Amorphous oxygen-rich molybdenum oxysulfide Decorated p-type silicon microwire Arrays for efficient photoelectrochemical water reduction

Bao, Xiaoguang; Petrovykh, Dmitri Y.; Alpuim, P.; Stroppa, Daniel G.; Guldris, Noelia; Fonseca, Hélder; Costa, Margaret; Gaspar, J.; Jin, Chuanhong; Liu, Lifeng

doi:10.1016/j.nanoen.2015.06.014

Cited by 85 publications

(73 citation statements)

References 69 publications

(117 reference statements)

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“…Using PECD, other HER catalysts, e.g., MoS x O y , CoMoS x , NiCoSe x , and CoP, have also been reported to couple to different photocathodes for light‐driven H 2 production. In many cases, the catalyst layers are usually directly photodeposited on semiconductor photoelectrodes without introducing an interlayer, and they offer, besides high catalytic activity, good passivation to semiconductors against corrosion given their exceptional electrochemical stability, exhibiting promising bi‐functionality.…”

Section: Strategies For Semiconductor/electrocatalyst Couplingmentioning

confidence: 99%

Strategies for Semiconductor/Electrocatalyst Coupling toward Solar‐Driven Water Splitting

et al. 2020

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Hydrogen (H2) has a significant potential to enable the global energy transition from the current fossil‐dominant system to a clean, sustainable, and low‐carbon energy system. While presently global H2 production is predominated by fossil‐fuel feedstocks, for future widespread utilization it is of paramount importance to produce H2 in a decarbonized manner. To this end, photoelectrochemical (PEC) water splitting has been proposed to be a highly desirable approach with minimal negative impact on the environment. Both semiconductor light‐absorbers and hydrogen/oxygen evolution reaction (HER/OER) catalysts are essential components of an efficient PEC cell. It is well documented that loading electrocatalysts on semiconductor photoelectrodes plays significant roles in accelerating the HER/OER kinetics, suppressing surface recombination, reducing overpotentials needed to accomplish HER/OER, and extending the operational lifetime of semiconductors. Herein, how electrocatalyst coupling influences the PEC performance of semiconductor photoelectrodes is outlined. The focus is then placed on the major strategies developed so far for semiconductor/electrocatalyst coupling, including a variety of dry processes and wet chemical approaches. This Review provides a comprehensive account of advanced methodologies adopted for semiconductor/electrocatalyst coupling and can serve as a guideline for the design of efficient and stable semiconductor photoelectrodes for use in water splitting.

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Section: Strategies For Semiconductor/electrocatalyst Couplingmentioning

confidence: 99%

Strategies for Semiconductor/Electrocatalyst Coupling toward Solar‐Driven Water Splitting

et al. 2020

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“…Even though 2H semiconducting MoS 2 has been investigated for Li + intercalation, water splitting, and catalysis, this is the first application of 1T MoS 2 for Na + intercalation. The obtained 1T MoS 2 electrode has a high reversible capacity of 313 mAh g −1 at a current density of 0.05 A g −1 after 200 cycles and a capability of 175 mAh g −1 at a high current density of 2 A g −1 .…”

Section: Introductionmentioning

confidence: 99%

Freestanding Metallic 1T MoS₂ with Dual Ion Diffusion Paths as High Rate Anode for Sodium‐Ion Batteries

Geng

Jiao

Yang

et al. 2017

Adv Funct Materials

280

164

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This work studies for the first time the metallic 1T MoS 2 sandwich grown on graphene tube as a freestanding intercalation anode for promising sodiumion batteries (SIBs). Sodium is earth-abundant and readily accessible. Compared to lithium, the main challenge of sodium-ion batteries is its sluggish ion diffusion kinetic. The freestanding, porous, hollow structure of the electrode allows maximum electrolyte accessibility to benefit the transportation of Na + ions. Meanwhile, the metallic MoS 2 provides excellent electron conductivity. The obtained 1T MoS 2 electrode exhibits excellent electrochemical performance: a high reversible capacity of 313 mAh g −1 at a current density of 0.05 A g −1 after 200 cycles and a high rate capability of 175 mAh g −1 at 2 A g −1 . The underlying mechanism of high rate performance of 1T MoS 2 for SIBs is the high electrical conductivity and excellent ion accessibility. This study sheds light on using the 1T MoS 2 as a novel anode for SIBs.

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“…26 We thus report an effective method to improve the time stability of the photocathode by using the electrostatic entrapment of the negatively charged thio-POM into a cationic polymer film, namely poly(3,4-ethylenedioxythiophene) (PEDOT). This method is applied on microstructured silicon surfaces 12,17,27,28 in order to considerably improve light absorption to yield robust photocathodes with appreciable solar-driven HER activity observed above 0 V vs Reversible Hydrogen Electrode (RHE). (Figure 1).…”

Section: Introductionmentioning

confidence: 99%

Molecular and Material Engineering of Photocathodes Derivatized with Polyoxometalate-Supported {Mo₃S₄} HER Catalysts

et al. 2019

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Molecular engineering of efficient HER catalysts is an attractive approach for controlling the spatial environment of specific building units selected for their intrinsic functionality required within the multistep HER process. As the {Mo 3 S 4 } core derived as various coordination complexes has been identified as one as the most promising MoS xbased HER electrocatalysts, we demonstrate that the covalent association between the {Mo 3 S 4 } core and the redox-active macrocyclic {P 8 W 48 } polyoxometalate (POM) produces a striking synergistic effect featured by high HER performance. Various experiments carried out in homogeneous conditions showed that this synergistic effect arises from the direct connection between the {Mo 3 S 4 } cluster and the toroidal {P 8 W 48 } units featured by a stoichiometry which can be tuned from two to four {Mo 4 S 4 } cores per {P 8 W 48 } unit. In addition, we report that this effect is preserved within heterogeneous photoelectrochemical devices where the {Mo 3 S 4 }-{P 8 W 48 } (thio-POM) assembly was used as co-catalyst (cocat) onto a microstructured p-type silicon. Using drop-casting procedure to immobilize cocat onto the silicon interface led to high initial HER performance under simulated sunlight achieving a photocurrent density of 10 mA.cm-2 at +0.13 V vs RHE. Furthermore, electrostatic incorporation of the thio-POM anion cocat into a poly(3,4-ethylenedioxythiophene) (PEDOT) film is demonstrated to be efficient and straightforward to durably retain the cocat at the interface of a micropyramidal silicon (SimPy) photocathode. The thio-POM/PEDOT-modified photocathode is able to produce H 2 under 1 Sun illumination at a rate of ca. 100 µmol cm-2 h-1 at 0 V vs RHE, highlighting the excellent performance of this photoelectrochemical system.

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Amorphous oxygen-rich molybdenum oxysulfide Decorated p-type silicon microwire Arrays for efficient photoelectrochemical water reduction

Cited by 85 publications

References 69 publications

Strategies for Semiconductor/Electrocatalyst Coupling toward Solar‐Driven Water Splitting

Strategies for Semiconductor/Electrocatalyst Coupling toward Solar‐Driven Water Splitting

Freestanding Metallic 1T MoS₂ with Dual Ion Diffusion Paths as High Rate Anode for Sodium‐Ion Batteries

Molecular and Material Engineering of Photocathodes Derivatized with Polyoxometalate-Supported {Mo₃S₄} HER Catalysts

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Amorphous oxygen-rich molybdenum oxysulfide Decorated p-type silicon microwire Arrays for efficient photoelectrochemical water reduction

Cited by 85 publications

References 69 publications

Strategies for Semiconductor/Electrocatalyst Coupling toward Solar‐Driven Water Splitting

Strategies for Semiconductor/Electrocatalyst Coupling toward Solar‐Driven Water Splitting

Freestanding Metallic 1T MoS2 with Dual Ion Diffusion Paths as High Rate Anode for Sodium‐Ion Batteries

Molecular and Material Engineering of Photocathodes Derivatized with Polyoxometalate-Supported {Mo3S4} HER Catalysts

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Freestanding Metallic 1T MoS₂ with Dual Ion Diffusion Paths as High Rate Anode for Sodium‐Ion Batteries

Molecular and Material Engineering of Photocathodes Derivatized with Polyoxometalate-Supported {Mo₃S₄} HER Catalysts