Thermally-enhanced charge collection boosts photoelectrochemical performance of hematite

doi:10.1088/1674-1056/ae37fc

Abstract The application of transition metal oxides in optoelectronics holds significant promise. However, their performance is often limited by small polaron hopping, a charge transport mechanism that reduces carrier mobility and collection efficiency. Therefore, improving small polaron hopping is crucial for enhancing charge collection. In this work, we propose a direct approach to effectively enhance the photoelectrochemical (PEC) performance of hematite by leveraging the thermal nature of polaron hopping. As a result, a photocurrent density of 4.53 mA/cm$^{2}$ at 1.23 V vs. RHE was achieved by heating the photoanode to 70 ${^\circ}$C. By combining carrier dynamics analysis with charge collection modeling, we demonstrate that heating facilitates small polaron hopping, thereby increasing carrier mobility and improving the collection efficiency of hematite photoanodes. Our work provides clear explanations of the thermal-activated small polaron hopping mechanism, offering a simple yet effective strategy for enhancing the PEC performance of transition metal oxides.

Keywords: small polaron hopping hematite thermal activation transfer matrix model

Received: 02 December 2025
Revised: 08 January 2026
Accepted manuscript online: 14 January 2026

PACS:	82.80.Fk	(Electrochemical methods)
	81.05.Zx	(New materials: theory, design, and fabrication)
	84.60.Jt	(Photoelectric conversion)
	64.70.ph	(Nonmetallic glasses (silicates, oxides, selenides, etc.))

Fund: The authors acknowledge support from the National Key Research and Development Program of China (Grant No. 2022YFC2204101), the National Natural Science Foundation of China (Grant No. 5257022607), the Fundamental Research Funds for the Central Universities (Grant No. lzujbky- 2025-ytC02), and the Key Research and Development Program of Gansu Province (Grant No. 24YFGA005).

Corresponding Authors: Youwei Zhang, Bonan Zhu, Zemin Zhang
E-mail: youweizhang@hust.edu.cn;bzhu@bit.edu.cn;zhangzemin@lzu.edu.cn

Cite this article:

Yujie Wang(王玉杰), Xu Cheng(程旭), Jialin Shao(邵嘉琳), Xugang Qi(漆旭刚), Jia Zhao(赵嘉), Lu Yang(杨露), Youwei Zhang(张有为), Bonan Zhu(朱博南), and Zemin Zhang(张泽民) Thermally-enhanced charge collection boosts photoelectrochemical performance of hematite 2026 Chin. Phys. B 35 058201

[1] Liu P F, Wang C W, Wang Y, Li Y H, Zhang B, Zheng L R, Jiang Z, Zhao H J and Yang H G 2011 Sci. Bull. 66 1013
[2] Bak A, Choi W and Park H 2011 App. Catal. B: Environ. 110 207
[3] Liu D Y and Kuang Y B 2024 Adv. Mater. 36 2311692
[4] Carneiro L M, Cushing S K, Liu C, Su Y D, Yang P D, Alivisatos A P and Leone S R 2017 Nat. Mater. 16 819
[5] Li C C, Luo Z B, Wang T and Gong J L 2018 Adv. Mater. 30 1707502
[6] Shen S H, Lindley S A, Chen X Y and Zhang J Z 2016 Energy Environ. Sci. 9 2744
[7] Yifat P, David S E, Daniel A G, Anton T and Avner R 2021 Energy Environ. Sci. 14 4584
[8] Hu X Q, Huang J, Cao Y, He B, Cui X, Zhu Y H, Wang Y, Chen Y H, Yang Y K, Li Z and Liu X Q 2023 Carbon Energy 5 369
[9] Shao J L, Wang Y J, Liu H Y, Hao R, Luo L L, Li Y T, Cooper J K and Zhang Z M 2025 Appl. Phys. Lett. 126 223508
[10] Tang S T, Qiu W T, Xu X W, Xiao S, Tong Y X, Wang X W and Yang S H 2022 Adv. Funct. Mater. 32 2110284
[11] Merschjann C, Imlau M, Bruning H, Schoke B and Torbr ugge S 2011 Phys. Rev. B 84 052302
[12] Franchini C, Reticcioli M, Setvin M and Diebold U 2021 Nat. Rev. Mater. 6 560
[13] Ren Z Z, Shi Z J, Feng H F, Xu Z F and Hao W C 2023 Adv. Sci. 11 2305139
[14] Cresi J S P, Mario L D, Catone D, Martelli F, Paladini A, Turchini S, D’Addato S, Luches P and O’Keeffe P 2020 J. Phys. Chem. Lett. 11 5686
[15] Rettie A J E, Chemelewski W D, Emin D and Mullins C B 2016 J. Phys. Chem. Lett. 7 471
[16] Wang Z L, Mao X, Chen P, Xiao M, Monny S A, Wang S C, Konarova M, Du A J and Wang L Z 2019 Angew. Chem. Int. Ed. 58 1030
[17] Qiu W T, Xiao S, Ke J W, Wang Z, Tang S T, Zhang K, Qian W, Huang Y C, Huang D, Tong Y X and Yang S H 2019 Angew. Chem. Int. Ed. 58 19087
[18] Li M Y, Yang Y, Ling Y C, Qiu W T, Wang F X, Liu T Y, Song Y, Liu X X, Fang P P, Tong Y X and Li Y 2017 Nano Lett. 17 2490
[19] Xiao Y Q, Fu J, Pihosh Y, Karmakar K, Zhang B B, Domen K and Li Y B 2025 Chem. Soc. Rev. 54 1268
[20] Li X, Hou S S, Xie X X, Yang H and Huang Y C 2026 J. Catal. 453 116540
[21] Zhang L L, Chu W B, Zhao C Y, Zheng Q J, Prezhdo O V and Zhao J 2021 J. Phys. Chem. Lett. 12 2191
[22] Huang J, Hu X Q, Wang J N, Lin K J, He B, Yang Y K, Wang Y, Li Z and Liu X Q 2023 Chemical Engineering Journal 462 142246
[23] Zhang J N, Tang T X, Xie Z Z, Chen Y X, Yang H, Ye K H, Chen J W, Zou W H, Shi J X and Huang Y C 2024 Chem. Eng. J. 497 154833
[24] Machreki M, Chouki T, Martelanc M, Butinar L, Vodopivec B M and Emin S 2021 J. Environ. Chem. Eng. 9 105495
[25] Liu J F, Du S W, Fan W J, Li Q L, Yang Q, Luo L, Li J N and Zhang F X 2024 Energy Environ. Sci. 17 9093
[26] Jin J T, Liu Y C, Zhao X D, Liu H, Deng S Q, Shen Q Y, Hou Y, Qi H, Xing X R, Jiao L F and Chen J 2023 J. Chen, Angew. Chem. Int. Ed. 62 202219230
[27] Li H M, Wang Z Y, Jing H J, Yi S S, Zhang S X, Yue X Z, Zhang Z T, Lu H X and Chen D L 2021 Applied Catalysis B: Environmental 284 119760
[28] Li H L, Guo M, Zhou Z H, Long R and Fang W H 2023 J. Phys. Chem. Lett. 14 2448
[29] Hu Z J, Bao Y J, Li Z W, Gong Y J, Feng R, Xiao Y D, Wu X C, Zhang Z H, Zhu X, Ajayan P M and Fang Z Y 2017 Sci. Bull. 62 16
[30] Gong X N, Wu H, Yang D F, Zhang B, Peng K L, Zou H J, Guo L J, Lu X, Chai Y S, Wang G Y and Zhou X Y 2020 Vib. Spectrosc. 107 103034
[31] Jang A R, Yoon J W, Son S B, Ryu H I, Cho J, Shin K H, Sohn J I and Hong W K 2021 ACS Appl. Mater. Interfaces 13 3426
[32] Bergeron A, Gradziel C, Leonelli R and Francoeur S 2023 Nat. Commun. 14 4098
[33] Wang N, Mao N N, Wang Z E, Yang X, Zhou X, Liu H N, Qiao S L, Lei X F, Wang J R, Xu H, Ling X, Zhang Q Y, Feng Q L and Kong J 2021 Adv. Mater. 33 2005815
[34] Hayes D, Hadt R G, Emery J D, Cordones A A, Martinson A B F, Shelby M L, Fransted K A, Dahlberg P D, Hong J Y, Zhang X Y, Kong Q Y, Schoenlein R W and Chen L X 2016 Energy Environ. Sci. 9 3754
[35] Kay A, Fiegenbaum-Raz M, Muller S, Eichberger R, Dotan H, Krol R V D, Abdi F F, Rothschild A, Friedrich D and Grave D A 2020 Adv. Funct. Mater. 30 1901590
[36] Grave D A and Segev G 2022 J. Phys. D: Appl. Phys. 55 023001
[37] Grave D A, Ellis D S, Piekner Y, Kolbach M, Dotan H, Kay A, Schnell P, Krol R V D, Abdi F F, Friedrich D and Rothschild A 2021 Nat. Mater. 20 833
[38] Segev G, Jiang C M, Cooper J K, Eichhorn J, Toma F M and Sharp I D 2018 Energy Environ. Sci. 11 904
[39] Segev G, Dotan H, Ellis D S, Piekner Y, Klotz D, Beeman J W, Cooper J K, Grave D A, Sharp I D and Rothschild A 2018 Joule 2 1

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Thermally-enhanced charge collection boosts photoelectrochemical performance of hematite

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