Faculty

Jiaping, Wang  Professor

Department of Physics, Tsinghua University

Tsinghua-Foxconn Nanotechnology

Research Center

Beijing 100084, China

Phone:8610-62796007

Fax:8610-62792457

jpwang@tsinghua.edu.cn

Education and Employment

Education

Ph.D. in Materials Science, University of Cambridge, UK, 2002

B.Eng. in Materials Science and Engineering, Tsinghua University, China, 1996

Employment

Dept. of Physics, Tsinghua University, Professor (2014-)

Dept. of Physics, Tsinghua University, Associate Professor (2007-2014)

Dept. of Mechanical Engineering, Louisiana State University, USA, Assistant Professor (2005-2007)

Dept. of Materials Science and Engineering, Johns Hopkins University, USA, Postdoctoral Fellow

(2002-2005)

Teaching

2016-2024 Physics
2015-2023 Physics Laboratory

Research Interests

Fabrication and properties of functional nanocomposite materials and devices and their applications in energy storage, electronics, and sensing, etc.
Research areas: carbon nanotube/polymer composites; applications of carbon nanotubes for energy storage including lithium ion batteries, lithium sulfur batteries, and supercapacitors.

Selected Publications

ResearcherID: K-7499-2012

1. W. Yu, W. H. Dai, Z. X. Hong, G. X. Li, Z. Y. Wang, C. Z. Meng*, J. P. Wang*, C. H. Liu*, S. J. Guo, and S. S. Fan, “Continuously-tunable and ultrawide-range thermal regulator based on superaligned carbon nanotube aerogels for dynamic thermal management of batteries and buildings”, Adv. Funct. Mater., 2314021, (2024).

2. Y. F. Luo, Z. H. Fang, Z. X. Hong, S. R. Duan, H. T. Liu, H. C. Wu, Q. Q. Li, Y. G. Zhang, S. S. Fan, W. H. Duan, and J. P. Wang*, “Influences of chemical reactions on polysulfide reduction reaction process on promotor surface in Li-S batteries”, Nano Research, 17, 2712-2718, (2024).

3. Y. F. Luo, Z. H. Fang, S. R. Duan, H. C. Wu, H. T. Liu, Y. X. Zhao, K. Wang, Q. Q. Li, S. S. Fan, Z. J. Zheng, W. H. Duan, Y. G. Zhang, and J. P. Wang*, “Direct monitoring of Li2S2 evolution and its influence on the reversible capacities of lithium-sulfur battery”, Angewandte Chemie, 62, e202215802, (2023).

4. Y. X. Zhao, Y. H. Jin, X. Wang, J. Zhao, S. M. Wu, M. J. Li, J. P. Wang, S. S. Fan, Q. Q. Li, “A high linearity and energy-efficient artificial synaptic device based on scalable synthesized MoS2”, J. Mater. Chem. C, 11, 5616-5624, (2023).

5. M. J. Li, Z. L. Wang, Y. H. Jin, H. T. Yang, L. H. Zhang, H. J. Li, J. P. Wang, S. S. Fan, Q. Q. Li, “Highly efficient visible-blind ultraviolet photodetector based on scalably produced titanium dioxide nanowire arrays”, Nano Lett., 23, 6059-6066, (2023).

6. Z. X. Hong, Z. H. Fang, Y. F. Luo, H. C. Wu, H. Tian, F. Zhao, Q. Q. Li, S. S. Fan, and J. P. Wang*, “Promising nano-silicon anodes prepared by the “disperse-anchor” strategy and functional carbon nanotube interlayers for flexible lithium-ion batteries”, J. Mater. Chem. A, 10, 23509-23520, (back cover), (2022).

7. Z. H. Fang, Z. X. Hong, Y. F. Luo, Y. Liu, H. C. Wu, H. Tian, F. Zhao, Y. G. Zhang, Q. Q. Li, S. S. Fan, and J. P. Wang*, “Systematic study and effective improvement of voltammetry for accurate electrochemical window measurement of solid electrolytes”, Electrochimica Acta, 414, 140210, (2022).

8. Z. H. Fang, S. R. Duan, H. T. Liu, Z. X. Hong, H. C. Wu, F. Zhao, Q. Q. Li, S. S. Fan, W. H. Duan, and J. P. Wang*, “Lithium storage mechanism and application of micron-sized lattice-reversible binary intermetallic compounds as high-performance flexible lithium-ion battery anodes”, Small, 18, 2105172, (2022).

9. Z. H. Fang, Y. F. Luo, H. T. Liu, Z. X. Hong, H. C. Wu, F. Zhao, P. Liu, Q. Q. Li, S. S. Fan, and J. P. Wang*, “Boosting the oxidative potential of polyethylene glycol-based polymer electrolyte to 4.36 V by spatially restricting hydroxyl groups for high-voltage flexible lithium-ion battery applications”, Adv. Sci., 8, 2100736, (2021).

10. J. Wang, Z. Shi, Y. F. Luo, D. T. Wang, H. W. Liu, H. C. Wu, Q. Q. Li, S. S. Fan, J. Li, and J. P. Wang*, “Efficient polysulfide trapping in lithium-sulfur batteries using ultrathin and flexible BaTiO3/graphene oxide/carbon nanotube layers”, Nanoscale, 13, 6863-6870, (2021).

11. J. Wang, H. W. Liu, H. C. Wu, Q. Q. Li, Y. G. Zhang, S. S. Fan, and J. P. Wang*, “Self-standing carbon nanotube aerogels with amorphous carbon coating as stable host for lithium anodes”, Carbon, 177, 181-188, (2021).

12. Y. H. Jin, T. F. Zhang, J. Zhao, Y. X. Zhao, C. Liu, J. Song, X. P. Hao, J. P. Wang*, K. L. Jiang, S. S. Fan, Q. Q. Li, “Spray coating of a perfect absorber based on carbon nanotube multiscale composites”, Carbon, 178, 616-624, (2021).

13. Z. L. Wang, L. W. Lai, T. F. Zhang, S. M. Wu, J. Zhao, Y. X. Zhao, Y. H. Jin, J. P. Wang*, S. S. Fan, Q. Q. Li, “Enhanced visible-light absorption and photocurrent generation of three-dimensional metal-dielectric hybrid-structured films”, ACS Appl. Energy Mater., 4 (10), 10542-10552, (2021).

14. Y. Yu, Z. H. Fang, Y. F. Luo, H. C. Wu, Q. Q. Li, S. S. Fan, and J. P. Wang*, “Ultra-stretchable supercapacitors based on biaxially pre-strained super-aligned carbon nanotube films”, Nanoscale, 12, 24259-24265, (2020).

15. Z. H. Fang, Y. F. Luo, H. C. Wu, L. J. Yan, F. Zhao, Q. Q. Li, S. S. Fan, and J. P. Wang*, “Mesoporous carbon nanotube aerogel-sulfur cathodes: a strategy to achieve ultrahigh areal capacity for lithium -sulfur batteries via capillary action”, Carbon, 166, 183-192, (2020).

16. Z. H. Fang, H. C. Wu, Q. Q. Li, S. S. Fan, and J. P. Wang*, “Progress and challenges of flexible lithium ion batteries”, J. Power Sources, 454, 227932, (2020). (invited review)

17. Y. F. Luo, K. Wang, Q. Q. Li, S. S. Fan, and J. P. Wang*, “Macroscopic carbon nanotube structures for lithium batteries”, Small, 1902719, (2020). (invited review)

18. C. Y. Li, S. Y. Zhao, K. L. Zhu, B. L. Wang, E. Z. Wang, Y. F. Luo, L. Q. He, J. P. Wang, K. L. Jiang, S. S. Fan, J. Li, K. Liu, “Flexible and free-standing hetero-electrocatalyst of high-valence-cation doped MoS2/MoO2/CNT foam with synergistically enhanced hydrogen evolution reaction catalytic activity”, J. Mater. Chem. A, 8(30), 14944-14954, (2020).

19. Y. H. Jin, T. F. Zhang, Z. Z. Huang, J. Zhao, Zhao, Y. X. Zhao, Z. L. Wang, L. W. Lai, J. P. Wang, K. L. Jiang, S. S. Fan, Q. Q. Li, “Broadband omnidirectional perfect absorber based on carbon nanotube films”, Carbon, 161, 510-516, (2020).

20. H. Y. Ding, Z. Q. Xin, Y. Y. Yang, Y. F. Luo, K. L. Xia, B. L. Wang, Y. F. Sun, J. P. Wang, Y. Y. Zhang, H. Wu, S. S. Fan, L. Zhang, K. Liu, “Ultrasensitive, low-voltage operational, and asymmetric ionic sensing hydrogel for multipurpose applications”, Adv. Funct. Mater., 30(12), 1909616, (2020).

21. X. Jin, H. X. Tan, Z. P. Wu, J. C. Liang, W. T. Miao, C. S. Lian, J. T. Wang, K. Liu, H. M. Wei, C. Feng, P. Liu, Y. Wei, Q. Q. Li, J. P. Wang, L. Liu, X. D. Li, S. S. Fan, W. H. Duan, K. L. Jiang, “Continuous, ultra-lightweight, and multipurpose super-aligned carbon nanotube tapes viable over a wide range of temperatures”, Nano Lett., 19, 6756-6764, (2019).

22. L. J. Jia, J. Wang, Z. J. Chen, Y. P. Su, W. Zhao, D. T. Wang, Y. Wei, K. L. Jiang, J. P. Wang, Y. Wu, J. Li, W. H. Duan, S. S. Fan, Y. G. Zhang, “High areal capacity flexible sulfur cathode based on multi-functionalized super-aligned carbon nanotubes”, Nano Research, 12, 1105-1113, (2019).

23. Y. C. Wang, Y. H. Jin, T. F. Zhang, Z. Z. Huang, H. T. Yang, J. P. Wang, K. L. Jiang, S. S. Fan, Q. Q. Li, “Emission enhancement from CdSe/ZnS quantum dots induced by strong localized surface plasmonic resonances without damping”, J. Phys. Chem. Lett., 10, 2113-2120, (2019).

24. Z. Z. Huang, T. F. Zhang, J. K. Liu, L. H. Zhang, Y. H. Jin, J. P. Wang, K. L. Jiang, S. S. Fan, Q. Q. Li, “Amorphous MoS2 photodetector with ultra-broadband response”, ACS Appl. Electron. Mater., 1, 1314-1321, (2019).

25. X. Y. Xiao, M. Chen, J. Zhang, T. F. Zhang, L. H. Zhang, Y. H. Jin, J. P. Wang, K. L. Jiang, S. S. Fan, and Q. Q. Li, “Sub-10 nm monolayer MoS2 transistors using single-walled carbon nanotubes as an evaporating mask”, ACS Appl. Mater. Interfaces, 11, 11612-11617, (2019).

26. Y. F. Luo, H. C. Wu, L. Liu, Q. Q. Li, K. L. Jiang, S. S. Fan, J. Li, andJ. P. Wang*, “TiO2-Nanocoated Black Phosphorus Electrodes with Improved Electrochemical Performance”, ACS Appl. Mater. Interfaces, 10, 36058-36066, (2018).

27. Y. Yu, Y. F. Luo, H. C. Wu, K. L. Jiang, Q. Q. Li, S. S. Fan, J. Li, andJ. P. Wang*, “Ultrastretchable Carbon Nanotube Composite Electrodes for Flexible Lithium-Ion Batteries”, Nanoscale, 10, 19972-19978, (2018).

28. W. B. Kong, D. T. Wang, L. J. Yan, Y. F. Luo, K. L. Jiang, Q. Q. Li, L. Zhang, S. G. Lu, S. S. Fan, J. Li, andJ. P. Wang*, “Ultrathin HfO2-modifiedcarbonnanotube films as efficient polysulfide barriers for Li-S batteries”, Carbon, 139, 896-905, (2018).

29. D. T. Wang, K. Wang, L. Sun, H. C. Wu, J. Wang, Y. X. Zhao, L. J. Yan, Y. F. Luo, K. L. Jiang, Q. Q. Li, S. S. Fan, J. Li, andJ. P. Wang*, “MnO2nanoparticles anchored on carbon nanotubes with hybrid supercapacitor-battery behavior for ultrafast lithium storage”, Carbon, 139, 145-155, (2018).

30. Y. F. Luo, K. Wang, S. Luo, F. Zhao, H. C. Wu, K. L. Jiang, Q. Q. Li, S. S. Fan, andJ. P. Wang*, “Three-dimensional carbon nanotube/transition-metal oxide sponges as composite electrodes with enhanced electrochemical performance”, ACS Appl. Nano Mater., 1, 2997-3005, (2018).

31. L. J. Yan, N. N. Luo, W. B. Kong, S. Luo, H. C. Wu, K. L. Jiang, Q. Q. Li, S. S. Fan, W. H. Duan*, andJ. P. Wang*, “Enhanced performance of lithium-sulfur batteries with an ultrathin and lightweight MoS2/carbon nanotube interlayer”, J. Power Sources, 389, 169-177, (2018).

32. D. T. Wang, K. Wang, H. C. Wu, Y. F. Luo, L. Sun, Y. X. Zhao, J. Wang, L. J. Jia, K. L. Jiang, Q. Q. Li, S. S. Fan, andJ. P. Wang*, “CO2oxidation of carbon nanotubes for lithium-sulfur batteries with improved electrochemical performance”, Carbon, 132, 370-379, (2018).

33. Y. F. Luo, N. N. Luo, W. B. Kong, H. C. Wu, K. Wang, S. S. Fan, W. H. Duan*, andJ. P. Wang*, “Multifunctional interlayer based on molybdenum diphosphide catalyst and carbon nanotube film for lithium-sulfur batteries”, Small, 14, 1702853, (2018).

34. K. L. Zhu, Y. F. Luo, F. Zhao, J. W. Hou, X. W. Wang, H. Ma, H. Wu, Y. G. Zhang, K. L. Jiang, S. S. Fan,J. P. Wang*, K. Liu*, “Free-Standing, binder-free titania/super-aligned carbon nanotube anodes for flexible and fast-charging li-ion batteries”, ACS Sustainable Chem. Eng., 6, 3426-3433, (2018).

35. J. T. Wang, X. Jin, Z. B. Liu, G. Yu, Q. Q. Ji, H. M. Wei, J. Zhang, K. Zhang, D. Q. Li, Z. Yuan, J. C. Li, P. Liu, Y. Wu, Y. Wei,J. P. Wang, Q. Q. Li, L. N. Zhang, J. Kong, S. S. Fan, and K. L. Jiang, “Growing highly pure semiconducting carbon nanotubes by electrotwisting the helicity”, Nature Catalysis, 1, 326-331, (2018).

36. W. Ning, Z. H. Wang, P. Liu, D. L. Zhou, S. Y. Yang,J. P. Wang, Q. Q. Li, S. S. Fan, K. L. Jiang, “Multifunctional super-aligned carbon nanotube/polyimide composite film heaters and actuators”, Carbon, 139, 1136-1143, (2018).

37. Y. C. Wang, Y. H. Jin, X. Y. Xiao, T. F. Zhang, H. T. Yang, Y. D. Zhao,J. P. Wang, K. L. Jiang, S. S. Fan, Q. Q. Li, “Flexible, transparent and highly sensitive SERS substrates with cross-nanoporous structures for fast on-site detection”, Nanoscale, 10, 15195-15204, (2018).

38. Z. Y. Huo, Y. F. Luo, X. Xie, C. Feng, K. L. Jiang,J. P. Wang*, and H. Y. Hu*, “Carbon-nanotube sponges enabling highly efficient and reliable cell inactivation by low-voltage electroporation”, Environ. Sci.: Nano, 4, 2010-2017, (2017).

39. Y. F. Luo, S. Luo, H. C. Wu, M. Y. Li, K. Wang, L. J. Yan, K. L. Jiang*, Q. Q. Li, S. S. Fan, andJ. P. Wang*, “Self-expansion construction of ultralight carbon nanotube aerogels with a three-dimensional and hierarchical cellular structure”, Small, 13, 1700966, (2017).

40. Y. Yu, Y. F. Luo, A. Guo, L. J. Yan, Y. Wu, K. L. Jiang, Q. Q. Li, S. S. Fan, andJ. P. Wang*, “Flexible and transparent strain sensors based on super-aligned carbon nanotube films”, Nanoscale, 9, 6716-6723, (2017).

41. W. B. Kong, L. J. Yan, Y. F. Luo, D. T. Wang, K. L. Jiang, Q. Q. Li, S. S. Fan, andJ. P. Wang*, “Ultrathin MnO2/graphene oxide/carbon nanotube interlayer as efficient polysulfide-trapping shield for high-performance Li-S batteries”, Adv. Funct. Mater., 27, 1606663, (2017).

42. K. Wang, Y. Wu, H. C. Wu, Y. F. Luo, D. T. Wang, K. L. Jiang, Q. Q. Li, Y. D. Li, S. S. Fan, andJ. P. Wang*, “Super-aligned carbon nanotube films with a thin metal coating as highly conductive and ultralight current collectors for lithium-ion batteries”, J. Power Sources, 351, 160-168, (2017).

43. L. J. Yan, K. Wang, S. Luo, H. C. Wu, Y. F. Luo, Y. Yu, K. L. Jiang, Q. Q. Li, S. S. Fan, andJ. P. Wang*, “Sandwich-structured cathodes with cross-stacked carbon nanotube film as conductive layer for high performance lithium-ion batteries”, J. Mater. Chem. A, 5, 4047-4057, (2017).

44. S. Luo, Y. F. Luo, H. C. Wu, M. Y. Li, L. J. Yan, K. L. Jiang*, L. Liu, Q. Q. Li, S. S. Fan,J. P. Wang*, “Self-assembly of 3D carbon nanotube sponges: a simple and controllable way to build macroscopic and ultralight porous architectures”, Adv. Mater., 29, 1603549, (2017).

45. Y. H. Jin, Y. C. Wang, M. Chen, X. Y. Xiao, T. F. Zhang,J. P. Wang, K. L. Jiang, S. S. Fan, and Q. Q. Li, “Highly sensitive, uniform, and reproducible surface-enhanced raman spectroscopy substrate with nanometer-scale quasi-periodic nanostructures”, ACS Appl. Mater. Interfaces, 9, 32369-32376, (2017).

46. Y. D. Zhao, X. Y. Xiao, Y. J. Huo, Y. C. Wang, T. F. Zhang, K. L. Jiang,J. P. Wang, S. S. Fan, and Q. Q. Li, “Influence of asymmetric contact form on contact resistance and schottky barrier, and corresponding applications of diode”, ACS Appl. Mater. Interfaces, 9, 18945-18955, (2017).

47. X. Y. Lin, W. Zhao, W. B. Zhou, P. Liu, S. Luo, H. M. Wei, G. Z. Yang, J. H. Yang, J. Cui, R. C. Yu, L. N. Zhang,J. P. Wang, Q. Q. Li, W. Y. Zhou, W. S. Zhao, S. S. Fan, and K. L. Jiang, “Epitaxial growth of aligned and continuous carbon nanofibers from carbon nanotubes”, ACS Nano, 11, 1257-1263, (2017).

48. D. Q. Li, J. Zhang, Y. J. He, Y. Qin, Y. Wei, P. Liu, L. N. Zhang,J. P. Wang, Q. Q. Li, S. S. Fan, and K. L. Jiang, “Scanning electron microscopy imaging of single-walled carbon nanotubes on substrates”, Nano Research, 10, 1804-1818, (2017).

49. Y. D. Zhao, Y. J. Huo, X. Y. Xiao, Y. C. Wang, T. F. Zhang, K. L. Jiang,J. P. Wang, S. S. Fan, and Q. Q. Li, “Inverse hysteresis and ultrasmall hysteresis thin-film transistors fabricated using sputtered dielectrics”, Adv. Electronic Mater., 3, 1600483, (2017).

50. L. Sun, W. B. Kong, M. Y. Li, H. C. Wu, K. L. Jiang, Q. Q. Li, Y. H. Zhang,J. P. Wang*, and S. S. Fan, “Cross-stacked carbon nanotube film as an additional built-in current collector and adsorption layer for high-performance lithium sulfur batteries”, Nanotechnology, 27, 075401, (2016).

51. L. Sun, D. T. Wang, Y. F. Luo, K. Wang, W. B. Kong, Y. Wu, L. N. Zhang, K. L. Jiang, Q. Q. Li, Y. H. Zhang,J. P. Wang*, and S. S. Fan, “Sulfur embedded in mesoporous carbon nanotube network as a binder-free electrode for high performance lithium sulfur batteries”, ACS Nano, 10, 1300-1308, (2016).

52. L. Sun, W. B. Kong, H. C. Wu, Y. Wu, D. T. Wang, F. Zhao, K. L. Jiang, Q. Q. Li,J. P. Wang*, and S. S. Fan, “Mesoporous Li4Ti5O12nanoclusters anchored on super-aligned carbon nanotubes as high performance electrodes for lithium ion batteries”, Nanoscale, 8, 617-625, (2016).

53. W. B. Kong, L. Sun, Y. Wu, K. L. Jiang, Q. Q. Li,J. P. Wang*, and S. S. Fan, “Binder-free polymer encapsulated sulfur-carbon nanotube composite cathodes for high performance lithium batteries”, Carbon, 96, 1053-1059, (2016).

54. Y. D. Zhao, D. Q. Li, L. Xiao, J. K. Liu, X. Y. Xiao, G. H. Li, Y. H. Jin, K. L. Jiang,J. P. Wang, S. S. Fan, Q. Q. Li, “Radiation effects and radiation hardness solutions for single-walled carbon nanotube-based thin film transistors and logic devices”, Carbon, 108, 363-371, (2016).

55. D. Y. Zhang, Y. H. Zhang, X. W. Li, Y. S. Luo, H. W. Huang,J. P. Wang, and P. K. Chu, “Self-assembly of mesoporous ZnCo2O4nanomaterials: density functional theory calculation and flexible all-solid-state energy storage”, J. Mater. Chem. A, 4, 568-577, (2016).

56. Y. D. Zhao, Q. Q. Li, X. Y. Xiao, G. H. Li, Y. H. Jin,J. P. Wang, K. L. Jiang, and S. S. Fan, “Three-dimensional flexible complementary metal–oxide–semiconductor logic circuits based on two-layer stacks of single-walled carbon nanotube networks”, ACS Nano, 10, 2193-2202, (2016).

57. J. T. Wang, P. Liu, B. Y. Xia, H. M. Wei, Y. Wei, Y. Wu, K. Liu, L. N. Zhang,J. P. Wang, Q. Q. Li, S. S. Fan, K. L. Jiang, “Observation of Charge Generation and Transfer during CVD Growth of Carbon Nanotubes”, Nano Lett. 16, 4102-4109, (2016).

58. Y. Yu, S. Luo, L. Sun, Y. Wu, K. L. Jiang, Q. Q. Li,J. P. Wang*, and S. S. Fan, “Ultra-stretchable conductors based on buckled super-aligned carbon nanotube films”, Nanoscale, 7, 10178-10185, (2015).

59. L. Sun, W. B. Kong, Y. Jiang, H. C. Wu, K. L. Jiang,J. P. Wang*, and S. S. Fan, “Super-aligned carbon nanotube/graphene hybrid materials as framework for sulfur cathodes in high performance lithium sulfur batteries”, J. Mater. Chem. A, 3, 5305-5312 (back cover), (2015).

60. S. Luo, Y. Yu, M. Y. Li, H. C. Wu, F. Zhao, K. L. Jiang,J. P. Wang*, F. Y. Kang, and S. S. Fan, “Synergistic effect of manganese oxide nanoparticles and graphene nanosheets in composite anodes for lithium ion batteries”, Mater. Res. Express, 2, 015503, (2015).

61. Y. C. Qiu, G. L. Rong, J. Yang, G. Z. Li, S. Ma, X. L. Wang, Z. H. Pan, Y Hou, M. N. Liu, F. M. Ye, W. F. Li, Z. W. Seh, X. Y. Tao, H. B. Yao, N. Liu, R. F. Zhang, G. M. Zhou,J. P. Wang, S. S. Fan, Y. Cui, and Y. G. Zhang, “Highly nitridated graphene-Li2S cathodes with stable modulated cycles”, Adv. Energy Mater., 5, 1501369, (2015).

62. S. C. Ma, Y. Wu, J. W. Wang, Y. L. Zhang, Y. T. Zhang, X. X. Yan, Y. Wei, P. Liu,J. P. Wang, K. L. Jiang, S. S. Fan, Y. Xu, Z. Q. Peng, Reversibility of Noble Metal-Catalyzed Aprotic Li-O2Batteries?”, Nano Lett., 15, p. 8084-8090, (2015).

63. Y. H. Jin, Q. Q. Li, M. Chen, G. H. Li, Y. D. Zhao, X. Y. Xiao,J. P. Wang, K. L. Jiang, and S. S. Fan, “Study of carbon nanotubes as etching masks and related applications in the surface modification of GaAs-based light-emitting diodes”, Small, 11, 4111-4116, (2015).

64. Y. H. Jin, Q. Q. Li, M. Chen, G. H. Li, Y. D. Zhao, X. Y. Xiao,J. P. Wang, K. L. Jiang, S. S. Fan, “Large area nanoscale metal meshes for use as transparent conductive layers”, Nanoscale, 7, 16508-16515, (2015).

65. W. Y. Wu, J. Y. Yue, X. Y. Lin, D. Q. Li, F. Q. Zhu, X. Yin, J. Zhu, J. T. Wang, J. Zhang, Y. Chen, X. H. Wang, T. Y. Li, Y. J. He, X. C. Dai, P. Liu, Y. Wei,J. P. Wang, W. Zhang, Y. D. Huang, L. Fan, L. N. Zhang, Q. Q. Li, S. S. Fan, K. L. Jiang, “True-color real-time imaging and spectroscopy of carbon nanotubes on substrates using enhanced Rayleigh scattering”, Nano Research, 8, 2721-2732, (2015).

66. W. Y. Wu, J. Y. Yue, D. Q. Li, X. Y. Lin, F. Q. Zhu, X. Yin, J. Zhu, X. C. Dai, P. Liu, Y. Wei,J. P. Wang, H. T. Yang, L. N. Zhang, Q. Q. Li, S. S. Fan, K. L. Jiang, “Interface dipole enhancement effect and enhanced Rayleigh scattering”, Nano Research, 8, 303-319, (2015).

67. P. Liu, D. L. Zhou, Y. Wei, K. L. Jiang,J. P. Wang, L. N. Zhang, Q. Q. Li, S. S. Fan, “Load characteristics of a suspended carbon nanotube film heater and the fabrication of a fast-response thermochromic display prototype”, ACS Nano, 9, 3753-3759, (2015).

68. G. H. Li, Q. Q. Li, Y. H. Jin, Q. K. Qian, Y. D. Zhao, X. Y. Xiao,J. P. Wang, K. L. Jiang, S. S. Fan, “Demonstration of nonvolatile multilevel memory in ambipolar carbon nanotube thin-film transistors”, Appl. Phys. Express, 8, 065101, (2015).

69. G. H. Li, Q. Q. Li, Y. H. Jin, Y. D. Zhao, X. Y. Xiao, K. L. Jiang,J. P. Wang, S. S. Fan, “Fabrication of air-stable n-type carbon nanotube thin-film transistors on flexible substrates using bilayer dielectrics”, Nanoscale, 7, 17693-17701, (2015).

70. H. Ma, Y. Wei, J. T. Wang, X. Y. Lin, W. Y. Wu, Y. Wu, L. Zhang, P. Liu,J. P. Wang, Q. Q. Li, S. S. Fan, K. L. Jiang, “Freestanding macroscopic metal-oxide nanotube films derived from carbon nanotube film templates”, Nano Research, 8, 2024-2032, (2015).

71. L. Sun, M. Y. Li, Y. Jiang, W. B. Kong, K. L. Jiang,J. P. Wang*, and S. S. Fan, “Sulfur nanocrystals confined in carbon nanotube network as a binder-free electrode for high-performance lithium sulfur batteries”, Nano Lett., 14, 4044-4049, (2014).

72. M. Y. Li, Y. Wu, F. Zhao, Y. Wei, J. P. Wang*, K. L. Jiang, and S. S. Fan, “Cycle and rate performance of chemically modified super-aligned carbon nanotube electrodes for lithium ion batteries”, Carbon, 69, 444-451, (2014).

73. S. Luo, H. C. Wu, Y. Wu, K. L. Jiang,J. P. Wang*, and S. S. Fan, “Mn3O4nanoparticles anchored on continuous carbon nanotube network as superior anodes for lithium ion batteries”, J. Power Sources, 249, 463-469, (2014).

74. L. Sun, J. P. Wang*, K. L. Jiang, and S. S. Fan, “Mesoporous Li4Ti5O12 nanoclusters as high performance negative electrodes for lithium ion batteries”, J. Power Sources, 248, 265-272, (2014).

75. Y. Wu, H. C. Wu, S. Luo, K. Wang, F. Zhao, Y. Wei, P. Liu, K. L. Jiang,J. P. Wang*, and S. S. Fan, “Entrapping electrode materials within ultrathin carbon nanotube network for flexible thin film lithium ion batteries”, RSC Advances, 4, 20010-20016, (2014).

76. Y. Wu,J. P. Wang*, K. L. Jiang, and S. S. Fan, “The applications of carbon nanotubes in high performance lithium ion batteries”, Frontiers of Physics, 9, 351-369, (2014).

77. H. Zheng, D. D. Xiao, X. Li, Y. L. Liu, Y. Wu,J. P. Wang, K. L. Jiang, C. Chen, L. Gu, X. L. Wei, Y. S. Hu, Q. Chen, H. Li, “New insight in understanding oxygen reduction and evolution in solid-state lithium oxygen batteries using an in situ environmental scanning electron microscope”, Nano Lett., 14, 4245-4249, (2014).

78. J. T. Wang, T. Y. Li, B. Y. Xia, X. Jin, H. M. Wei, W. Y. Wu, Y. Wei,J. P. Wang, P. Liu, L. N. Zhang, Q. Q. Li, S. S. Fan, K. L. Jiang, “Vapor-condensation-assisted optical microscopy for ultralong carbon nanotubes and other nanostructures”, Nano Lett., 14, 3527-3533, (2014).

79. L. F. Fei, L. Sun, W. Lu, M. Guo, H. T. Huang,J. P. Wang, H. L. W. Chan, S. S. Fan, Y. Wang, “Stable 4 V-class bicontinuous cathodes by hierarchically porous carbon coating on Li3V2(PO4)3nanospheres”, Nanoscale, 6, 12426-12433, (2014).

80. F. Zhu, X. Y. Lin, P. Liu, K. L. Jiang, Y. Wei, Y. Wu,J. P. Wang, S. S. Fan, “Heating graphene to incandescence and the measurement of its work function by the thermionic emission method”, Nano Research, 7, 553-560, (2014).

81. Y. J. He, D. Q. Li, T. Y. Li, X. Y. Lin, J. Zhang, Y. Wei, P. Liu, L. N. Zhang,J. P. Wang, Q. Q. Li, S. S. Fan, K. L. Jiang, “Metal-film-assisted ultra-clean transfer of single-walled carbon nanotubes”, Nano Research, 7, 981-989, (2014).

82. Y. Wu, Y. Wei,J. P. Wang*, K. L. Jiang, and S. S. Fan, “Conformal Fe3O4 sheath on aligned carbon nanotube scaffolds as high performance anodes for lithium ion batteries”, Nano Lett., 13, 818-823, (2013).

83. K. Wang, S. Luo, Y. Wu, X. F. He, F. Zhao,J. P. Wang*, K. L. Jiang, and S. S. Fan, “Super-aligned carbon nanotube films as current collectors for lightweight and flexible lithium ion batteries”, Adv. Funct. Mater., 23, 846-853 (cover picture), (2013).

84. X. F. He, Y. Wu, F. Zhao,J. P. Wang*, K. L. Jiang, and S. S. Fan, “Enhanced rate capabilities of Co3O4/carbon nanotube anodes for lithium ion battery applications”, J. Mater. Chem. A, 1, 11121-11125, (2013).

85. K. Wang, Y. Wu, S. Luo, X. F. He,J. P. Wang*, K. L. Jiang, and S. S. Fan, “Hybrid super-aligned carbon nanotube/carbon black conductive networks: a strategy to improve both electrical conductivity and capacity for lithium ion batteries”, J. Power Sources, 233, 209-215, (2013).

86. X. Y. Lin, P. Liu, Y. Wei, Q. Q. Li,J. P. Wang, Y. Wu, C. Feng, L. N. Zhang, S. S. Fan, and K. L. Jiang, “Development of an ultra-thin film comprised of a graphene membrane and carbon nanotube vein support”, Nat. Commun., 4, 2920, (2013).

87. Y. J. He, J. Zhang, D. Q. Li, J. T. Wang, Q. Wu, Y. Wei, L. N. Zhang,J. P. Wang, P. Liu, Q. Q. Li, S. S. Fan, K. L. Jiang, “Evaluating bandgap distributions of carbon nanotubes via scanning electron microscopy imaging of the schottky barriers”, Nano Lett., 13, 5556-5562, (2013).

88. L. F. Fei, W. Lu, L. Sun,J. P. Wang, J. B. Wei, H. L. W. Chan, and Y. Wang, “Highly entangled carbon nanoflakes on Li3V2(PO4)3microrods for improved lithium storage performance”, RSC Advances, 3, 1297-1301, (2013).

89. S. Luo, K. Wang,J. P. Wang*, K. L. Jiang, Q. Q. Li, S. S. Fan, “Binder-free LiCoO2/carbon nanotube cathodes for high performance lithium ion batteries”, Adv. Mater., 24, 2294-2298, (2012).

90. J. Li, Y. J. He, Y. M. Han, K. Liu,J. P. Wang*, Q. Q. Li, S. S. Fan, K. L. Jiang, “Direct identification of metallic and semiconducting single-walled carbon nanotubes in scanning electron microscopy”, Nano Lett., 12, 4095-4101, (2012).

91. F. Hao, Z. Wang, Q. Luo, J. Lou, J. B. Li,J. P. Wang*, S. S. Fan, K. L. Jiang, and H. Lin, “Highly catalytic cross-stacked superaligned carbon nanotube sheets for iodine-free dye-sensitized solar cells”, J. Mater. Chem., 22, 22756-22762, (2012).

92. R. Xie,J. P. Wang*, Y. Yang, K. L. Jiang, Q. Q. Li, S. S. Fan, “Aligned carbon nanotube coating on polyethylene surface formed by microwave radiation”, Compos. Sci. Technol., 72, 85-90, (2011).

93. L. Z. Chen, C. H. Liu, K. Liu, C. Z. Meng, C. H. Hu,J. P. Wang, and S. S. Fan, “High-performance, low-voltage, and easy-operable bending actuator based on aligned carbon nanotube/polymer composites”, ACS Nano, 5, 1588-1593, (2011).

94. K. L. Jiang,J. P. Wang, Q. Q. Li, L. Liu, C. H. Liu, and S. S. Fan, “Superaligned carbon nanotube arrays, films and yarns: a road to applications”, Adv. Mater., 23, 1154-1161, (2011).

95. K. Liu, Y. H. Sun, X. Y. Lin, R. F. Zhou,J. P. Wang, S. S. Fan, K. L. Jiang, “Scratch-resistant, highly conductive, and high-strength carbon nanotube-based composite yarns”. ACS Nano, 4, 5827-5834, (2010).

96. K. Liu, Y. H. Sun, R. F. Zhou, H. Y. Zhu,J. P. Wang*, L. Liu, S. S. Fan and K. L. Jiang, “Carbon nanotube yarns with high tensile strength made by a twisting and shrinking method”, Nanotechnology, 21, Art. No. 045708, (2010).

97. Q. F. Cheng,J. P. Wang*, J. J. Wen, C. H. Liu, K. L. Jiang, Q. Q. Li, and S. S. Fan, “Carbon nanotube/epoxy composites fabricated by resin transfer molding”, Carbon, 48, p. 260-266, (2010).

98. K. Liu, Y. H. Sun, P. Liu,J. P. Wang*, Q. Q. Li, S. S. Fan, and K. L. Jiang, “Periodically striped films produced from super-aligned carbon nanotube arrays”, Nanotechnology, 20, Art. No. 335705, (2009).

99. L. Z. Chen, C. H. Liu,J. P. Wang, W. Zhang, C. H. Hu, and S. S. Fan, “Auxetic materials with large negative Poisson’s ratios based on highly oriented carbon nanotube structures”, Appl. Phys. Lett., 94, Art. No. 253111, (2009).

100. X. T. Qiu, R. R. Liu, S. M. Guo, J. H. Graeter, L. Kecskes, andJ. P. Wang*, “Combustion synthesis reactions in cold-rolled Ni/Al and Ti/Al multilayers”, Metall. Mater. Trans. A, 40A, 1541-1546, (2009).

101. Q. F. Cheng,J. P. Wang*, K. L. Jiang, Q. Q. Li, and S. S. Fan, “Fabrication and properties of aligned multi-walled carbon nanotubes reinforced epoxy composites”, J. Mater. Res., 23, 2975-2983, (2008).

102. X. Qiu andJ. P. Wang*, “Bonding silicon wafers with reactive multilayer foils”, Sensors and Actuators A, 141, 476-481, (2008).

103. X. Qiu, J. H. Graeter, L. Kecskes,J. P. Wang*, “Exothermic reactions in cold rolled Ni/Al reactive multilayer foils”, J. Mater. Res., 23, 367-375, (2007).

104. H. Nathani,J. P. Wang, and T. P. Weihs, “Long-term stability of nanostructured systems with negative heats of mixing”, J. Appl. Phys., 101, Art. No.104315, (2007).

105. X. Qiu andJ. P. Wang*, “Experimental evidence of two-stage formation of Al3Ni in reactive Ni/Al multilayer foils”, Scripta Mater., 56, 1055-1058, (2007).

106. J. C. Trenkle,J. P. Wang, T. P. Weihs, and T. C. Hufnagel, “Microstructural study of oscillatory combustion in nanostructured reactive multilayer foils”, Appl. Phys. Lett., 87, Art. No.153108, (2005).

107. J. P. Wang*, E. Besnoin, O. M. Knio, and T. P. Weihs, “Effects of physical properties of components on reactive nanolayer joining”, J. Appl. Phys., 97: Art. No.114307, (2005).

108. J. P. Wang*, E. Besnoin, O. M. Knio, and T. P. Weihs, “Investigating the effect of applied pressure on reactive multilayer foil joining”, Acta. Mater., 52, 5265-5274, (2004).

109. A. Duckham, S. J. Spey,J. P. Wang, M. E. Reiss, T. P. Weihs, E. Besnoin, and O. M. Knio, “Reactive nanostructured foil used as a heat source for joining titanium”, J. Appl. Phys., 96, 2336-2342, (2004).

110. J. P. Wang*, E. Besnoin, A. Duckham, S. J. Spey, M. E. Reiss, O. M. Knio, and T. P. Weihs, “Joining of stainless steel specimens with nanostructured Al/Ni foils”, J. Appl. Phys., 95, 248-256, (2004).

111. L. J. Vandeperre,J. P. Wang, and W. J. Clegg, “Effects of porosity on the measured fracture energy of brittle materials”, Phil. Mag., 84, 3689-3704, (2004).

112. J. P. Wang*, E. Besnoin, A. Duckham, S. J. Spey, M. E. Reiss, O. M. Knio, M. Powers, M. Whitener, and T. P. Weihs, “Room temperature soldering with nanostructured foils”, Appl. Phys. Lett., 83, 3987-3989, (2003).

113. J. P. Wang, L. J. Vandeperre, R. J. Stearn, and W. J. Clegg, “The fracture energy of porous ceramics”, Key Engineering Materials, 206-2, 2025-2028, (2002).

114. J. P. Wang, L. J. Vandeperre, R. J. Stearn, and W. J. Clegg, “Pores and cracking in ceramics”, J. Ceramic Processing Research, 2, 27-30, (2001).

115. J. P. Wang, L. J. Vandeperre, W. J. Clegg, C. Engebretsen, and E. Carlstrom, “Fracture behavior of porous alumina ceramics”, Materials Integration, 14, 5-9, (2001).