Xinzhi Wu

567 total citations
29 papers, 400 citations indexed

About

Xinzhi Wu is a scholar working on Materials Chemistry, Electrical and Electronic Engineering and Mechanical Engineering. According to data from OpenAlex, Xinzhi Wu has authored 29 papers receiving a total of 400 indexed citations (citations by other indexed papers that have themselves been cited), including 28 papers in Materials Chemistry, 6 papers in Electrical and Electronic Engineering and 5 papers in Mechanical Engineering. Recurrent topics in Xinzhi Wu's work include Advanced Thermoelectric Materials and Devices (21 papers), Thermal properties of materials (16 papers) and Thermal Expansion and Ionic Conductivity (8 papers). Xinzhi Wu is often cited by papers focused on Advanced Thermoelectric Materials and Devices (21 papers), Thermal properties of materials (16 papers) and Thermal Expansion and Ionic Conductivity (8 papers). Xinzhi Wu collaborates with scholars based in China, Japan and Hong Kong. Xinzhi Wu's co-authors include Weishu Liu, Zhijia Han, Chengyan Liu, Feng Jiang, Yongbin Zhu, Binghui Ge, Kang Zhu, Yangjian Lin, Yupeng Wang and Kun Peng and has published in prestigious journals such as Advanced Materials, Nature Communications and Energy & Environmental Science.

In The Last Decade

Xinzhi Wu

25 papers receiving 397 citations

Peers — A (Enhanced Table)

Peers by citation overlap · career bar shows stage (early→late) cites · hero ref

Name h Career Trend Papers Cites
Xinzhi Wu China 13 355 99 90 72 68 29 400
Jianping Lin China 11 295 0.8× 172 1.7× 103 1.1× 36 0.5× 50 0.7× 28 382
Janak Tiwari United States 10 213 0.6× 116 1.2× 70 0.8× 27 0.4× 41 0.6× 14 349
Hyo-Seob Kim South Korea 12 361 1.0× 110 1.1× 92 1.0× 47 0.7× 143 2.1× 20 420
Nathalie Caillault France 10 256 0.7× 61 0.6× 102 1.1× 109 1.5× 63 0.9× 16 333
Ding Ren China 10 276 0.8× 127 1.3× 43 0.5× 44 0.6× 65 1.0× 31 330
Paweł Nieroda Poland 13 290 0.8× 151 1.5× 58 0.6× 44 0.6× 35 0.5× 33 341
Driss Kenfaui France 11 550 1.5× 107 1.1× 92 1.0× 181 2.5× 116 1.7× 22 627
Hisashi Kaga Japan 11 339 1.0× 153 1.5× 82 0.9× 86 1.2× 37 0.5× 37 420
Elbara Ziade United States 11 442 1.2× 153 1.5× 93 1.0× 31 0.4× 149 2.2× 18 522
Shang Peng China 11 366 1.0× 265 2.7× 62 0.7× 44 0.6× 41 0.6× 29 461

Countries citing papers authored by Xinzhi Wu

Since Specialization
Citations

This map shows the geographic impact of Xinzhi Wu's research. It shows the number of citations coming from papers published by authors working in each country. You can also color the map by specialization and compare the number of citations received by Xinzhi Wu with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites Xinzhi Wu more than expected).

Fields of papers citing papers by Xinzhi Wu

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by Xinzhi Wu. Nodes represent research fields, and links connect fields that are likely to share authors. Colored nodes show fields that tend to cite the papers produced by Xinzhi Wu. The network helps show where Xinzhi Wu may publish in the future.

Co-authorship network of co-authors of Xinzhi Wu

This figure shows the co-authorship network connecting the top 25 collaborators of Xinzhi Wu. A scholar is included among the top collaborators of Xinzhi Wu based on the total number of citations received by their joint publications. Widths of edges represent the number of papers authors have co-authored together. Node borders signify the number of papers an author published with Xinzhi Wu. Xinzhi Wu is excluded from the visualization to improve readability, since they are connected to all nodes in the network.

All Works

20 of 20 papers shown
1.
Wu, Xinzhi & Takao Mori. (2025). Sub-lattice amorphization as a new driver of room temperature plasticity in inorganic semiconductors. The Innovation. 6(6). 100891–100891.
2.
Wang, Longquan, et al.. (2025). Leveraging carrier mobility enables high-performance Mg3(Sb, Bi)2 thermoelectrics. National Science Review. 13(1). nwaf507–nwaf507.
3.
Wang, Yupeng, et al.. (2025). A general route to design solar thermoelectric generators under the constant heat flux thermal boundary. Energy & Environmental Science. 18(6). 2861–2872. 1 indexed citations
4.
Wu, Xinzhi, et al.. (2025). Negative enthalpy delivering improved thermal stability for Mg2Sn-based thermoelectric power generator. Acta Materialia. 289. 120865–120865. 3 indexed citations
5.
Liu, Ming, Xinzhi Wu, Yuan Yu, et al.. (2025). Thermoelectric interface materials for reliable power generation. Materials Today. 90. 838–858.
6.
Wang, Longquan, et al.. (2025). Self-optimized contact in air-robust thermoelectric junction towards long-lasting heat harvesting. Nature Communications. 16(1). 1502–1502. 11 indexed citations
7.
Wang, Longquan, et al.. (2025). Active Diffusion Controlled Dual Stability in Thermoelectrics for Sustainable Heat Harvesting. Advanced Materials. 37(38). e2508270–e2508270. 1 indexed citations
8.
Zhang, Yiming, Bo Li, Zhijia Han, et al.. (2024). Orientation optimization for high performance Mg3Sb2 thermoelectric films via thermal evaporation. Nanotechnology. 35(45). 455701–455701. 1 indexed citations
9.
Wu, Xinzhi, Yangjian Lin, Chengyan Liu, et al.. (2024). A high performance eco-friendly MgAgSb-based thermoelectric power generation device near phase transition temperatures. Energy & Environmental Science. 17(8). 2879–2887. 27 indexed citations
10.
Zhang, Jiajia, Caichao Ye, Liang Guo, et al.. (2024). Polaron interfacial entropy as a route to high thermoelectric performance in DAE-doped PEDOT:PSS films. National Science Review. 11(3). nwae009–nwae009. 9 indexed citations
11.
Wang, Yupeng, Xinzhi Wu, Yu Mao, et al.. (2024). Thermoelectric cyclic-thermal regulation: A new operational mode of thermoelectric materials with high energy efficiency. Joule. 8(11). 3201–3216. 6 indexed citations
12.
Ding, Chao, et al.. (2023). Fabrication of hypereutectic Al–Si alloy with improved mechanical and thermal properties by hot extrusion. Materials Characterization. 202. 113026–113026. 20 indexed citations
13.
Wu, Xinzhi & Weishu Liu. (2023). An engineering roadmap for the thermoelectric interface materials. Journal of Materiomics. 10(3). 748–750. 8 indexed citations
14.
Wu, Xinzhi, Yongbin Zhu, Chengliang Xia, et al.. (2023). Boosting room-temperature thermoelectric performance of Mg3Sb1.5Bi0.5 material through breaking the contradiction between carrier concentration and carrier mobility. Acta Materialia. 265. 119636–119636. 16 indexed citations
15.
Li, Huan, Yupeng Wang, Kang Zhu, et al.. (2023). General Figures of Merit ZQ for Thermoelectric Generators Under Constant Heat‐In Flux Boundary. Advanced Science. 10(32). e2303695–e2303695. 5 indexed citations
16.
Wu, Xinzhi, Yangjian Lin, Chengyan Liu, et al.. (2023). Interface Engineering Boosting High Power Density and Conversion Efficiency in Mg2Sn0.75Ge0.25‐Based Thermoelectric Devices. Advanced Energy Materials. 13(32). 16 indexed citations
17.
Wu, Xinzhi, Yangjian Lin, Zhijia Han, et al.. (2022). Interface and Surface Engineering Realized High Efficiency of 13% and Improved Thermal Stability in Mg3Sb1.5Bi0.5‐Based Thermoelectric Generation Devices. Advanced Energy Materials. 12(48). 54 indexed citations
18.
Jiang, Feng, Tao Feng, Yongbin Zhu, et al.. (2022). Extraordinary thermoelectric performance, thermal stability and mechanical properties of n-type Mg3Sb1.5Bi0.5 through multi-dopants at interstitial site. Materials Today Physics. 27. 100835–100835. 35 indexed citations
19.
Zhu, Yongbin, Zhijia Han, Bing Han, et al.. (2021). Enhanced Thermoelectric Performance by Strong Phonon Scattering at the Heterogeneous Interfaces of the Mg2Sn/Mg3Sb2 High-Content Nanocomposite. ACS Applied Materials & Interfaces. 13(47). 56164–56170. 22 indexed citations
20.
Wu, Xinzhi, et al.. (2021). Interfacial interactions between different metal oxides and dibenzyl disulfide in mineral insulating oil. Journal of Molecular Liquids. 347. 118359–118359. 3 indexed citations

Rankless uses publication and citation data sourced from OpenAlex, an open and comprehensive bibliographic database. While OpenAlex provides broad and valuable coverage of the global research landscape, it—like all bibliographic datasets—has inherent limitations. These include incomplete records, variations in author disambiguation, differences in journal indexing, and delays in data updates. As a result, some metrics and network relationships displayed in Rankless may not fully capture the entirety of a scholar's output or impact.

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