Simone Pokrant
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Explore the profile of Simone Pokrant including associated specialties, affiliations and a list of published articles.
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10
Citations
17
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Recent Articles
1.
Werner V, Lora F, Chai Z, Horndl J, Praxmair J, Luber S, et al.
RSC Sustain
. 2024 Jun;
2(6):1738-1752.
PMID: 38845685
Advancing towards alternative technologies for the sustainable production of hydrogen is a necessity for the successful integration of this potentially green fuel in the future. Photocatalytic and photoelectrochemical water splitting...
2.
Ricca C, Blandenier T, Werner V, Wang X, Pokrant S, Aschauer U
Phys Chem Chem Phys
. 2023 Jul;
25(30):20575-20584.
PMID: 37475639
Perovskite oxynitrides are, due to their reduced band gap compared to oxides, promising materials for photocatalytic applications. They are most commonly synthesized from {110} layered Carpy-Galy (ABO) perovskites thermal ammonolysis,...
3.
Werner V, Aschauer U, Redhammer G, Schoiber J, Zickler G, Pokrant S
Inorg Chem
. 2023 Apr;
62(17):6649-6660.
PMID: 37079557
Exploring photocatalysts for solar water splitting is a relevant step toward sustainable hydrogen production. Sillén-Aurivillius-type compounds have proven to be a promising material class for photocatalytic and photoelectrochemical water splitting...
4.
Schoiber J, Sollinger D, Baran V, Diemant T, Redhammer G, Behm R, et al.
Acta Crystallogr B Struct Sci Cryst Eng Mater
. 2022 Aug;
78(Pt 4):637-642.
PMID: 35975830
Vanadate compounds, such as VO·HO, are of high interest due to their versatile applications as electrode material for metal-ion batteries. In particular, VO·HO can insert different ions such as Li,...
5.
Sollinger D, Karl M, Redhammer G, Schoiber J, Werner V, Zickler G, et al.
ChemSusChem
. 2020 Dec;
14(4):1112-1121.
PMID: 33337578
Nanostructured H V O is a promising high-capacity cathode material, suitable not only for Li but also for Na+, Mg , and Zn insertion. However, the full theoretical capacity for...
6.
7.
Dilger S, Trottmann M, Pokrant S
ChemSusChem
. 2019 Jan;
12(9):1931-1938.
PMID: 30600935
A scalable process for fabrication of particle-based photoanodes is developed. The electrodes are versatilely made of photocatalytically active semiconductor particles, in this case LaTiO N, and optionally coated with cocatalysts...
8.
Landsmann S, Surace Y, Trottmann M, Dilger S, Weidenkaff A, Pokrant S
ACS Appl Mater Interfaces
. 2016 May;
8(19):12149-57.
PMID: 27159411
Efficient water splitting with photoelectrodes requires highly performing and stable photoactive materials. Since there is no material known which fulfills all these requirements because of various loss mechanisms, we present...
9.
Landsmann S, Maegli A, Trottmann M, Battaglia C, Weidenkaff A, Pokrant S
ChemSusChem
. 2015 Sep;
8(20):3451-8.
PMID: 26360811
Semiconductor powders are perfectly suited for the scalable fabrication of particle-based photoelectrodes, which can be used to split water using the sun as a renewable energy source. This systematic study...
10.
Pokrant S, Maegli A, Chiarello G, Weidenkaff A
Chimia (Aarau)
. 2013 Apr;
67(3):162-7.
PMID: 23574956
Over the last decades photocatalytic water splitting has become of increasing importance for fundamental and applied research, since the direct conversion of sunlight into chemical energy via the production of...