Boron Doping of Metal-Doped Hematite for Reduced Surface Recombination in Water Splitting

Ahn, Hyo-Jin; Yoon, Ki Hyun; Kwak, Myung-Jun; Park, Juhyung; Jang, Ji‐Hyun

doi:10.1021/acscatal.8b03184

Cited by 88 publications

(60 citation statements)

References 55 publications

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“…Third, the preservation of high electrical conductivity in the bulk (by high concentration Ta 5+ dopants) promotes the rapid separation of photogenerated charge carriers. Besides, n + -n homojunction by heavily and slightly doped Ta 5+ in the core and shell parts provides a supplemental charge separation by an increased built-in electric field 39 . Finally, the gradient Ta dopants benefits the smooth flow of the separated charge carriers as schematically shown in Supplementary Fig.…”

Section: Resultsmentioning

confidence: 99%

Gradient tantalum-doped hematite homojunction photoanode improves both photocurrents and turn-on voltage for solar water splitting

et al. 2020

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Hematite has a great potential as a photoanode for photoelectrochemical (PEC) water splitting by converting solar energy into hydrogen fuels, but the solar-to-hydrogen conversion efficiency of state-of-the-art hematite photoelectrodes are still far below the values required for practical hydrogen production. Here, we report a core-shell formation of gradient tantalum-doped hematite homojunction nanorods by combination of hydrothermal regrowth strategy and hybrid microwave annealing, which enhances the photocurrent density and reduces the turn-on voltage simultaneously. The unusual bi-functional effects originate from the passivation of the surface states and intrinsic built-in electric field by the homojunction formation. The additional driving force provided by the field can effectively suppress charge–carrier recombination both in the bulk and on the surface of hematite, especially at lower potentials. Moreover, the synthesized homojunction shows a remarkable synergy with NiFe(OH)x cocatalyst with significant additional improvements of photocurrent density and cathodic shift of turn-on voltage. The work has nicely demonstrated multiple collaborative strategies of gradient doping, homojunction formation, and cocatalyst modification, and the concept could shed light on designing and constructing the efficient nanostructures of semiconductor photoelectrodes in the field of solar energy conversion.

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Section: Resultsmentioning

confidence: 99%

Gradient tantalum-doped hematite homojunction photoanode improves both photocurrents and turn-on voltage for solar water splitting

et al. 2020

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“…[117] Plenty of attention has been drawn to the development of composite hematite photoanodes with doping or secondary semiconductors, to further enhance the PEC water oxidation efficiency. [106][107][108][109][110][111][112][113][114][115][116] Meanwhile, other researchers spared no effort in correlating PEC performance improvement with the surface states evolution upon doping or coating of a secondary semiconductor onto hematite photoanodes. [117][118][119][120][121][122][123][124][125][126][127][128] For instance, D. Monllor-Satoca et al prepared mesoporous hematite-titania composite films by mixing the respective preformed nanoparticles obtained by a non-aqueous solgel route in a wide range of loading levels (0-20 mol %).…”

Section: Kinetic Isotope Effect (Kie)mentioning

confidence: 99%

Engineering surface states of hematite based photoanodes for boosting photoelectrochemical water splitting

Tang

Arbiol

2019

Nanoscale Horiz.

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“…The presence of natural mineral reserves and mining activity represents an advantage if hematite is used in PEC photoanodes, since the demand could be supplied by the countries that explore iron sources. To overcome well‐known intrinsic deficiencies of hematite associated with their electronic limitation that make the real response fall short of the predicted theoretical efficiency into solar to hydrogen conversion, different elements, such as: Ti, 18 V, 19 Sb, 20,21 P, 22 Cr, 23 B, 24,25 Ge, 26 and Sn, 27–32 and combinations like Nb‐Sn, 33 Ti‐Mg, 34 and Co‐Sn, 35 have been successfully employed. Sn has been highlighted as a potential modifier for this semiconductor polycrystalline ceramic, since it has been reported as able to improve the separation of photogenerated charges, achieving the highest photocurrent values among hematite photoanodes with different morphologies 36–38 .…”

Section: Introductionmentioning

confidence: 99%

Revealing the synergy of Sn insertion in hematite for next‐generation solar water splitting nanoceramics

Bedin

Freitas

Tofanello

et al. 2020

Int J Ceramic Engine & Sci

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Solar water splitting-driven hydrogen fuel production is very attractive due to positive aspects as higher energy density and a renewable energy source arising from water and sunlight. 1 Despite these remarkable overall strengths, sustainable largescale clean hydrogen production is quite far from being available, in particular by the lack of efficient and economically viable electrodes for photoelectrochemical (PEC) cells. These devices involve two redox electrochemical reactions: hydrogen evolution on the cathode and oxygen evolution on the anode, where one or more photosensitive material can be enforced in the device design. 2 It is worth mentioning that oxygen evolution reaction (OER) is the rate-determining step of the photoelectrochemical water splitting, because of the four-electron reaction mechanism of water oxidation, which

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Boron Doping of Metal-Doped Hematite for Reduced Surface Recombination in Water Splitting

Cited by 88 publications

References 55 publications

Gradient tantalum-doped hematite homojunction photoanode improves both photocurrents and turn-on voltage for solar water splitting

Gradient tantalum-doped hematite homojunction photoanode improves both photocurrents and turn-on voltage for solar water splitting

Engineering surface states of hematite based photoanodes for boosting photoelectrochemical water splitting

Revealing the synergy of Sn insertion in hematite for next‐generation solar water splitting nanoceramics

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