Visible Light Driven Photoelectrochemical Water Oxidation by Zn- and Ti-Doped Hematite Nanostructures

Abstract: The electrodeposition method was used for modification of a nanostructured hematite photoanode with Ti and Zn to improve the photoelectrocatalytic performance of hematite in the water splitting reaction. The photoelectrocatalytic activity of the hematite electrodes modified with Ti 4+ and Zn 2+ was optimized through the controlled variation of the dopant ion concentration in the electrodeposition solution. Under optimized conditions, for standard illumination of AM 1.5G (100 mW cm −2 ), the photocurrent densit… Show more

“…The FTO electrodes were cleaned ultrasonically in Millipore water, ethanol, acetone, and finally rinsed in Milli-Q water. Next, the cleaned FTO electrodes were immersed into the electrodeposition solution containing 5 mM FeCl 3 , 5 mM KF, 0.1 M KCl, and 1 M H 2 O 2 [16]. For modification of hematite with titanium (Ti-modified hematite electrode), calculated amounts TiCl 4 were added to the electrodeposition solution to achieve Ti/Fe nominal atomic ratios of 1%, 3%, 5% and 10%.…”

“…A versatile synthesis procedure, allowing performance optimization by doping, has been obtained by the hydrothermal route [11][12][13][14]. An equally versatile, room temperature procedure for hematite film formation and doping is by electrodeposition [6][7][8]15,16]. The last procedure, which is easy to apply and interesting for industrial applications, has been adopted for the purposes of the present work.…”

“…Doping is expected to repair defects and thus decrease electron-hole recombination. Metal doping involves a variety of dopants, for example, Pt [8], Zn and Ti [16]. Another interesting approach is to combine hematite with an oxygen evolution co-catalyst, such as Co-Pi [7].…”

“…In this respect, in the present work, we have studied the applicability of hematite photoanodes beyond water splitting to the production of hydrogen in the presence of organic sacrificial agents. We have employed a standard procedure to construct electrochemically deposited hematite photoanodes doped with Ti 4+ [16]. The content of the present work involves elaboration on the method of hematite film deposition on FTO electrodes, doping with Ti 4+ , film optimization and characterization and presentation of some typical data on photoelectrochemical hydrogen production.…”

Electrodeposited Ti-doped hematite photoanodes and their employment for photoelectrocatalytic hydrogen production in the presence of ethanol

“…The FTO electrodes were cleaned ultrasonically in Millipore water, ethanol, acetone, and finally rinsed in Milli-Q water. Next, the cleaned FTO electrodes were immersed into the electrodeposition solution containing 5 mM FeCl 3 , 5 mM KF, 0.1 M KCl, and 1 M H 2 O 2 [16]. For modification of hematite with titanium (Ti-modified hematite electrode), calculated amounts TiCl 4 were added to the electrodeposition solution to achieve Ti/Fe nominal atomic ratios of 1%, 3%, 5% and 10%.…”

“…A versatile synthesis procedure, allowing performance optimization by doping, has been obtained by the hydrothermal route [11][12][13][14]. An equally versatile, room temperature procedure for hematite film formation and doping is by electrodeposition [6][7][8]15,16]. The last procedure, which is easy to apply and interesting for industrial applications, has been adopted for the purposes of the present work.…”

“…Doping is expected to repair defects and thus decrease electron-hole recombination. Metal doping involves a variety of dopants, for example, Pt [8], Zn and Ti [16]. Another interesting approach is to combine hematite with an oxygen evolution co-catalyst, such as Co-Pi [7].…”

“…In this respect, in the present work, we have studied the applicability of hematite photoanodes beyond water splitting to the production of hydrogen in the presence of organic sacrificial agents. We have employed a standard procedure to construct electrochemically deposited hematite photoanodes doped with Ti 4+ [16]. The content of the present work involves elaboration on the method of hematite film deposition on FTO electrodes, doping with Ti 4+ , film optimization and characterization and presentation of some typical data on photoelectrochemical hydrogen production.…”

Electrodeposited Ti-doped hematite photoanodes and their employment for photoelectrocatalytic hydrogen production in the presence of ethanol

“…Compared to the pure ZnO and g-C 3 N 4 , the g-C 3 N 4 /ZnO extends the 15 absorbance to not only the ultraviolet region but also the visible region, suggesting that the recombination rate of the photoinduced electro-hole pairs was successfully reduced in the heterostructured g-C 3 N 4 /ZnO composite. The band gap (E g ) of the ZnO and g-C 3 N 4 can be calculated from the formula: 20 Where α, hν and A is the absorption coefficient, photo energy and constant, respectively [40].…”

g-C3N4 decorated ZnO nanorod arrays for enhanced photoelectrocatalytic performance

Hematite Materials for Solar‐Driven Photoelectrochemical Cells