The Nernst effect, a transverse thermoelectric phenomenon, has attracted significant attention for its potential in energy conversion, thermoelectrics, and spintronics. However, achieving high performance and versatility at low temperatures remains elusive. Here, we demonstrate a large and electrically tunable Nernst effect by combining graphene's electrical properties with indium selenide's semiconducting nature in a field-effect geometry. Our results establish a novel platform for exploring and manipulating this thermoelectric effect, showcasing the first electrical tunability with an on/off ratio of 10^3. Moreover, photocurrent measurements reveal a stronger photo-Nernst signal in the Gr/InSe heterostructure compared to individual components. Remarkably, we observe a record-high Nernst coefficient of 66.4 μV K^(-1) T^(-1) at ultra-low temperatures and low magnetic fields, paving the way toward applications in quantum information and low-temperature emergent phenomena.
L. Elesin, А. Л. Шилов, Somnath Jana, Ievgen Mazurenko, Pierre A. Pantaleón, M. A. Kashchenko, N. Krivovichev, V. V. Dremov, Igor Gayduchenko, Gregory Goltsman, T. Taniguchi, K. Watanabe, Yao Wang, Elena Titova, Dmitry Svintsov, Konstantin ‘kostya’ Novoselov, D. A. Bandurin
Garry W. Mudd, Simon A. Svatek, Lee Hague, O. Makarovsky, Z. R. Kudrynskyi, Christopher J. Mellor, Peter H. Beton, L. Eaves, Konstantin ‘kostya’ Novoselov, Z. D. Kovalyuk, Evgeny E. Vdovin, Alexander J. Marsden, Neil R. Wilson, A. Patanè
Z. R. Kudrynskyi, Mahabub Alam Bhuiyan, O. Makarovsky, Jake D. G. Greener, Е. Е. Вдовин, Z. D. Kovalyuk, Yang Cao, Artem Mishchenko, Konstantin ‘kostya’ Novoselov, Peter H. Beton, L. Eaves, A. Patanè
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