Oxygen vacancy doping of hematite analyzed by electrical conductivity and thermoelectric power measurements

Abstract: Hematite (α-Fe 2 O 3) is known for poor electronic transport properties, which are the main drawback of this material for optoelectronic applications. In this study, we investigate the concept of enhancing electrical conductivity by the introduction of oxygen vacancies during temperature treatment under low oxygen partial pressure. We demonstrate the possibility of tuning the conductivity continuously by more than five orders of magnitude during stepwise annealing in a moderate temperature range between 300 an… Show more

“…Theoretically, the maximum photocurrent of Fe 2 O 3 photoanode under AM 1.5G illumination is 12.6 mA/cm 2 for water oxidation . However, the practical photocurrent is much lower than the theoretical value ascribed to limited electrical conductivity, slow charge separation, sluggish charge transfer, and short hole diffusion lengths (2–4 nm). − …”

Manipulation of Charge Transfer in FeP@Fe₂O₃ Core–Shell Photoanode by Directed Built-In Electric Field

“…Theoretically, the maximum photocurrent of Fe 2 O 3 photoanode under AM 1.5G illumination is 12.6 mA/cm 2 for water oxidation . However, the practical photocurrent is much lower than the theoretical value ascribed to limited electrical conductivity, slow charge separation, sluggish charge transfer, and short hole diffusion lengths (2–4 nm). − …”

Manipulation of Charge Transfer in FeP@Fe₂O₃ Core–Shell Photoanode by Directed Built-In Electric Field

“…[20][21][22][23][24] X-ray photoelectron spectroscopy and X-ray absorption spectroscopy have been successfully employed to conrm and quantify these vacancies, 20,21 and to show that complete removal of oxygen vacancies from the photoanode surface can result in suppression of PEC performance. 20,21 Increased concentrations have been shown to increase both the density and mobility of charge carriers by orders of magnitude, 25 a feature which is frequently observed in PEC studies as an increased charge carrier density (N d ) measured through Mott-Schottky analysis; [22][23][24] increased N d has been widely shown to result in improved PEC performance but induce negligible changes in absorption proles. 24 Evidence has been provided that excessive removal of oxygen from the lattice leads to decomposition to Fe 3 O 4 , 25 suggesting a limitation in potential gains.…”

“… 20,21 Increased concentrations have been shown to increase both the density and mobility of charge carriers by orders of magnitude, 25 a feature which is frequently observed in PEC studies as an increased charge carrier density ( N d ) measured through Mott–Schottky analysis; 22–24 increased N d has been widely shown to result in improved PEC performance but induce negligible changes in absorption profiles. 24 Evidence has been provided that excessive removal of oxygen from the lattice leads to decomposition to Fe 3 O 4 , 25 suggesting a limitation in potential gains. The improved fundamental understanding of the relationship between PEC behavior and a specific structural defect marks a significant advance that brings the field closer to the rational development of photoanodes.…”

Identifying protons trapped in hematite photoanodes through structure–property analysis

“…It is generally accepted that the OVs in hematite serve as electron donors, resulting in improved electrical conductivity. [6][7][8][9]56 The donor density (N d ) of the samples was estimated using Mott− Schottky analysis. Figure 5a In an electrochemical cell, the bulk capacitance (C bulk ) of an electrode is related to the applied potential (V) by the Mott− Schottky equation as follows…”

Laser-Induced Photoreduction for Selective Tuning of the Oxidation State and Crystal Structure of Hematite Nanorods