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范宇馳研究員

  范宇馳，東華大學(xué)研究員，博士生導(dǎo)師。2013年于日本東北大學(xué)材料加工專(zhuān)業(yè)獲得工學(xué)博士學(xué)位，之后入選日本學(xué)術(shù)振興會(huì)特別研究員（JSPS Fellow）并繼續(xù)在東北大學(xué)從事高性能結(jié)構(gòu)陶瓷復(fù)合材料的研究；2015年加入日本九州大學(xué)應(yīng)用化學(xué)系從事面向能源應(yīng)用的低維粉體復(fù)合材料的開(kāi)發(fā)工作，同時(shí)兼任WPI國(guó)際碳中和能源研究所(I2CNER)研究員。2016年進(jìn)入東華大學(xué)工作。截至目前，已獲批并主持國(guó)家優(yōu)秀青年基金、上海市曙光計(jì)劃、上海高校特聘教授（東方學(xué)者）、上海市浦江人才計(jì)劃（A類(lèi)）等國(guó)家級(jí)及省部級(jí)人才項(xiàng)目，主持多項(xiàng)國(guó)自然基金、原創(chuàng)探索專(zhuān)項(xiàng)計(jì)劃、原創(chuàng)探索延續(xù)性資助及上海市自然基金面上項(xiàng)目和滾動(dòng)項(xiàng)目。于2018年獲得上海市自然科學(xué)二等獎(jiǎng)。長(zhǎng)期從事結(jié)構(gòu)-功能一體化復(fù)相陶瓷和陶瓷材料低溫?zé)Y(jié)研究，在Nat. Commun.、Adv. Mater.、Adv. Energy Mater.、Adv. Funct. Mater.、Adv. Sci.、Small、ACTA Mater.等國(guó)際知名期刊發(fā)表SCI論文100余篇。

研究方向：

1、  陶瓷超低溫?zé)Y(jié)技術(shù)

2、  結(jié)構(gòu)-功能一體化陶瓷

3、  電磁波吸收/屏蔽陶瓷

4、  先進(jìn)光學(xué)透明陶瓷

5、  陶瓷基復(fù)合材料

榮譽(yù)及獲獎(jiǎng)情況：

1、  上海市自然科學(xué)二等獎(jiǎng)

近年來(lái)承擔(dān)的主要科研項(xiàng)目：

1、  2026-01~至今 國(guó)家自然科學(xué)基金（原創(chuàng)探索項(xiàng)目延續(xù)性資助） 在研

2、  2025-01~至今 上海市“曙光計(jì)劃” 在研

3、  2025-01~至今 國(guó)家自然科學(xué)基金面上項(xiàng)目  在研

4、  2024-12~至今 上海市自然科學(xué)基金項(xiàng)目 在研

5、  2024-01~2024-12 國(guó)家自然科學(xué)基金（原創(chuàng)探索項(xiàng)目) 結(jié)題

6、  2023-01~至今 海市自然科學(xué)基金“科技創(chuàng)新項(xiàng)目” 在研

7、  2022-01~2024-12 國(guó)家自然科學(xué)基金優(yōu)秀青年科學(xué)基金項(xiàng)目 結(jié)題

8、  2021-07~2024-06 上海市自然科學(xué)基金項(xiàng)目 結(jié)題

9、  2020-01~2023-12 國(guó)家自然科學(xué)基金面上項(xiàng)目 結(jié)題

10、2019-12~2022-12 上海市“東方學(xué)者”計(jì)劃 結(jié)題

11、2018-01~2020-12 國(guó)家自然科學(xué)基金青年基金項(xiàng)目  結(jié)題

12、2017-07~2019-06 上海市“浦江人才計(jì)劃”  結(jié)題

13、2017-05~2020-04 上海市自然科學(xué)基金 結(jié)題

近年來(lái)發(fā)表的代表性論著、專(zhuān)利：

論文（部分）

1、     Si, M. et al. Switchable Electromagnetic Absorption and Shielding in Liquid Metal-ZnO Ceramics via Ultralow-Electric-Field. Advanced Functional Materials, e74171, doi:https://doi.org/10.1002/adfm.74171 (2026).

2、     Min, J. et al. Continuous polyimide fiber reinforced ceramic matrix composites with high-temperature flame retardancy and mechanical reliability. Journal of Materials Science & Technology251, 81-88, doi:https://doi.org/10.1016/j.jmst.2025.06.027 (2026).

3、     Zhu, G. et al. Accelerating Tandem Electroreduction of Nitrate to Ammonia via Multi-Site Synergy in Mesoporous Carbon-Supported High-Entropy Intermetallics. Advanced Materials37, 2413560, doi:https://doi.org/10.1002/adma.202413560 (2025).

4、     Yan, P. et al. Hard, strong, and tough cold-sintered α-quartz composites as high-performance structural ceramics. Journal of Materiomics11, 101076, doi:https://doi.org/10.1016/j.jmat.2025.101076 (2025).

5、     Wu, S. et al. Enhanced thermoelectric performance in CuAgSe/Cu₂Se composite by cold sintering mediated nanoengineering. Scripta Materialia269, 116901, doi:https://doi.org/10.1016/j.scriptamat.2025.116901 (2025).

6、     Liu, Y. et al. Electric Double-Layer Structured Grain Boundaries in Medium-Entropy Perovskite Enable Robust Electromagnetic Interference Shielding after 1200 °C Oxidation. Small21, 2502782, doi:https://doi.org/10.1002/smll.202502782 (2025).

7、     Gao, J. et al. Cold sintering of CsPbBr3 quantum dots embedded KBr ceramics for LED displays. Journal of Materiomics11, 100933, doi:https://doi.org/10.1016/j.jmat.2024.100933 (2025).

8、     Yan, P. et al. Large internal stress induced nonlinear current-voltage behavior in nanodiamond strengthened ZnO ceramics. Nature Communications15, 9812, doi:10.1038/s41467-024-54279-x (2024).

9、     Lu, W. et al. Cold Sintering Mediated Engineering of Polycrystalline SnSe with High Thermoelectric Efficiency. ACS Applied Materials & Interfaces16, 4671-4678, doi:https://doi.org/10.1021/acsami.3c15970 (2024).

10、Liu, Y. et al. A Highly Deficient Medium-Entropy Perovskite Ceramic for Electromagnetic Interference Shielding under Harsh Environment. Advanced Materials36, 2400059, doi:https://doi.org/10.1002/adma.202400059 (2024).

11、Hu, Y. et al. Strong and Robust Core–Shell Ceramic Fibers Composed of Highly Compacted Nanoparticles for Multifunctional Electronic Skin. Small20, 2404080, doi:https://doi.org/10.1002/smll.202404080 (2024).

12、Mustafa, T. et al. Highly aligned reduced graphene oxide in alumina composites for strengthening, toughening, and electromagnetic interference shielding. Journal of Materiomics9, 993-1003, doi:https://doi.org/10.1016/j.jmat.2023.03.005 (2023).

13、Gao, J. et al. Cold Sintering of Highly Transparent Calcium Fluoride Nanoceramic as a Universal Platform for High-Power Lighting. Advanced Functional Materials33, 2302088, doi:https://doi.org/10.1002/adfm.202302088 (2023).

14、Xiong, Z. et al. Integrating thin wall into block: A new scanning strategy for laser powder bed fusion of dense tungsten. Journal of Materials Science & Technology120, 167-171, doi:https://doi.org/10.1016/j.jmst.2021.11.066 (2022).

15、Luo, W. et al. A Robust Hierarchical MXene/Ni/Aluminosilicate Glass Composite for High-Performance Microwave Absorption. Advanced Science9, 2104163, doi:https://doi.org/10.1002/advs.202104163 (2022).

16、Huang, J. et al. Mechanically exfoliated MoS₂ nanoflakes for optimizing the thermoelectric performance of SrTiO3-based ceramic composites. Journal of Materiomics8, 790-798, doi:https://doi.org/10.1016/j.jmat.2022.02.002 (2022).

17、Guo, R., Zheng, Q., Wang, L., Fan, Y. & Jiang, W. Porous N-doped Ni@SiO2/graphene network: Three-dimensional hierarchical architecture for strong and broad electromagnetic wave absorption. Journal of Materials Science & Technology106, 108-117, doi:https://doi.org/10.1016/j.jmst.2021.07.046 (2022).

18、Gao, J. et al. Realizing translucency in aluminosilicate glass at ultralow temperature via cold sintering process. Journal of Advanced Ceramics11, 1714-1724, doi:10.1007/s40145-022-0642-y (2022).

19、Zhu, S. et al. Modulating electromagnetic interference shielding performance of ultra-lightweight composite foams through shape memory function. Composites Part B: Engineering204, 108497, doi:https://doi.org/10.1016/j.compositesb.2020.108497 (2021).

20、Zhu, S. et al. Multi-functional and highly conductive textiles with ultra-high durability through ‘green’ fabrication process. Chemical Engineering Journal406, 127140, doi:https://doi.org/10.1016/j.cej.2020.127140 (2021).

21、Zhou, W., Yang, P., Fan, Y., Nomura, N. & Kawasaki, A. Simultaneous enhancement of dispersion and interfacial adhesion in Al matrix composites reinforced with nanoceramic-decorated carbon nanotubes. Materials Science and Engineering: A804, 140784, doi:https://doi.org/10.1016/j.msea.2021.140784 (2021).

22、Yang, X. et al. Mesoporous Materials–Based Electrochemical Biosensors from Enzymatic to Nonenzymatic.Small17, 1904022, doi:https://doi.org/10.1002/smll.201904022 (2021).

23、Su, L. et al. Achieving effective broadband microwave absorption with Fe₃O₄@C supraparticles. Journal of Materiomics7, 80-88, doi:https://doi.org/10.1016/j.jmat.2020.07.011 (2021).

24、Li, J. et al. Graphene controlled phase evolution in Sr-deficient Sr(Ti, Nb)O₃ thermoelectric ceramics. Journal of Materiomics7, 366-376, doi:https://doi.org/10.1016/j.jmat.2020.07.004 (2021).

25、Fang, Y. et al. Incorporating Cobalt Nanoparticles in Nitrogen-Doped Mesoporous Carbon Spheres through Composite Micelle Assembly for High-Performance Lithium–Sulfur Batteries. ACS Applied Materials & Interfaces13, 38604-38612, doi:https://doi.org/10.1021/acsami.1c10227 (2021).

26、Zhou, B.-Y. et al. Recent progress in ceramic matrix composites reinforced with graphene nanoplatelets. Rare Metals39, 513-528, doi:https://doi.org/10.1007/s12598-019-01306-2 (2020).

27、Zhao, T. et al. Confined interfacial micelle aggregating assembly of ordered macro–mesoporous tungsten oxides for H2S sensing. Nanoscale12, 20811-20819, doi:10.1039/D0NR06428A (2020).

28、Lu, X. et al. High-Efficiency Thermoelectric Power Generation Enabled by Homogeneous Incorporation of MXene in (Bi,Sb)₂Te₃ Matrix. Advanced Energy Materials10, 1902986, doi:https://doi.org/10.1002/aenm.201902986 (2020).

29、Huang, J. et al. Simultaneously Breaking the Double Schottky Barrier and Phonon Transport in SrTiO₃-Based Thermoelectric Ceramics via Two-Step Reduction. ACS Applied Materials & Interfaces12, 52721-52730, doi:10.1021/acsami.0c16084 (2020).

30、Guo, R., Fan, Y., Wang, L. & Jiang, W. Core-rim structured carbide MXene/SiO₂ nanoplates as an ultrathin microwave absorber. Carbon169, 214-224, doi:https://doi.org/10.1016/j.carbon.2020.07.054 (2020).

31、Fan, Y. et al. Liquid-Phase Assisted Engineering of Highly Strong SiC Composite Reinforced by Multiwalled Carbon Nanotubes. Advanced Science7, 2002225, doi:https://doi.org/10.1002/advs.202002225 (2020).

32、Zhou, Z. et al. Uniform dispersion of SiC in Yb-filled skutterudite nanocomposites with high thermoelectric and mechanical performance. Scripta Materialia162, 166-171, doi:https://doi.org/10.1016/j.scriptamat.2018.11.015 (2019).

33、Zhou, Z. et al. Microstructure and composition engineering Yb single-filled CoSb₃ for high thermoelectric and mechanical performances. Journal of Materiomics5, 702-710, doi:https://doi.org/10.1016/j.jmat.2019.04.008 (2019).

34、Zhou, W. et al. Interfacial reaction induced efficient load transfer in few-layer graphene reinforced Al matrix composites for high-performance conductor. Composites Part B: Engineering167, 93-99, doi:https://doi.org/10.1016/j.compositesb.2018.12.018 (2019).

35、Zhou, W. et al. Corrigendum to “Interfacial reaction induced efficient load transfer in few-layer graphene reinforced Al matrix composites for high-performance conductor” [Compos Part B: Eng 167 (2019) 93–99]. Composites Part B: Engineering179, 107463, doi:https://doi.org/10.1016/j.compositesb.2019.107463 (2019).

36、Zhao, T. et al. Hierarchical Branched Mesoporous TiO₂–SnO₂ Nanocomposites with Well-Defined n–n Heterojunctions for Highly Efficient Ethanol Sensing. Advanced Science6, 1902008, doi:https://doi.org/10.1002/advs.201902008 (2019).

37、Ma, J. et al. Ultrathin and Light-Weight Graphene Aerogel with Precisely Tunable Density for Highly Efficient Microwave Absorbing. ACS Applied Materials & Interfaces11, 46386-46396, doi:https://doi.org/10.1021/acsami.9b17849 (2019).

38、Lu, X. et al. Structurally nanocrystalline electrically monocrystalline Sb2Te3 with high thermoelectric performance. Scripta Materialia166, 81-86, doi:https://doi.org/10.1016/j.scriptamat.2019.03.013 (2019).

39、Chen, X. et al. Carbon-Encapsulated Copper Sulfide Leading to Enhanced Thermoelectric Properties. ACS Applied Materials & Interfaces11, 22457-22463, doi:10.1021/acsami.9b06212 (2019).

專(zhuān)利（部分）

1、     范宇馳、蔡正波等，一種基于芳綸纖維織物的陶瓷基復(fù)合材料的制備方法，CN202210262344.4

2、     王連軍、范宇馳等，一種吸波材料及其制備方法和應(yīng)用，CN202210081402.3

3、     范宇馳、嚴(yán)廣山等，一種高強(qiáng)度和高硬度的細(xì)晶α相氧化鋁陶瓷的制備方法，CN202011561148.4

4、     范宇馳、顏鵬等，一種高強(qiáng)度高韌性的碳化硅納米線(xiàn)增強(qiáng)碳化硅陶瓷復(fù)合材料的制備方法，CN202010876982.6

5、     王連軍、郭蕊等，核-邊結(jié)構(gòu)的碳化物MXene/SiO2納米板狀超薄微波吸收材料，CN202010424641.5

6、     范宇馳、陸曉芳等，一種二維過(guò)渡金屬碳化物/碲化鉍或其衍生物基熱電復(fù)合材料及其制備，CN201910974580.7

7、     范宇馳、杜繼實(shí)等，一種氧化物梯度復(fù)相陶瓷核電用饋通線(xiàn)及其制備和應(yīng)用，CN201910269773.2

主要學(xué)術(shù)兼職：

1、    擔(dān)任中國(guó)硅酸鹽學(xué)會(huì)特種陶瓷分會(huì)、測(cè)試技術(shù)分會(huì)理事，中國(guó)稀土學(xué)會(huì)陶瓷材料專(zhuān)業(yè)委員會(huì)理事，上海硅酸鹽學(xué)會(huì)理事

2、    擔(dān)任Interdisciplinary Materials 期刊Academic editor, International Journal of Applied Ceramics期刊Associate editor, Crystals期刊Editorial board member，Journal of Materiomics、《現(xiàn)代技術(shù)陶瓷》編委，Jounal of Materials Science and Technology期刊青年編委

國(guó)際交流與合作：

在注重科研工作與培養(yǎng)研究生的同時(shí)，積極參與本領(lǐng)域內(nèi)的眾多國(guó)際學(xué)術(shù)會(huì)議，多次受邀在重要國(guó)際學(xué)術(shù)會(huì)議上做學(xué)術(shù)報(bào)告，為項(xiàng)目合作以及國(guó)際科研視野奠定了重要基礎(chǔ)，與此同時(shí)同日本東北大學(xué)、日本九州大學(xué)等國(guó)際國(guó)際名校建立了良好的研究合作關(guān)系，為研究生參與國(guó)際學(xué)術(shù)交流以及輸送優(yōu)秀博士后創(chuàng)造更多機(jī)會(huì)。

課題組長(zhǎng)期招收具有材料、物理、化學(xué)等背景的博士后研究員、博士研究生和碩士研究生。

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