS2/2H-WS2/RGO multi-layers. It was significantly detected for 1T-MoS2 layers cont uting to the catalytic performance of HER. The hybrid nature owing to 2H-MoS2 and 2 WS2, involving various band structures, facilitates effective charge carrier dynamics fa itated with a promising band alignment. RGO nanosheets in the form of a conductiv unified network to promote charge isolation have been offered. Consequently, the r vant constituents have been occasioned efficiently toward PEC efficiency for optimu hybridized ultrathin film photocathodes. Additionally, for graphene derivatives, few-l ered black phosphorus (BP), being the subject of novel research attention toward the materials family, has also been associated with TMDCs such as WS2, and has showed improvement in photocurrent retorts at 4780 nm irradiated with near-infrared [158]. Shin et al. [157] have examined an ideal hybrid system containing 1T-MoS 2 /2H-MoS 2 /2H-WS 2 /RGO multi-layers. It was significantly detected for 1T-MoS 2 layers contributing to the catalytic performance of HER. The hybrid nature owing to 2H-MoS 2 and 2H-WS 2, involving various band structures, facilitates effective charge carrier dynamics facilitated with a promising band alignment. RGO nanosheets in the form of a conductively unified network to promote charge isolation have been offered. Consequently, the relevant constituents have been occasioned efficiently toward PEC efficiency for optimum, hybridized ultrathin film photocathodes. Additionally, for graphene derivatives, fewlayered black phosphorus (BP), being the subject of novel research attention toward the 2D materials family, has also been associated with TMDCs such as WS 2 , and has showed an improvement in photocurrent retorts at 4780 nm irradiated with near-infrared [158].
For BP/WS 2 systems, Majima et al. have presented a CB and VB edge location for BP that have been assessed as ca.~0.18 and 0.52 eV vs. NHE, irradiated with nearinfrared range and excitation caused by a narrowed bandgap. The narrow bandgap may essentially result in a fast charge recombination attributed to the BP. Nevertheless, due to interaction with WS 2 , the electrons in the CB for BP might be proficiently included in the WS 2 layers, caused by a lower work function attributed to WS 2 indicating as 1.07 eV vs. NHE. Adequate electrons are trapped toward the WS 2 , thereby reducing the protons (H + ) in water leading to HER. The charge isolation mechanism has been explored through PEC measurements, with an electron reduced reaction investigation as well as transitory fascination spectroscopy. Consequently, while involving ethylenediaminetetraacetic acid in the form of an artificial mediator to trap holes, the BP/WS 2 hybrids obtained a 21and 50-times improvement in HER performance as compared to that of bare BP and WS 2 , respectively. Therefore, there are benefits to consider owing to the BP/WS 2 hybridized layers behaving like photoelectrodes that are noble metal-free and irradiated close to the infrared region, along with photocatalytic materials offering novel chances while catching a wide range solar spectrum-band toward energy renovation. Collectively, the reports have identified novel routes to modulate PEC efficiency while offering novelty into TMDC layered dependent photoelectrodes associated with suggested opportunities for effective progress attributed to transparent, larger area and lower cost, solar-energy transformation devices.

Theoretical Aspects
H 2 and O 2 generation by splitting water is considered a sustainable solution to solve the energy crisis. The overall splitting of water includes two self-governed reactions: HER and OER at the cathodic and anodic sides, respectively. HER is a two-electron transfer process (2 H + + 2 e → H 2 ), and OER is a four-electron transfer process (acidic condition: 2 H 2 O + O 2 → 4 H + + 4 e or alkaline condition: 4 OH − + O 2 → 2 H 2 O + 4 e). Thus, it requires that electrocatalysts should have an efficient performance in both HER and OER, being the different reaction kinetics between the two electrodes in overall water splitting. To design these bifunctional catalysts, emerging composite heterostructures may show great potential in combining the synergic effect of different components to boost catalytic performances. Therefore, a variety of composite heterostructures of 0D-1D, 0D-2D, 1D-2D, and 2D-2D have been developed in the water-splitting attributed to the electron transfer and conductivity in heterostructures that can be improved by a suitable combination of two constitutions. For example, the 0D-1D heterostructure of C 60 and SWCNTs can induce the intermolecular charge-transfer, [159] which trigger the inert C material to become active. Liu et al. reported the combination of a 1D-CNT with a thienothiophene-pyrene covalent organic framework (COF) for OER. It found that the charge transfer barrier from the CNT to COF at the heterointerface was tailored by the thickness of the 2D COF shell, [160] resulting in an enhanced OER activity.
Although the HER process is simpler than OER, it still challenging in an alkaline system. In an alkaline media, the HER activity is determined by the activation and dissociation of H 2 O to form hydrogen intermediates (H 2 O + e + * → H* + OH − ). Thus, the catalysts for HER should not only show a near-zero Gibbs free energy of the adsorbed hydrogen but also exhibit a good capacity to break the H-OH bonds effectively. Jiang et al. prepared a 0D-2D heterostructure Ru 2 P/WO 3 @NPC (NPC: N, P co-doped carbon), showing a superior HER performance in an alkaline media [161]. The HO-H bonds can be effectively cleaved by W atoms at the heterointerface, meanwhile the hydrogen adsorption and desorption favor at Ru sites to form a H 2 product. Further, dissimilar 2D nanosheets were investigated as multifunctional electrocatalysts in the fast kinetics and durable water splitting due to their large surface area and high redox capacity by high-speed charge separation and transfer at vertical and lateral heterointerfaces. Of note, some 2D material itself showed inferior catalytic activity or poor stability in the HER and OER due to its low density of active sites, limited electrical conductivity, and instability. Dai et al. assembled a 2D-2D EBP/NG heterostructure as an electrolyte for the overall water splitting in alkaline solutions [162]. The large work function of BP triggers the electron transfer from NG to the BP active sites, resulting in the charge redistribution at the 2D-2D heterointerface. The electron accumulated BP nanosheet not only efficiently reduced the hydrogen adsorption energy to give H 2 but also optimized the binding strength of OER intermediates to improve the OER kinetics in the overall water splitting. Note that the stability of BP was largely enhanced by an NG nanosheet in the hybrid heterostructure.
On the other hand, covalently bonded heterointerfaces can solve the weak structural stability of heterostructures through van der Waals and limited changing of the electronic property. A covalent heterostructure of NiO and Ni nanosheets onto an Ag nanowire network displayed high HER performance and catalytic stability in alkaline media [163]. The different materials were covalently bonded together to form a heterointerface, which facilitated electron migration and the separation of charge carriers through covalent-bonds. The modified electronic property of Ni and O sites near the heterointerface rendered a high intermediate affinity to OH* and H* species and gave a nearly barrier-free water dissociation. Furthermore, when a Pt single atom was doped at the heterointerface of the Ni/NiO, a Pt site with a locally enhanced electric field induced a higher Pt 5d occupation at the Fermi level that offered a favorable hydrogen adsorption energy. This concept of anchoring heteroatoms on an appropriate substrate can be well expanded to design efficient multi-functional catalysts.
Theoretical aspects have also provided some guidance to design bifunctional heterostructure electrocatalysts for overall water-splitting, such as (i) suitable integration of two distinct materials to generate a heterostructure, taking advantage for HER on one component and for OER on the other, and (ii) composition manipulation at the heterointerface (including doping, adding linkers, vacancies, etc.) to modify the electronic property of electrocatalysts. In one word, these aspects are aimed at turning the charge distribution at the heterointerface which modulates the intermediate binding and then boosts the kinetics of both HER/OER during overall water-splitting [164,165].

Conclusions, Challenges, and Future Perspective
The solar-oriented PEC significantly representing water splitting systems has been denoted as a superior faculty for the conversion of solar energy in the shape of cleaning as well as sustainable chemical energy generation. The PEC mechanisms mentioned above denote an integrated photoelectrode, thereby incorporating light-harvesting for absorbing solar energy sources while offering interlayered transformation belonging to photogenerated charge carriers associated with catalysts during the triggering of redox chemical reactions. In detailed discussion, the novelty into 2D layered photoanodes and photocathodes, especially and prominently for GCNs, TMDC, LDH, MXenes, and co-catalysts, for assembling in a collective form of photoelectrodes offering oxygen and hydrogen growth chemical reactions was reported. In addition, very intrinsic principles attributed to PEC owing to the water splitting mechanisms containing physicochemical properties for photoelectrodes, therefore involving specific catalytic reactions, have also been analyzed. The attributed interconnection among the 2D photoelectrodes is too detailed in supplementary analysis. The improvement strategies include the construction of heterostructures, surface functionalization, and formations of heterojunctions that have also been discussed.
The effective optimizing principles, such as metal-free nanocarbons as that of 0D CDs, 1D CNTs, 2D graphene as well as 2D GDYs, have been utilized in the form of electron mediators for improving the isolation and transportation proficiencies for photogenerated electrons and holes owing to high performing PEC systems for water splitting. Meanwhile, the authentic art of synthesis along with characterizations for 2D photoelectrodes hybridnanocarbons for highly efficient PEC water splitting has been significantly studied. In this regard, g-C 3 N 4 material has been as extensively reviewed as that of photoelectrodes because of possession of an exclusive layered structure, reasonable bandgap, whereas a proper negative conduction band is attributed to HER. The g-C 3 N 4 performs as a supporting material for harvesting solar energy as well as an effective electrocatalyst for driving electrocatalytic HER. To develop PEC-HER efficiency, graphene associated with CDs has been repeatedly involved in g-C 3 N 4 for enhancing the isolation and transportation performance owing to photogenerated charge carriers. Similarly, for g-C 3 N 4 being utilized alone, TMDC particularly of MoS 2 , and the HER catalysts too, meet a poor separation as well as a severe recombination that belongs to the photogenerated charge carriers. To avoid these difficulties, a chain of nanocarbons such as that of graphene or CNTs inherited with a higher charge mobility in the form of co-catalysts, have been offered as solutions for assembling photocathodes, thereby exhibiting a significant progress toward PEC-HER performance. Moreover, despite emerging MXenes along with metallic conductivities and higher exposing metal sites, that exhibit strong redox activity toward HER and thereby show isolation and transportation efficiency owing to photogenerated charge carriers, there yet needs to be considerable improvement. Thus, nanocarbons such as CNTs, being co-catalysts as well as electron mediators, have been involved in MXenes for promoting the charge carrier isolation and transformation in photocathodes to enhance the PEC-HER performance that is illuminated by light.
Apart from the aforementioned g-C 3 N 4 , TMDCs, along with the MXenes for a competent HER, the LDHs are introduced as Ru or Ir-free photoelectrodes to achieve higher PEC-OER activity, caused by the LDHs materials containing transition metals such as Fe, Co, and Ni. Further, these metals enable the PEC-OER to be comparatively lower overpotentials, which in turn accelerate the water splitting. More importantly, LDH materials significantly retain a tunable chemical composition through changing ratios owing to various cations, porous-like nanostructures associated with a specific surface area, with high exposing active sites along with higher catalytic reaction rates, and a higher structural stability. Due to these qualities, the varied LDHs-based photoanodes using nanocarbons have been investigated. These aforesaid observations have explored significant performances to improve PEC water splitting as compared with that of bare LDHs photoanodes. Meanwhile, bismuth oxyhalide (BiOI) has been numerously utilized as a light absorber toward PEC-OER and because of it possessing a semiconducting nature, it shows a sufficient positive valence band, whereas photoinduced holes associated with a strong oxidative ability may substantially oxidize water for producing O 2 . Hence, these bismuth oxyhalides have been combined with layered nanocarbons, such as graphene and GDY (co-catalysts) for forming hybridized photoanodes, which in turn may achieve the targeted goal toward PEC-OER performance. Not only attractive achievements have been gained to increase the PEC-HER as well as the PEC-OER performances through the coupling of photoelectrodes along with nanocarbon co-catalysts, to date; however, the performance of supporting materials with nanocarbons for heterostructured photoelectrodes are still not completely implicit, caused by a lack of reasonable experimental suggestions along with adequate theoretical understandings. Consequently, comprehensive knowledge toward reactive mechanisms is considered as a feasible route while designing and fabricating a highly efficient performance of integrated photoelectrodes toward water splitting.
Recently, direct comparative studies of PEC-HER/OER presentations among a variety of nanocarbons-based photoelectrodes with metal clusters [166][167][168][169] have shown a fairly challenging situation due to the compositions, quantities, and testing parameters, thereby prominently affecting PEC outcomes. Therefore, there is an immense need for test principles as well as particular conditions for PEC-HER/OER to be unified in the coming years. Furthermore, the synthesis approaches owing to photoelectrodes and nanocarbons have been considered as the basic determinants toward final water splitting performances. Therefore, there should be an obligation for developing variously feasible and integrated synthetic protocols, such as that of the electrochemical or hydrothermal routes to compare and find an optimally desired material system. In all, it is a promising approach for translating the laboratory-based research and the extensive marketable applications in favor of PEC-HER/OER developments.
Funding: This research received no external funding.

Institutional Review Board Statement:
The study was conducted in accordance with the Declaration of Helsinki, and approved by the Institutional Review Board.

Conflicts of Interest:
The authors declare no conflict of interest.