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郭传飞

2018-12-27

Journal Papers

Peer-Reviewed High Impact Papers

  1. Pang Zhu#, Huifeng Du#, Xingyu Hou#, Peng Lu, Liu Wang, Jun Huang, Ningning Bai, Zhigang Wu, Nicholas X. Fang*, Chuan Fei Guo*, Skin-Electrode Iontronic Interface for Mechanosensing. Nat.Commun. 2021, accepted.
  2. Peng Lu, Liu Wang, Pang Zhu, Jun Huang, Yueji Wang, Ningning Bai, Yan Wang, Gang Li, Junlong Yang, Kewei Xie, Jianming Zhang, Bo Yu, Yuan Dai, Chuan Fei Guo*. Iontronic Pressure Sensor with High Sensitivity and Linear Response over A Wide Pressure Range Based on Soft Micropillared Electrodes. Sci. Bull. 2021,66(11), 1091–1100.
  3. Lingyu Zhao#, Liu Wang#, Jidong Shi, Xingyu Hou, Qi Wang, Yuan Zhang, Yan Wang, Ningning Bai, Junlong Yang, Jianming Zhang, Bo Yu, Chuan Fei Guo*. Shape-Programmable Interfacial Solar Evaporator with Salt-Precipitation Monitoring Function. ACS Nano 2021, 15, 5752–5761. 
  4. Yong Qian, Yijie Zhou, Mingjin Lu, Xiaoshuang Guo, Dongjie Yang, Hongming Lou, Xueqing Qiu*Chuan Fei Guo*, Direct Construction of Catechol Lignin for Engineering Long-acting Conductive, Adhesive, and UV-blocking Hydrogel Bioelectronics. Small Methods 2021, 2001311. 
  5. Yan Ding#, Haoqi Tang#, Chaohong Zhang*, Weixuan Li, Gang Li, Yuan Zhang, Chen Xu, Fu Zhao, Qiongyu Guo, Chuan Fei Guo*, X.-D. Xiang*. High-throughput Screening of Self-Healable Polysulfobetaine Hydrogels and Their Applications in Flexible Electronics. Adv. Funct. Mater. 2021, 2100489.
  6. Jue Deng#, Hyunwoo Yuk#, Jingjing Wu, Claudia E. Varela, Xiaoyu Chen, Ellen T. Roche, Chuan Fei Guo*, Xuanhe Zhao*. Electrical Bioadhesive Interface for Bioelectronics, Nat. Mater. 2021, 20(2), 229-236.
  7. Yu Chang, Liu Wang, Ruya Li, Zhichao Zhang, Qi Wang, Junlong Yang, Chuan Fei Guo* and Tingrui Pan*. First Decade of Iontronic Sensing: From Droplet Sensors to Flexible Electronics. Advanced Materials 2020, in press. 
  8. Qiupeng Lin, Junlong Yang, Yi Huang, Linlin Yuan, Yifan Zhang, Minkun Cai, Yunlong Zhou, Shi Guo Chen*, Chuan Fei Guo*. Flexible pressure sensor for fingertip pulse monitoring, Advanced Healthcare Materials 2020, 2001023.
  9. Min Fu, Jianming Zhang, Yuming Jin, Yue Zhao, Siya Huang*,  Chuan Fei Guo*. A Highly Sensitive, Reliable and High-Temperature-Resistant Flexible Pressure Sensor Based on Resilient Ceramic Nanofibers, Adv. Sci. 2020, 2000258. 
  10. Ningning Bai#, Liu Wang#, Qi Wang, Jue Deng, Yan Wang, Peng Lu, Jun Huang, Gang Li, Yuan Zhang, Junlong Yang, Kewei Xie, Xuanhe Zhao, Chuan Fei Guo*. Graded Intrafillable Architecture-based Ionic Pressure Sensor with Ultra-Broad-Range High Sensitivity, Nature Commun. 2020, 11(1), 209.
  11. Junlong Yang, Tianzeng Hong, Jue Deng, Yan Wang, Fan Lei, Jianming Zhang, Bo Yu, Zhigang Wu, Xinzheng Zhang, Chuan Fei Guo*, Stretchable, Transparent and Imperceptible Supercapacitors Based on Au@MnO2 Nanomesh Electrodes.Chem. Commun. 2019, 55, 13737-13740.
  12. Yan Wang, Qihan Liu, Jianming Zhang, Tianzeng Hong, Wenting Sun, Lu Tang, Eric Arnold, Zhigang Suo, Wei Hong, Zhifeng Ren*, Chuan Fei Guo*, Giant Poisson’s effect for wrinkle-free stretchable transparent electrodes, Adv. Mater. 2019, 1902955.
  13. Junlong Yang#, Qingxian Liu#, Zhihao Deng, Fan Lei, Jianming Zhang, Quan Wang, Xinzheng Zhang, Zhigang Wu, Chuan Fei Guo*. Ionic Liquid Activated Wearable Electronics. Mater. Today Phys. 2019, 8, 78-85.
  14. S. Huang, Y. Liu, Y. Zhao, Z. Ren*, C. F. Guo*. Flexible electronics: stretchable electrodes and their future. Adv. Funct. Mater. 2018, 1805924.
  15. Y. Wan, Z. Qiu, J. Huang, J. Yang, Q. Wang, P. Lu, J. Yang, J.g Zhang, S. Huang, Z. Wu, C. F. Guo*, Natural Plant Materials as Dielectric Layer for Highly Sensitive Flexible Electronic Skin. Small, 2018, 14, 801657.
  16. Z. Qiu, Y. Wan, W. Zhou, J. Yang, J. Yang, J. Huang, J. Zhang, Q. Liu, S. Huang, N. Bai, Z. Wu, W. Hong, H. Wang, C. F. Guo*, Ionic Skin with Biomimetic Dielectric Layer Templated from Calathea Zebrine Leaf, Adv. Funct. Mater.  2018, 1802343. 
  17. Yongbiao Wan, Yan Wang, Chuan Fei Guo*. Recent progresses on flexible tactile sensors. Mater. Today Phys. 2017, 1, 61-73.
  18. Y. Liu, J. Zhang, G. Heng, Y. Wang, Q. Liu,  S. Huang, C. F. Guo*,  Z.Ren*, Capillary-Force-Induced Cold Welding in Silver-Nanowire-Based Flexible Transparent Electrodes. Nano Lett. 2017, 17, 1090-1096.
  19.  H. Zhang,  F. Yang,  J. Dong,  L. Du,  C. Wang,  J. Zhang, C. F. Guo*,Q. Liu *, Kaleidoscopic imaging patterns of complex structures fabricated by laser-induced deformation. Nature Commun. 2016, 7, 13743.
  20. C. F. Guo, Y. Chen, L. Tang, F. Wang, Z. Ren. Enhancing scratch-resistance by introducing chemical bonding in highly stretchable and transparent electrodes. Nano Lett. 2016, 16, 594–600. 
  21. C. F. Guo, Q. Liu, G. Wang, Y. Wang, Z. Suo, C. Chu, Z. Ren. Fatigue-free, super-stretchable, transparent, and biocompatible metal electrodes. PNAS 2015, 112, 12332–12337.
  22. C. F. Guo, and Z. Ren. Flexible transparent conductors based on metal nanowire networks. Mater. Today 2015, 18, 143–153.
  23. C. F. Guo, T. Sun, Q. Liu, Z. Suo, Z. Ren. Highly stretchable and transparent nanomesh electrodes made by grain boundary lithography. Nature Commun. 2014, 5, 3121.
  24. C. F. Guo, Tianyi Sun, Feng Cao, Qian Liu, Zhifeng Ren. Metallic nanostructures for light trapping in solar energy harvesting devices. Light Sci. Appl. 2014, 3, e161.
  25. C. F. Guo, Y. Lan, T. Sun, and Z. Ren. Deformation–induced cold-welding for self-healing of super-durable flexible transparent electrodes. Nano Energy 2014, 8, 110
  26. T. Sun#C. F. Guo#, F. Cao, E. Akinoglu,Y. Wang, M. Giersig, Z. Ren, and K. Kempa. A Broadband Solar Absorber with 12 nm Thick Ultrathin a-Si Layer by Using Random Metallic Nanomeshes. Appl. Phys. Lett. 2014, 104, 251119. (Co-1st author)
  27. W. Liu#C. F. Guo#, M. Yao, Y. Lan, H. Zhang, Q. Zhang, S. Chen, C. Opeil, Z. Ren. Surface treatments of Bi2S3 nano network as the strategy for improved thermoelectrics. Nano Energy 2014, 4, 113-122. (Co-1st author)
  28. C. F. Guo, T. Sun, Y. Wang, J. Gao, Q. Liu, Z. Ren. Conductive black silicon surface made by silver nanonetwork assisted etching. Small 2013, 9, 2415–2419.
  29. C. F. Guo, J. Zhang, M. Wang, Y. Tian, Q. Liu. A Strategy to prepare wafer scale bismuth compound superstructures. Small 2013, 9, 2394–2398.
  30. C. F. Guo, J. Zhang, Y. Tian, Q. Liu. A general strategy to superstructured networks and nested self-similar networks of bismuth compounds. ACS Nano 2012, 6, 8746–8752.
  31. C. F. Guo, V. Nayyar, Z. Zhang, Y. Chen, J. Miao,  R. Huang,and Q. Liu. Path-guided wrinkling of nanoscale metal films.  Adv. Mater.  2012, 24, 3010–3014. (Cover). 
  32. C. F. Guo, Y. Tian, S. Cao, J. Zhang, H. Tang, and Q. Liu. Topotactic transformations of superstructures: from thin films to 2D networks to nested 2D networks. J. Am. Chem. Soc. 2011, 133, 8211–8215. (Cover). 
  33. C. F. Guo, J. Zhang, J. Miao, Y. Fan and Q. Liu. MTMO grayscale mask.  Opt. Express 2010, 18, 2621–2631. 
  34. C. F. Guo, Z. Zhang, S. Cao, Q. Liu. Laser direct writing of nanoreliefs in Sn nanofilms.   Opt. Lett. 2009, 34, 2820–2822. 
  35. C. F. Guo, S. Cao, P. Jiang, Y. Fang, J. Zhang, Y. Fan, Y. Wang, W. Xu, Z. Zhao, and Q. Liu. Grayscale photomask fabricated by laser direct writing in metallic nano-films.  Opt. Express 2009, 17, 19981–19987. 

Research

Research Interests

1. High-performance electronic-skins: this field of emphasis focuses on designing electronic-skins with super-high sensitivity, ultrafast response, wide detection range and great linearity. Also, novel sensing models and more sensing dimensionalities are developed simultaneously. The stability of electronic-skins in real usage is one of our research interests.

2. Body-flexible electronics: this field of emphasis covers the epidermal and implantable electronics. Main researches focus on the sticky bioelectronic materials and devices, novel conductive hydrogels, and tissue-electrodes interface sensing technology.

3. Abnormal micro-nanofabrication technologies: this field studies the fabrication of large-scale, low-cost, and high-precision micro/nano-structures through developing special processing methods, like biomimicry, template-free, strain-based, and etc., with expecting of higher processing efficiency and lower cost.

Teaching

2021

MSE5014 Flexible Electronic Materials

Offered in Spring semester for graduate students, credits: 2

2020

MSE001 Fundamentals of Materials Science and Engineering

Offered in Fall semester for undergraduate students, credits: 3

GGC5009 Literature Research and Academic Writing

Offered in Fall semester for graduate students, credits: 2

MSE5014 Flexible Electronic Materials

Offered in Spring semester for graduate students, credits: 2

2019

MSE001 Fundamentals of Materials Science and Engineering

Offered in Fall semester for undergraduate students, credits: 3

GGC5009 Literature Research and Academic Writing

Offered in Fall semester for graduate students, credits: 2

MSE5014 Flexible Electronic Materials

Offered in Spring semester for graduate students, credits: 2

2018

MSE201 Fundamentals of Materials Science and Engineering

Offered in Fall semester for undergraduate students, credits: 3

GGC5009 Literature Research and Academic Writing

Offered in Fall semester for graduate students, credits: 2

MSE5014 Flexible Electronic Materials

Offered in Spring semester for graduate students, credits: 2

2017

MSE201 Fundamentals of Materials Science and Engineering

Offered in Fall semester for undergraduate students, credits: 3

GGC5009 Literature Research and Academic Writing

Offered in Fall semester for graduate students, credits: 2

2016

MSE201 Fundamentals of Materials Science and Engineering

Offered in Fall semester for undergraduate students, credits: 3

GGC5009 Literature Research and Academic Writing

Offered in Fall semester for graduate students, credits: 2