Your search keyword '"Zhou, Weinan"' showing total 10 results

1. Seebeck-driven transverse thermoelectric generation in magnetic hybrid bulk materials

Author

Zhou, Weinan, Miura, Asuka, Hirai, Takamasa, Sakuraba, Yuya, and Uchida, Ken-ichi

Subjects

Condensed Matter - Materials Science

Abstract

The Seebeck-driven transverse thermoelectric generation in magnetic/thermoelectric hybrid materials (STTG) has been investigated in all-bulk hybrid materials. The transverse thermopower in a ferromagnetic Co$_2$MnGa/thermoelectric $n$-type Si hybrid bulk material with the adjusted dimensions reaches 16.0 $\mu$V/K at room temperature with the aid of the STTG contribution, which is much larger than the anomalous Nernst coefficient of the Co$_2$MnGa slab (6.8 $\mu$V/K). Although this transverse thermopower is smaller than the value for previously reported thin-film-based hybrid materials, the hybrid bulk materials exhibit much larger electrical power owing to their small internal resistance. This demonstration confirms the validity of STTG in bulk materials and clarifies its potential as a thermal energy harvester., Comment: 12 pages, 4 figures, 1 table

Published

2023

2. Direct electrical probing of anomalous Nernst conductivity

Author

Zhou, Weinan, Miura, Asuka, Sakuraba, Yuya, and Uchida, Ken-ichi

Subjects

Condensed Matter - Materials Science

Abstract

Despite the usefulness of the anomalous Nernst conductivity ($\alpha^{A}_{xy}$) for studying electronic band structures and exploring magnetic materials with large transverse thermopower, there has not been a straightforward way to obtain $\alpha^{A}_{xy}$ in the experiment. Here, we propose a simple and versatile method enabling direct electrical probing of $\alpha^{A}_{xy}$, which is realized by creating a closed circuit consisting of a target magnetic material and a non-magnetic conductor. This method was experimentally demonstrated on a thin film of magnetic Weyl semimetal Co$_{2}$MnGa, where the closed circuit was formed simply by connecting both ends of the Co$_{2}$MnGa film with a Au wire. A good approximation of $\alpha^{A}_{xy}$ was obtained in a wide temperature range, validating the proposed method and exhibiting its potential for aiding the further development of topological materials science and transverse thermoelectrics., Comment: 7 pages, 5 figures

Published

2023

3. Seebeck-driven transverse thermoelectric generation in on-chip devices

Author

Zhou, Weinan, Hirai, Takamasa, Uchida, Ken-ichi, and Sakuraba, Yuya

Subjects

Condensed Matter - Materials Science

Abstract

An unconventional approach to enhance the transverse thermopower by combining magnetic and thermoelectric materials, namely the Seebeck-driven transverse thermoelectric generation (STTG), has been proposed and demonstrated recently. Here, we improve on the previously used sample structure and achieve large transverse thermopower over 40 $\mu$V K$^{-1}$ due to STTG in on-chip devices. We deposited polycrystalline Fe-Ga alloy films directly on n-type Si substrates, where Fe-Ga and Si serve as the magnetic and thermoelectric materials, respectively. Using microfabrication, contact holes were created through the SiO$_{x}$ layer at the top of Si to electrically connect the Fe-Ga film with the Si substrate. These thin devices with simple structure clearly exhibited enhancement of transverse thermopower due to STTG, and the obtained values agreed well with the estimation over a wide range of the size ratio between the Fe-Ga film and the Si substrate., Comment: 8 pages, 7 figures

Published

2022

4. Sm-Co-based amorphous alloy films for zero-field operation of transverse thermoelectric generation

Author

Modak, Rajkumar, Sakuraba, Yuya, Hirai, Takamasa, Yagi, Takashi, Sepehri-Amin, Hossein, Zhou, Weinan, Masuda, Hiroto, Seki, Takeshi, Takanashi, Koki, Ohkubo, Tadakatsu, and Uchida, Ken-ichi

Subjects

Condensed Matter - Materials Science, Physics - Applied Physics

Abstract

Transverse thermoelectric generation using magnetic materials is essential to develop active thermal engineering technologies, for which the improvements of not only the thermoelectric output but also applicability and versatility are required. In this study, using combinatorial material science and lock-in thermography technique, we have systematically investigated the transverse thermoelectric performance of Sm-Co-based alloy films. The high-throughput material investigation revealed the best Sm-Co-based alloys with the large anomalous Nernst effect (ANE) as well as the anomalous Ettingshausen effect (AEE). In addition to ANE/AEE, we discovered unique and superior material properties in these alloys: the amorphous structure, low thermal conductivity, and large in-plane coercivity and remanent magnetization. These properties make it advantageous over conventional materials to realize heat flux sensing applications based on ANE, as our Sm-Co-based films can generate thermoelectric output without an external magnetic field. Importantly, the amorphous nature enables the fabrication of these films on various substrates including flexible sheets, making the large-scale and low-cost manufacturing easier. Our demonstration will provide a pathway to develop flexible transverse thermoelectric devices for smart thermal management., Comment: 40 pages in total, 10 main figures, 1 graphical abstract, 3 supplementary figures

Published

2022

5. Origin of negative anomalous Nernst thermopower in Mn-Ga ordered alloys

Author

Zhou, Weinan, Masuda, Keisuke, and Sakuraba, Yuya

Subjects

Condensed Matter - Materials Science

Abstract

The negative sign of the anomalous Nernst thermopower ($S_\text{ANE}$) observed in Mn-Ga ordered alloys is an attractive property for thermoelectric applications exploiting the anomalous Nernst effect (ANE); however, its origin has not been clarified. In this study, to gain insight into the negative $S_\text{ANE}$, we prepared epitaxial thin films of Mn$_{x}$Ga$_{100-x}$ with $x$ ranging from 56.2 to 71.7, and systematically investigated the structural, magnetic, and transport properties including the anomalous Hall effect (AHE) and the ANE. The measured $S_\text{ANE}$ is negative for all samples and shows close to one order of magnitude difference among different compositions. Together with the measured transport properties, we were able to separate the two different contributions of the ANE, i.e., one originating from the transverse thermoelectric coefficient ($\alpha_{xy}$), and the other one originating from the AHE acting on the longitudinal carrier flow induced by the Seebeck effect. Both contributions are found to be negative for all samples, while the experimentally obtained negative $\alpha_{xy}$ exhibits a monotonic increase towards zero with increasing $x$, which is consistent with the tendency indicated by first-principles calculations. Our results show that the large difference in the negative $S_\text{ANE}$ is mostly attributed to $\alpha_{xy}$, and thus shed light on further enhancement of the ANE in Mn-based ordered alloys., Comment: 13 pages, 5 figures

Published

2021

6. Transverse thermoelectric generation using magnetic materials

Author

Uchida, Ken-ichi, Zhou, Weinan, and Sakuraba, Yuya

Subjects

Condensed Matter - Materials Science, Physics - Applied Physics

Abstract

The transverse thermoelectric effect refers to the conversion of a temperature gradient into a transverse charge current, or vice versa, which appears in a conductor under a magnetic field or in a magnetic material with spontaneous magnetization. Among such phenomena, the anomalous Nernst effect in magnetic materials has been receiving increased attention from the viewpoints of fundamental physics and thermoelectric applications owing to the rapid development of spin caloritronics and topological materials science. In this research trend, a conceptually different transverse thermoelectric conversion phenomenon appearing in thermoelectric/magnetic hybrid materials has been demonstrated, enabling the generation of a large transverse thermopower. Here, we review the recent progress in fundamental and applied studies on the transverse thermoelectric generation using magnetic materials. We anticipate that this perspective will further stimulate research activities on the transverse thermoelectric generation and lead to the development of next-generation thermal energy harvesting and heat-flux sensing technologies., Comment: 18 pages, 5 figures

Published

2021

7. Phenomenological analysis of transverse thermoelectric generation and cooling performance in magnetic/thermoelectric hybrid systems

Author

Yamamoto, Kaoru, Iguchi, Ryo, Miura, Asuka, Zhou, Weinan, Sakuraba, Yuya, Miura, Yoshio, and Uchida, Ken-ichi

Subjects

Condensed Matter - Materials Science

Abstract

We phenomenologically calculate the performance of the recently-observed Seebeck-driven transverse thermoelectric generation (STTG) for various systems in terms of the thermopower, power factor, and figure of merit to demonstrate the usefulness of STTG. The STTG system consists of a closed circuit comprising thermoelectric and magnetic materials which exhibit the Seebeck and anomalous Hall effects, respectively. When a temperature gradient is applied to the hybrid system, the Seebeck effect in the thermoelectric material layer generates a longitudinal charge current in the closed circuit and the charge current subsequently drives the anomalous Hall effect in the magnetic material layer. The anomalous Hall voltage driven by the Seebeck effect has a similar symmetry to the transverse thermoelectric conversion based on the anomalous Nernst effect. We find that the thermoelectric properties of STTG can be much better than those of the anomalous Nernst effect by increasing the Seebeck coefficient and anomalous Hall angle of the thermoelectric and magnetic materials, respectively, as well as by optimizing their dimensions. We also formulate the electronic cooling performance in the STTG system, confirming the reciprocal relation for the hybrid transverse thermoelectric conversion., Comment: 7 pages, 4 figures

Published

2021

8. Structural insight using anomalous XRD into Mn2CoAl Heusler alloy films grown by magnetron sputtering, IBAS and MBE techniques

Author

Tajiri, Hiroo, Kumara, Loku Singgappulige Rosantha, Sakuraba, Yuya, Chen, Zixi, Wang, Jian, Zhou, Weinan, Varun, Kushwaha, Ueda, Kenji, Yamada, Shinya, Hamaya, Kohei, and Hono, Kazuhiro

Subjects

Condensed Matter - Materials Science

Abstract

Inverse Heusler alloy Mn2CoAl thin films, known as a spin-gapless semiconductor (SGS), grown by three different methods: ultra-high vacuum magnetron spattering, Ar-ion beam assisted sputtering, and molecular beam epitaxy, are investigated by comparing their electric transport properties, microstructures and atomic-level structures. Of the samples, the Mn2CoAl thin film grown by MBE consists of Mn- and Co-rich phases, the structures of which are determined to be the L21B-type and disordered L21-type, respectively, according to anomalous XRD analysis. None of them forms the XA-type structure expected for SGS Heusler alloy, although they all show SGS characteristics. We suggest, to validate SGS characteristics, it is necessary to extract not only magnetic and electric transport properties but also information about microstructures and atomic-scale structures of the films including defects such as atomic swap.

Published

2020

9. Spin-polarized Weyl cones and gigantic anomalous Nernst effect in ferromagnetic Heusler films

Author

Sumida, Kazuki, Sakuraba, Yuya, Masuda, Keisuke, Kono, Takashi, Kakoki, Masaaki, Goto, Kazuki, Zhou, Weinan, Miyamoto, Koji, Miura, Yoshio, Okuda, Taichi, and Kimura, Akio

Subjects

Condensed Matter - Materials Science

Abstract

Weyl semimetals are characterized by the presence of massless band dispersion in momentum space. When a Weyl semimetal meets magnetism, large anomalous transport properties emerge as a consequence of its topological nature. Here, using $in-situ$ spin- and angle-resolved photoelectron spectroscopy combined with $ab\ initio$ calculations, we visualize the spin-polarized Weyl cone and flat-band surface states of ferromagnetic Co$_2$MnGa films with full remanent magnetization. We demonstrate that the anomalous Hall and Nernst conductivities systematically grow when the magnetization-induced massive Weyl cone at a Lifshitz quantum critical point approaches the Fermi energy, until a high anomalous Nernst thermopower of $\sim 6.2$ $\rm \mu V K^{-1}$ is realized at room temperature. Given this topological quantum state and full remanent magnetization, Co$_2$MnGa films are promising for realizing high efficiency heat flux and magnetic field sensing devices operable at room temperature and zero-field., Comment: 25 pages, 5 figures, 1 table

Published

2020

10. Vortex Dynamics-Mediated Low-Field Magnetization Switching in an Exchange-Coupled System

Author

Zhou, Weinan, Seki, Takeshi, Arai, Hiroko, Imamura, Hiroshi, and Takanashi, Koki

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

A magnetic vortex has attracted significant attention since it is a topologically stable magnetic structure in a soft magnetic nanodisk. Many studies have been devoted to understanding the nature of magnetic vortex in isolated systems. Here we show a new aspect of a magnetic vortex the dynamics of which strongly affects the magnetic structures of environment. We exploit a nanodot of an exchange-coupled bilayer with a soft magnetic Ni81Fe19 (permalloy; Py) having a magnetic vortex and a perpendicularly magnetized L10-FePt exhibiting a large switching field (Hsw). The vortex dynamics with azimuthal spin waves makes the excess energy accumulate in the Py, which triggers the reversed-domain nucleation in the L10-FePt at a low magnetic field. Our results shed light on the non-local mechanism of a reversed-domain nucleation, and provide with a route for efficient Hsw reduction that is needed for ultralow-power spintronic devices., Comment: 26 pages, 5 figures, Supplementary Information

Published

2016