1. Zhang H.#; Zhao G.#; Wu S.; Alsaid Y.; Zhao W.; Yan X.; Liu L.; Zou G.; Lv J.; He X.*; He Z.*; Wang J.; Solar anti-icing surface with enhanced condensate self-removing at extreme environmental conditions. Proc. Natl. Acad. Sci. 2021 Vol. 118 No. 18 e2100978118
2. Wu Shuwang.; He Zhiyuan.*; Zang Jinger.; Jin Shenglin.; Wang Zuowe.i; Wang Jianping.; Yao Yefeng.; Wang Jianjun.*; Heterogeneous Ice Nucleation Correlates with Bulk-like Interfacial Water, Science Advances, 2019, 5(4): eaat9825.
3. He Zhiyuan.#; Xie Wen Jun.#; Liu Zhenqi.; Liu Guangming.; Wang Zuowei.; Gao Yi Qin.*; Wang Jianjun.*; Tuning Ice Nucleation with Counterions on Polyelectrolyte Brush Surfaces, Science Advances, 2016, 2(6): e1600345.
4. Jin Yuankai; He Zhiyuan.*; Guo Qian.; Wang Jianjun.*; Control of Ice
Propagation by Using Polyelectrolyte Multilayer Coatings , Angewandte Chemie International Edition, 2017, 56(38): 11436-11439.
5. He Zhiyuan; Wu Chenyang; Hua Mutian; Wu Shuwang; Wu Dong; Zhu Xinyuan*;Wang Jianjun*; He Ximin*; Bioinspired Multifunctional Anti-icing Hydrogel, Matter, 2020, 2(3): 723-734.
6. He Zhiyuan#; Liu Pai#; Zhang Shizhong; Yan Jie; Wang Mengni; Cai Zhengxu
*; Wang Jianjun*; Dong Yuping; A Freezing-Induced Turn-on Imaging Modality for Real-time Monitoring of Cancer Cells in Cryosurgery , Angewandte Chemie International Edition, 2019, 58(12): 3834-3837.
7. He Zhiyuan; Liu Kai; Wang Jianjun*; Bioinspired Materials for Controlling Ice Nucleation, Growth, and Recrystallization , Accounts of Chemical Research, 2018, 51(5): 1082-1091
8. Jin Yuankai#; Wu Chenyang#; Yang Yanling; Wu Jiagui; He Zhiyuan*; Wang Jianjun; Inhibiting Condensation Freezing on Patterned Polyelectrolyte Coatings , ACS Nano, 2020, 14(4): 5000-5007.
9. Wang Zhanhui#; Lin Baixue#; Sheng Siyu; Tan Sicong; Wang Pengchao; Tao Yong; Liu Zhang; He Zhiyuan*; Wang Jianjun; Bioinspired Anti-icing Hydrogel Enabled by Ice-nucleating Protein, CCS Chemistry, 2021, 3: 473-480.
10. Wu Chenyang; Geng Hongya; Tan Sicong; Lv Jianyong; Wang Haiqiao*; He Zhiyuan*; Wang Jianjun; Highly Efficient Solar Anti-icing/deicing via A Hierarchical Structured Surface, Materials Horizons, 2020, 7(8): 2097-2104.
11. Hao Tongtong.; Zhu Zhicheng.; Yang Huige.*; He Zhiyuan.*; Wang Jianjun.*;All-day anti-icing/deicing film based on combined photo-electro-thermal conversion[J]. ACS Applied Materials & Interfaces, 2021, 13(37): 44948-44955.
12. Zhao Yusen.; Peng Zihang.; Yao Bowen.; Alsaid Yousif.; Hua Mutian.; Wu Dong.; Qiu Yu.;
Pei Qibing.; Zhu Xinyuan.; He Zhiyuan.*; He Ximin.*;Ultrastretchable Polyaniline-Based Conductive Organogel with High Strain Sensitivity[J]. ACS Materials Letters, 2021, 3(10): 1477-1483.
13. Zhang Shizhong.#; Zhang Chuanbiao.#;Wu Shuwang.#; Zhou Xin ; He Zhiyuan.*;Wang Jianjun .* ;
Ion-Specific Effects on the Growth of Single Ice Crystals[J]. The Journal of Physical Chemistry Letters, 2021, 12(36): 8726-8731.
14. Liu Zhang;Wang Yan;Zheng Xia;Jin Shenglin;Liu Shuo;He Zhiyuan; Xiang Jun-Feng;Wang Jianjun.*;Bioinspired Crowding Inhibits Explosive Ice Growth in Antifreeze Protein Solutions[J]. Biomacromolecules, 2021, 22(6): 2614-2624.
15. Wang Jian.#;Tian Yulan.#;Chen Fangming.;Chen Wei;Du Liping;He Zhiyuan;Wu Chunsheng.*;Zhang De-Wen.*;Scanning Electrochemical Photometric Sensors for Label-Free Single-Cell Imaging and Quantitative Absorption Analysis[J]. Analytical Chemistry, 2020, 92(14): 9739-9744.
16. Wang Zhanhui ; Yang Bin; Chen Zhuo; Liu Dan ;Jing Lihong ; Gao Chong; Li Jian.*; He Zhiyuan.*; WangJianjun; Bioinspired Cryoprotectants of Glucose-Based Carbon Dots[J]. ACS Applied Bio Materials, 2020, 3(6): 3785-3791.
18. Zhao Guanlei .;Zou Guisheng.; Wang Wengan.; Geng Ruikun.; Yan Xiao.; He Zhiyuan.; Liu Lei.*; Zhou Xin.; Lv Jianyong.*; Wang Jianjun.*;
Competing effects between condensation and self-removal of water droplets determine antifrosting performance of superhydrophobic surfaces[J]. ACS applied materials & interfaces, 2020, 12(6): 7805-7814.
19. Zhao Guanlei .; Zou Guisheng. ;Wang Wengan.;Geng Ruikun .;Yan Xiao.; He Zhiyuan.;
Liu Lei.*; Zhou Xin.; Lv Jianyong.* ; Wang Jianjun.*;
Rationally designed surface microstructural features for enhanced droplet jumping and anti-frosting performance[J]. Soft Matter, 2020, 16(18): 4462-4476.
20. Li Linhai.; Fan Qingrui.; Xu Han.; Zhang Shizhong.; Wu Shuwang.; He Zhiyuan.*; Wang Jianjun.*; Recrystallized ice-templated electroless plating for fabricating flexible transparent copper meshes[J]. RSC Advances, 2020, 10(17): 9894-9901.
21. Jin Shenglin; Yin Lingkang.; Kong Bin.; Wu Shuwang.; He Zhiyuan.; Xue Han.; Liu Zhang.; Cheng Qi.; Zhou Xin.*; Wang Jianjun.*; Spreading fully at the ice-water interface is required for high ice recrystallization inhibition activity[J]. Science China Chemistry, 2019, 62(7): 909-915.
22. Wu Shuwang; He Zhiyuan*; Zang Jinger; Jin Shenglin; Wang Zuowei; Wang Jianping; Yao Yefeng; Wang Jianjun*; Heterogeneous Ice Nucleation Correlates with Bulk-like Interfacial Water, Science Advances, 2019, 5(4): eaat9825.
23. Wang Yaling ; Li Zehui;Tang Cheng ;Ren Haixia ; Zhang Qiang ; Xue Mo; Xiong Jin ;Wang Dongbin ; Yu Qian; He Zhiyuan.; Wei Fei ;
Jiang Jingkun *;Few-layered mesoporous graphene for high-performance toluene adsorption and regeneration[J]. Environmental Science: Nano, 2019, 6(10): 3113-3122.
24. Guo Qian ; He Zhiyuan*;Jin Yuankai; Zhang Shizhong; Wu Shuwang ; Bai Guoying; Xue Han ; Liu Zhang ;
Jin Shenglin; Zhao Lishan; Wang Jianjun;
Tuning ice nucleation and propagation with counterions on multilayer hydrogels[J]. Langmuir, 2018, 34(40): 11986-11991.
代表性授权专利
1. 一种水凝胶涂层及其制备方法与应用,中国发明专利,ZL201810327418.1
2. 一种无规超支化聚乙烯的新用途,中国发明专利,ZL201410653511.3
3. 一种聚电解质涂层及其调控冰传递的应用,中国发明专利,ZL201710007090.0
4. 一种表面带电荷的可以调节冷凝水冻结温度的材料及其制备方法与应用,中国发明专利,ZL201510175013.7
5.碳点作为抗冻材料的应用,中国发明专利,ZL202010197719.4
1. D. Wang, D. Han, X.-B. Li, S.-Y. Xie, N.-K. Chen, W. Q. Tian, D. West, H.-B. Sun, and S. Zhang, “Determination of formation and ionization energies of charged defects in two-dimensional materials”, Phys. Rev. Lett. 114, 196801 (2015).
2. D. Wang, X.-B. Li, D. Han, W. Q. Tian, and H.-B. Sun, “Engineering two-dimensional electronics by semiconductor defects”, Nano Today 16, 30 (2017).
3. D. Wang, X.-B. Li, and H.-B. Sun, “Modulation Doping: A Strategy for 2D Materials Electronics”, Nano Letters, 21, 6298 (2021).
4. D. Wang, D. Han, X.-B. Li, N.-K. Chen, D. West, V. Meunier, S. Zhang, and H.-B. Sun, “Charged defects in two-dimensional semiconductors of arbitrary thickness and geometry: formulation and application to few-layer black phosphorus”, Phys. Rev. B 96, 155424 (2017).
5. D. Wang and R. Sundararaman, “Layer dependence of defect charge transition levels in twodimensional materials”, Phys. Rev. B 101, 054103 (2020).
6. D. Wang and R. Sundararaman, “Substrate effects on charged defects in two-dimensional materials”, Phys. Rev. Mater. 3, 083803 (2019).
7. D. Wang, D. Han, D. West, N.-K. Chen, S.-Y. Xie, W. Q. Tian, V. Meunier, S. Zhang, and X.-B. Li, “Excitation to defect-bound band edge states in two-dimensional semiconductors and its effect on carrier transport”, npj Comput. Mater. 5, 8 (2019). 1/4
8. D. Wang, X.-B. Li, and H.-B. Sun, “Native defects and substitutional impurities in two-dimensional monolayer InSe”, Nanoscale 9, 11619 (2017).
9. D. Wang, D. Han, X.-B. Li, S.-Y. Xie, N.-K. Chen, W. Q. Tian, S. Zhang, and H.-B. Sun, “Possible n/ptype conductivity of two-dimensional graphene oxide by boron and nitrogen doping: evaluated via constrained excitation”, Appl. Phys. Lett. 109, 203113 (2016).
10. S. Xia*, D. Wang*, N.-K. Chen, D. Han, X.-B. Li, and H.-B. Sun, “Evaluation of charged defects in two-dimensional semiconductors for nanoelectronics: The WLZ extrapolation method”, Annalen der Physik 532, 1900318 (2020). *Corresponding author and equal contribution 11. M.-Y. Ma, N.-K. Chen, D. Wang*, D. Han, H.-B. Sun, and X.-B. Li*, “Defect physics in 2D monolayer I-VII semiconductor AgI”, Materi. Today Nano, In Revision (2022). *Corresponding author
11. F.-C. Pang, D. Wang, N.-K. Chen, S.-Y. Xie, X. Meng, C.-S. Huo, H. Yang, X.-P. Su, W.-Q. Wang, and H.-L. Tu, “First-principles simulations of local structure contrast for liquid Ge1Sb2Te4, Ge2Sb2Te5, and Ge4Sb1Te5 alloys”, Comput. Mater. Sci. 61, 287 (2012).
12. L. Guo, Y.-L. Zhang, D.-D. Han, H.-B. Jiang, D. Wang, X.-B. Li, H. Xia, J. Feng, Q.-D. Chen, and H.-B. Sun, “Laser-mediated programmable N-doping and simultaneous reduction of graphene oxides”, Adv. Opt. Mater. 2, 120 (2014).
13. S.-Y. Xie, X.-B. Li, W.-Q. Tian, D. Wang, N.-K. Chen, D. Han, and H.-B. Sun, “Slide fastener reduction of graphene-oxide edges by calcium: insight from ab initio molecular dynamics”, Chem. Phys. Chem. 15, 2707 (2014).
14. L. Wang, Z. Wang, H.-Y. Wang, G. Grinblat, Y.-L. Huang, D. Wang, X.-H. Ye, X.-B. Li, Q. Bao, A.-S. Wee, S. A. Maier, Q.-D. Chen, M.-L. Zhong, C.-W. Qiu, and H.-B. Sun, “Slow cooling and efficient extraction of C-exciton hot carriers in MoS2 monolayer”, Nat. Comm. 8, 13906 (2017).
15. X.-Y. Ren, S. Xia, X.-B. Li, N.-K. Chen, X.-P. Wang, D. Wang, Z.-G. Chen, S. Zhang, and H.-B. Sun, “Non-phase-separated 2D B–C–N alloys via molecule-like carbon doping in 2D BN: atomic structures and optoelectronic properties”, Phys. Chem. Chem. Phys. 20, 23106 (2018).
16. Y.-L. Zhang, Y.‐Q. Liu, D.‐D. Han, J.‐N. Ma, D. Wang, X.‐B. Li, and H.‐B. Sun, “Quantum‐Confined‐ Superfluidics‐Enabled Moisture Actuation Based on Unilaterally Structured Graphene Oxide Papers”, Adv. Mater. 31, 1901585 (2019).
17. Z. Wang, G. Yuan, M. Yang, J. Chai, Q. Y. S. Wu, T. Wang, M. Sebek, D. Wang, L. Wang, S. Wang, D. Chi, G. Adamo, C. Soci, H. Sun, K. Huang, and J. Teng, “Exciton-Enabled Meta-Optics in TwoDimensional Transition Metal Dichalcogenides”, Nano Lett. 20, 7964 (2020).
18. N.-K. Chen, J. Bang, X.-B. Li, X.-P. Wang, D. Wang, Q.-D. Chen, H.-B. Sun, and S. Zhang, “Optical subpicosecond nonvolatile switching and electron-phonon coupling in ferroelectric materials”, Phys. Rev. B 102, 184115 (2020).
19. Y.-Y. Yue, Z. Wang, L. Wang, H.-Y. Wang, Y. Chen, D. Wang, Q. Chen, B.-R. Gao, A. T. S. Wee, C. Qiu, and H.-B. Sun, “Many-particle induced band renormalization processes in few- and monolayer MoS2”, Nanotechnology 32 135208 (2020). 2/4
20. D. Han, X.-B Li, D. Wang, N.-K Chen, and X. W. Fan, “Doping in the two-dimensional limit: p/ntype defects in monolayer ZnO”, Phys. Rev. B 105, 024104 (2022).
21. S.-W. Zheng, D. Wang, H.-Y. Wang, H. Wang, X. Chen, L.-Y. Zhao, L. Wang, X.-B. Li, and H.-B. Sun. "Spin-Valley Depolarization in van der Waals Heterostructures", J. Phys. Chem. Lett. 13, 5501 (2022).
22. M.-Y. Ma, D. Han, N.-K. Chen, D. Wang, and X.-B. Li, “Recent Progress in Double-Layer Honeycomb Structure: A New Type of Two-Dimensional Material”, Materials 15, 7715 (2022).
23. B. Hou, D. Wang, B. A. Barker, and D. Y. Qiu*, “Exchange-Driven Intermixing of Bulk and Topological Surface State by Chiral Excitons in Bi2Se3”, Phys. Rev. Lett., In Review (2022).
PATENT
Screening method for encapsulation layer in the strategy of modulation doping of 2D materials and the obtained heterostructure, CN 113436963A (2021).
1.Fushuai Luo, Zheming Chen, Juan Chen, Peng Liu, Yanfen Ding, Shimin Zhang, Chong Gao*, Mingshu Yang*. Nanoparticle layer via UV-induced directional migration of iron-doped titania nanoparticles in polyvinyl butyral films and superior UV-stability. Polymer. 2022, 254, 125107.
2.Chong Gao, Peng Liu, Yanfen Ding, Tao Li, Feng Wang, Juan Chen, Shimin Zhang, Zengxi Li, Mingshu Yang*. Non-contact percolation of unstable graphene networks in poly(styrene-co-acrylonitrile) nanocomposites: electrical and rheological properties. Composites Science and Technology. 2018, 155, 41-49.
3.Chong Gao, Cunzhe He, Yanfen Ding, Juan Chen, Feng Wang, Peng Liu, Mingshu Yang*. The yield stress of model waxy oil after incorporation of organic montmorillonite. Fuel. 2017, 230,570-8.
4.Chong Gao, Shimin Zhang, Feng Wang, Peng Liu, Yanfen Ding, Mingshu Yang*. Conductive composites with segregated structure and ultralow percolation threshold via flocculation-assembled PVDF/graphene core-shell particles. Materials Letters. 2015, 1, 428-31.
5.Chong Gao, Shimin Zhang, Feng Wang, Bin Wen, Chunchun Han, Yanfen Ding, Mingshu Yang, et al. Graphene networks with low percolation threshold in ABS nanocomposites: selective localization, electrical and rheological properties. ACS Applied Materials & Interfaces. 2014, 15, 12252-60.
专利
1.具有隔离结构的氟树脂/石墨烯复合材料及其制备方法与应用。中国发明专利,专利号:ZL201510256234.7。
2.一种表面包覆纳米颗粒的可膨胀石墨阻燃剂及制备方法。中国发明专利,专利号:ZL201711294624.9。
表面接枝抗氧剂分子的功能化纳米二氧化钛及其制备方法。中国发明专利,专利号:ZL201711294623.4。
3.纳米降粘降凝剂稳定乳液及其制备方法和用途。中国发明专利,专利号:ZL201611039541.0。
4.纳米降粘降凝剂稳定乳液及其制备方法和用途。国际发明专利,PCT申请号:PCT/CN2017/111267。
5.表面接枝有紫外线吸收功能基团的功能化纳米二氧化硅及其制备方法。中国发明专利,专利号:ZL201210495444.8。
6.纳米金属氢氧化物无卤阻燃剂及其复合材料的制备方法。中国发明专利,申请号:ZL202010387923.2。