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Proton transfer dynamics control the mechanism of O2 reduction by a non-precious metal electrocatalyst.

Nature materials

Tse EC, Barile CJ, Kirchschlager NA, Li Y, Gewargis JP, Zimmerman SC, Hosseini A, Gewirth AA.
PMID: 27135859
Nat Mater. 2016 Jul;15(7):754-9. doi: 10.1038/nmat4636. Epub 2016 May 02.

Many chemical and biological processes involve the transfer of both protons and electrons. The complex mechanistic details of these proton-coupled electron transfer (PCET) reactions require independent control of both electron and proton transfer. In this report, we make use...

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Tse EC, Barile CJ, Kirchschlager NA, et al. Proton transfer dynamics control the mechanism of O2 reduction by a non-precious metal electrocatalyst. Nat Mater. 2016;15(7):754-9doi: 10.1038/nmat4636.
Tse, E. C., Barile, C. J., Kirchschlager, N. A., Li, Y., Gewargis, J. P., Zimmerman, S. C., Hosseini, A., & Gewirth, A. A. (2016). Proton transfer dynamics control the mechanism of O2 reduction by a non-precious metal electrocatalyst. Nature materials, 15(7), 754-9. https://doi.org/10.1038/nmat4636
Tse, Edmund C M, et al. "Proton transfer dynamics control the mechanism of O2 reduction by a non-precious metal electrocatalyst." Nature materials vol. 15,7 (2016): 754-9. doi: https://doi.org/10.1038/nmat4636
Tse EC, Barile CJ, Kirchschlager NA, Li Y, Gewargis JP, Zimmerman SC, Hosseini A, Gewirth AA. Proton transfer dynamics control the mechanism of O2 reduction by a non-precious metal electrocatalyst. Nat Mater. 2016 Jul;15(7):754-9. doi: 10.1038/nmat4636. Epub 2016 May 02. PMID: 27135859.
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Nonmagnetic band gap at the Dirac point of the magnetic topological insulator (Bi(1-x)Mn(x))2Se3.

Nature communications

Sánchez-Barriga J, Varykhalov A, Springholz G, Steiner H, Kirchschlager R, Bauer G, Caha O, Schierle E, Weschke E, Ünal AA, Valencia S, Dunst M, Braun J, Ebert H, Minár J, Golias E, Yashina LV, Ney A, Holý V, Rader O.
PMID: 26892831
Nat Commun. 2016 Feb 19;7:10559. doi: 10.1038/ncomms10559.

Magnetic doping is expected to open a band gap at the Dirac point of topological insulators by breaking time-reversal symmetry and to enable novel topological phases. Epitaxial (Bi(1-x)Mn(x))2Se3 is a prototypical magnetic topological insulator with a pronounced surface band...

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Sánchez-Barriga J, Varykhalov A, Springholz G, et al. Nonmagnetic band gap at the Dirac point of the magnetic topological insulator (Bi(1-x)Mn(x))2Se3. Nat Commun. 2016;7:10559doi: 10.1038/ncomms10559.
Sánchez-Barriga, J., Varykhalov, A., Springholz, G., Steiner, H., Kirchschlager, R., Bauer, G., Caha, O., Schierle, E., Weschke, E., Ünal, A. A., Valencia, S., Dunst, M., Braun, J., Ebert, H., Minár, J., Golias, E., Yashina, L. V., Ney, A., Holý, V., & Rader, O. (2016). Nonmagnetic band gap at the Dirac point of the magnetic topological insulator (Bi(1-x)Mn(x))2Se3. Nature communications, 710559. https://doi.org/10.1038/ncomms10559
Sánchez-Barriga, J, et al. "Nonmagnetic band gap at the Dirac point of the magnetic topological insulator (Bi(1-x)Mn(x))2Se3." Nature communications vol. 7 (2016): 10559. doi: https://doi.org/10.1038/ncomms10559
Sánchez-Barriga J, Varykhalov A, Springholz G, Steiner H, Kirchschlager R, Bauer G, Caha O, Schierle E, Weschke E, Ünal AA, Valencia S, Dunst M, Braun J, Ebert H, Minár J, Golias E, Yashina LV, Ney A, Holý V, Rader O. Nonmagnetic band gap at the Dirac point of the magnetic topological insulator (Bi(1-x)Mn(x))2Se3. Nat Commun. 2016 Feb 19;7:10559. doi: 10.1038/ncomms10559. PMID: 26892831; PMCID: PMC4762886.
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From highly monodisperse indium and indium tin colloidal nanocrystals to self-assembled indium tin oxide nanoelectrodes.

ACS nano

Yarema M, Pichler S, Kriegner D, Stangl J, Yarema O, Kirchschlager R, Tollabimazraehno S, Humer M, Häringer D, Kohl M, Chen G, Heiss W.
PMID: 22506926
ACS Nano. 2012 May 22;6(5):4113-21. doi: 10.1021/nn3005558. Epub 2012 Apr 23.

Indium tin oxide (ITO) nanopatterned electrodes are prepared from colloidal solutions as a material saving alternative to the industrial vapor phase deposition and top down processing. For that purpose highly monodisperse In(1-x)Sn(x) (x < 0.1) colloidal nanocrystals (NCs) are...

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Yarema M, Pichler S, Kriegner D, et al. From highly monodisperse indium and indium tin colloidal nanocrystals to self-assembled indium tin oxide nanoelectrodes. ACS Nano. 2012;6(5):4113-21doi: 10.1021/nn3005558.
Yarema, M., Pichler, S., Kriegner, D., Stangl, J., Yarema, O., Kirchschlager, R., Tollabimazraehno, S., Humer, M., Häringer, D., Kohl, M., Chen, G., & Heiss, W. (2012). From highly monodisperse indium and indium tin colloidal nanocrystals to self-assembled indium tin oxide nanoelectrodes. ACS nano, 6(5), 4113-21. https://doi.org/10.1021/nn3005558
Yarema, Maksym, et al. "From highly monodisperse indium and indium tin colloidal nanocrystals to self-assembled indium tin oxide nanoelectrodes." ACS nano vol. 6,5 (2012): 4113-21. doi: https://doi.org/10.1021/nn3005558
Yarema M, Pichler S, Kriegner D, Stangl J, Yarema O, Kirchschlager R, Tollabimazraehno S, Humer M, Häringer D, Kohl M, Chen G, Heiss W. From highly monodisperse indium and indium tin colloidal nanocrystals to self-assembled indium tin oxide nanoelectrodes. ACS Nano. 2012 May 22;6(5):4113-21. doi: 10.1021/nn3005558. Epub 2012 Apr 23. PMID: 22506926.
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Ferroelectric phase transition in multiferroic Ge.

Physical review. B

Kriegner D, Furthmüller J, Kirchschlager R, Endres J, Horak L, Cejpek P, Reichlova H, Marti X, Primetzhofer D, Ney A, Bauer G, Bechstedt F, Holy V, Springholz G.
PMID: 28459114
Phys Rev B. 2016 Aug 01;94(5). doi: 10.1103/PhysRevB.94.054112. Epub 2016 Aug 19.

The evolution of local ferroelectric lattice distortions in multiferroic Ge

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Kriegner D, Furthmüller J, Kirchschlager R, et al. Ferroelectric phase transition in multiferroic Ge. Phys Rev B. 2016;94(5)doi: 10.1103/PhysRevB.94.054112.
Kriegner, D., Furthmüller, J., Kirchschlager, R., Endres, J., Horak, L., Cejpek, P., Reichlova, H., Marti, X., Primetzhofer, D., Ney, A., Bauer, G., Bechstedt, F., Holy, V., & Springholz, G. (2016). Ferroelectric phase transition in multiferroic Ge. Physical review. B, 94(5), . https://doi.org/10.1103/PhysRevB.94.054112
Kriegner, Dominik, et al. "Ferroelectric phase transition in multiferroic Ge." Physical review. B vol. 94,5 (2016). doi: https://doi.org/10.1103/PhysRevB.94.054112
Kriegner D, Furthmüller J, Kirchschlager R, Endres J, Horak L, Cejpek P, Reichlova H, Marti X, Primetzhofer D, Ney A, Bauer G, Bechstedt F, Holy V, Springholz G. Ferroelectric phase transition in multiferroic Ge. Phys Rev B. 2016 Aug 01;94(5). doi: 10.1103/PhysRevB.94.054112. Epub 2016 Aug 19. PMID: 28459114; PMCID: PMC5404721.
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Molecular beam epitaxy of single phase GeMnTe with high ferromagnetic transition temperature.

Journal of crystal growth

Hassan M, Springholz G, Lechner RT, Groiss H, Kirchschlager R, Bauer G.
PMID: 21776175
J Cryst Growth. 2011 May 15;323(1):363-367. doi: 10.1016/j.jcrysgro.2010.10.135.

Ferromagnetic Ge(1-x)Mn(x)Te is a promising candidate for diluted magnetic semiconductors because solid solutions exist over a wide range of compositions up to x(Mn)≈0.5, where a maximum in the total magnetization occurs. In this work, a systematic study of molecular...

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Hassan M, Springholz G, Lechner RT, et al. Molecular beam epitaxy of single phase GeMnTe with high ferromagnetic transition temperature. J Cryst Growth. 2011;323(1):363-367doi: 10.1016/j.jcrysgro.2010.10.135.
Hassan, M., Springholz, G., Lechner, R. T., Groiss, H., Kirchschlager, R., & Bauer, G. (2011). Molecular beam epitaxy of single phase GeMnTe with high ferromagnetic transition temperature. Journal of crystal growth, 323(1), 363-367. https://doi.org/10.1016/j.jcrysgro.2010.10.135
Hassan, M, et al. "Molecular beam epitaxy of single phase GeMnTe with high ferromagnetic transition temperature." Journal of crystal growth vol. 323,1 (2011): 363-367. doi: https://doi.org/10.1016/j.jcrysgro.2010.10.135
Hassan M, Springholz G, Lechner RT, Groiss H, Kirchschlager R, Bauer G. Molecular beam epitaxy of single phase GeMnTe with high ferromagnetic transition temperature. J Cryst Growth. 2011 May 15;323(1):363-367. doi: 10.1016/j.jcrysgro.2010.10.135. PMID: 21776175; PMCID: PMC3114077.
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Heavy-Hole States in Germanium Hut Wires.

Nano letters

Watzinger H, Kloeffel C, Vukušić L, Rossell MD, Sessi V, Kukučka J, Kirchschlager R, Lausecker E, Truhlar A, Glaser M, Rastelli A, Fuhrer A, Loss D, Katsaros G.
PMID: 27656760
Nano Lett. 2016 Nov 09;16(11):6879-6885. doi: 10.1021/acs.nanolett.6b02715. Epub 2016 Oct 17.

Hole spins have gained considerable interest in the past few years due to their potential for fast electrically controlled qubits. Here, we study holes confined in Ge hut wires, a so-far unexplored type of nanostructure. Low-temperature magnetotransport measurements reveal...

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Watzinger H, Kloeffel C, Vukušić L, et al. Heavy-Hole States in Germanium Hut Wires. Nano Lett. 2016;16(11):6879-6885doi: 10.1021/acs.nanolett.6b02715.
Watzinger, H., Kloeffel, C., Vukušić, L., Rossell, M. D., Sessi, V., Kukučka, J., Kirchschlager, R., Lausecker, E., Truhlar, A., Glaser, M., Rastelli, A., Fuhrer, A., Loss, D., & Katsaros, G. (2016). Heavy-Hole States in Germanium Hut Wires. Nano letters, 16(11), 6879-6885. https://doi.org/10.1021/acs.nanolett.6b02715
Watzinger, Hannes, et al. "Heavy-Hole States in Germanium Hut Wires." Nano letters vol. 16,11 (2016): 6879-6885. doi: https://doi.org/10.1021/acs.nanolett.6b02715
Watzinger H, Kloeffel C, Vukušić L, Rossell MD, Sessi V, Kukučka J, Kirchschlager R, Lausecker E, Truhlar A, Glaser M, Rastelli A, Fuhrer A, Loss D, Katsaros G. Heavy-Hole States in Germanium Hut Wires. Nano Lett. 2016 Nov 09;16(11):6879-6885. doi: 10.1021/acs.nanolett.6b02715. Epub 2016 Oct 17. PMID: 27656760; PMCID: PMC5108027.
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Showing 1 to 6 of 6 entries