学术成果
[1] Zheng, Q.-S.: Theory of representations for tensor functions — A unified invariant approach to constitutive equations. Applied Mechanics Review 47, 545-587 (1994).
[2] Zheng, Q.-S.: On transversely isotropic, orthotropic and relative isotropic functions of symmetric tensors, skew-symmetric tensors and vectors: Parts I – V. International Journal of Engineering Science 31, 1399-1409; 1411-1423; 1425-1433; 1435-1443; 1445-1453 (1993).
[3] Zheng, Q.-S., Du, D.-X.: An explicit and universally applicable estimate for the properties of multiphase composites which accounts for inclusion distribution. Journal of the Mechanics and Physics of Solids 49, 2765-2788 (2001).
[4] Zou, W.-N., et al.: Eshelby’s problem of non-elliptical inclusions. Journal of the Mechanics and Physics of Solids 58, 346-372 (2010).
[5] Zheng, Q.-S., Jiang, Q.: Multiwalled carbon nanotubes as gigahertz oscillators. Physical Review Letters 88, 045503 (2002).
[6] Zheng, Q.-S. et al.: Self-retracting motion of graphite microflakes. Physical Review Letters 100,.067205 (2008).
[7] Liu, Z. et al.: Observation of microscale superlubricity in graphite. Physical Review Letters 108, 205503 (2012).
[8] Yang, J. et al.: Observation of high-speed microscale superlubricity in graphite. Physical Review Letters 110, 255504 (2013).
[9] Wang, W. et al.: Measurement of the cleavage energy of graphite; Nature Communications 6, 7853 (2015).
[10] Song, Y. et al.: Robust microscale superlubricity in graphite/hexagonal Boron Nitride layered heterojunctions. Nature Materials 17, 894–899 (2018).
[11] Hod, O. et al.: Structural superlubricity: Frictionless motion across the length-scales. Nature 563, 485-492 (2018).
[12] Zheng, Q.-S. et al.: Effects of hydraulic pressure on the stability and transition of wetting modes of superhydrophobic surfaces. Langmuir 21, 12207-12212 (2005).
[13] Li, Y.-S., et al.: Monostable superrepellent materials. PNAS 114, 3387–3392 (2017).
[14] Zheng, Q.-S. et al.: Small is beautiful, and dry. Science China - Physics, Mechanics & Astronomy 53, 2245–2259 (2010).
[15] Ma, M. et al.: Water transport inside carbon nanotubes mediated by phonon-induced oscillating friction, Nature Nanotechnology 10, 692-695 (2015).
[16] 郑泉水:开放式的创新人才培养. 水木清华, 10, 22-25 (2012).
[17] 郑泉水,白峰杉,苏芃,徐芦平,陈常青:清华大学钱学森力学班本科荣誉学位项目的探索. 中国大学教学, 08, 50-54 (2016).
[18] 郑泉水:论创新型工科的力学课程体系,力学与实践,40: 194-202 (2018).
[19] 郑泉水:“多维测评”招生:破解钱学森之问的最大挑战,中国教育学刊,5: 36-45 (2018).
[20] 郑泉水:序:十年寻心、任重道远,见郑泉水、何枫主编《求索创新教育,筑梦共赢未来—清华学堂人才培养计划钱学森力学班十周年纪念文集》,清华大学出版社,I-VII (2019).