安盟,北京理工大学副教授,国家级青年人才,日本文部省学术振兴会JSPS特别研究员,浙江省海外青年人才计划,陕西省科技新星等。主要从事微纳尺度材料与界面导热特性和微纳尺度热物性测量的研究工作。2019-2022年在清华大学马维刚教授课题组从事博士后研究,关注飞秒激光泵浦探测、双波长闪光拉曼测量纳米材料和界面导热性质研究,2022-2025年在东京大学Shiomi Junichiro教授从事日本学术振兴会特别研究员研究,关注固液界面导热和受限空间液体热物性测量研究。以第一作者、共同一作或通讯作者在SCI收录期刊发表学术论文100余篇,Google学术引用4600余次,成果发表于Nature Communications(4篇)、Science Advances、Proceedings of the National Academy of Sciences、Advanced Materials(5篇)、International Journal of Heat and Mass Transfer(15篇)、Energy & Environmental Science、Advanced Energy Materials、Advanced Functional Materials(7篇)、Nano Letters、Advanced Science等国际高水平期刊。受邀以第一作者编写英文著作《Chalcogenide semiconductors: from 3D to 2D and beyond》第11章“硫化物热输运性质”,爱思唯尔(Elsevier)出版社,ISBN: 978-0-08-102687-8。担任2025年第三届世界材料大会先进热管理材料分会联合主席,2024智能材料设计国际会议组委会主席。受邀2020年在澳大利亚纽卡斯尔举行的第四届新兴先进纳米材料国际会议作特邀报告。曾分别在2024 智能材料设计国际会议,2024 MRS春季会议,2023年The 7th Phonon Engineering Workshp, 2023日本传热年会,2022 日本应用物理年会,2017 Phononics 国际会议和2018第16届国际传热大会做口头报告、在2017美国材料学会春季会议做张贴报告,均受到纳米传热领域专家们的认可;担任国际知名SCI 收录期刊《Chinese Chemical Letters》(中国化学快报)青年编委;担任Nano Thermal期刊副主编,Journal of Modern Green Energy期刊编委,担任在Energy Materials、Review of Materials Research、Energy Materials和Frontiers in Mechanical Engineering期刊客座主编。
(1) 微纳尺度材料和界面的热传导特性与热物性测量;
(2) 机器学习和人工智能驱动热器件和热功能材料的优化与设计;
(3) 面向功率芯片散热的热物理性测量与热界面材料开发与应用;
(4) 柔性多触觉能量转换器件开发与材料性能优化。
通讯地址:北京市海淀区,北京理工大学
邮箱:anmeng@bit.edu.cn
Researcher ID: 
orcid.org/0000-0002-1560-7329; Google Scholar: Meng AN;
Researchgate: Meng An
~微纳尺度材料与界面导热~
1. Anomalous enhancement of thermal conduction across twisted van der Waals heterointerfaces, 123 (9), Proceedings of the National Academy of Sciences, e2531049123, 2026.
2. Moisture sorption and hydration dynamics in intrinsically hygroscopic hydrogels, Science Advances, in press, 2026.
3. Generalized two-temperature model for coupled phonons in nanosized graphene. Nano Letters, 17, 5805, 2017.
4. Heat conduction modulation in incommensurate twisted stacking of transition-metal dichalcogenide, Advanced Functional Materials, 2422761, 2025.
5. Enhancement of interfacial thermal conductance at semiconductor/polymer interfaces induced by intercalating water layer in humidity environment, International Journal of Heat and Mass Transfer, 239, 126495, 2025.
6. Directly visualizing the crossover from incoherent to coherent phonons in two-dimensional periodic MoS2/MoSe2 arrayed heterostructure. International Journal of Heat and Mass Transfer, 178, 121630, 2021.
7. Regulatable thermal conductivity and excellent mass transport of water-filled carbon nanotube as capillary wicks, International Journal of Heat and Mass Transfer, 195, 123211, 2022.
8. Anomalous thermal conductivity enhancement in twisted graphene/-BN bilayers revealed by neuroevolution potential driven atomistic simulations, Physical Review B, 113 (3), 035426, 2026.
9. Data-driven prediction of thermal conductivity from short MD trajectories: a GCN-LSTM approach, Chinese Physics Letters, 43 (2), 020801, 2026.
10. Softening of vibrational modes and anharmonicity induced thermal conductivity reduction in a-Si: H at high temperatures, Advanced Electronic Materials, 2500104, 2025.
~热功能材料与热能转换器件~
11. Reversible bipolar thermopower of ionic thermoelectric polymer composite for cyclic energy generation, Nature Communications, 14(1), 306, 2023.
12. Tailoring P-N conversion in all-solid-state polymer composites with a record ionic thermopower. Nature Communications, 13(1), 1-10, 2022.
13. Spider webs-inspired aluminum coordination hydrogel piezoionic sensors for tactile nerve systems, Advanced Functional Materials, 35(4), 2414016, 2025.
14. Mineral tanning-inspired metal ions coordination hydrogels with outstanding mechanical strength and toughness for flexible force sensors, Advanced Functional Materials, 34, 21, 2313633, 2024.
15. Reconfiguring Zn deposition dynamics via epitaxial Zn2+ pathway in profiled viscose Rayon for long-cyclability Zinc-Ion batteries, Energy & Environmental Science, 18, 5457-5469, 2025.
16. Near-100% site utilization of single atoms for efficient electrocatalysis, Nature Communications, 17, 1013, 2026.
17. Unlocking the trade-off between intrinsic and interfacial thermal transport of boron nitride nanosheets by surface functionalization for advanced thermal interface materials, Advanced Materials, 37(1), 2412137, 2025.
18. A thermochromic, viscoelastic nacre-like nanocomposite for the smart thermal management of planar electronics. Nano-Micro Letters, 15(1), 170, 2023.
19. Electrically regulated thermal conductivity of aramid polymer systems, Applied Physics Letters, 124 (12), 2024.
20. Molecularly engineered rigid ultra-micropore membranes for ultrahigh-power osmotic energy harvesting from high-temperature hypersaline brine, Advanced Materials, 37, 29, 2505458, 2025.
21. Anti-swelling polyelectrolyte hydrogel with submillimeter lateral confinement for osmotic energy conversion, Nano-Micro Letters, 17(11), 1-15, 2025.
22. Large-area graphene-based ion-selective membranes with micro/meso-pores for osmotic energy Harvesting. Advanced Functional Materials, 2401922, 2024.
23. Low-friction graphene oxide-based ion selective membrane for high-efficiency osmotic energy harvesting. Advanced Energy Materials, 2302262, 2023.
~固液气相变传热~
24. Spatially regulated water-heat transport by fluidic diode membrane for efficient solar-powered desalination and electricity generation, Nature Communications, 16(1), 5050, 2025.
25. Anti-swelling textile power generator with 1D nanoscale channel alignment in nanofiber/graphene hybrid Yarns, Advanced Functional Materials, e10758, 2025.
26. Solar evaporator coupled with strong/weak convection and its cascade utilization, Science Bulletin, 70(8), 1264-1274, 2025.
27. Hydrogel fiber fabric combining rapid water transport, thermal localization, and large-scale production for ultra-high salt-resistant solar desalination, Nano Energy, 108847, 2023.
28. Tilted crack-engineered photothermal membranes achieve attenuation-free solar evaporation and oil recovery from emulsions. Advanced Materials, e15845, 2025.
29. 4D-printed dual-functional hydrogels breaking the trade-off between rapid kinetics and ultrahigh water uptake for atmospheric water harvesting, Advanced Materials, 38 (10), e16698, 2026.
30. Anisotropic biomass microfluidics via directed moisture transport and enhanced water-binding capacity for high-yield solar-driven atmospheric water harvesting, Advanced materials, e22241, 2026.
1. 国家级青年人才
2. 日本学术振兴会JSPS Fellowship
3. 浙江省海外青年人才
4. 陕西省青年科技新星
5. 陕西省高校青年杰出人才
6. 华中科技大学知行奖学金三等奖
7. 研究生国家奖学金
8. 研究生曾永裕奖学金
9. 研究生华藏奖学金
Scholat.com/anmeng0618
