Yuan Huang                                        

The postdoc has left the station. Currently working at Sun Yat-Sen University as an assistant professor and master tutor. Published 18 papers in Energy Storage Materials, Nano energy, Npj flexible electronics, Carbon, Journal of Power Sources, Nanoscale and other journals, 3 invention patents, and H-index of 12.

• Education and work experience：

Sun Yat-sen University                            School of Microelectronics Science and Technology                            Assistant Professor, Master's Tutor

Peking University                                     Electronic Science and Technology                                                     Post-doc

The Chinese University of Hong Kong    Department of Materials Science and Engineering                              Phd

Sun Yat-sen University                            School of Physical Science and Engineering Technology                   Master

Sun Yat-sen University                           School of Physical Science and Engineering Technology                    Bachelor

• The main research direction：

Micro-nano vacuum electronic devices, micro-nano processing integration, flexible wearable electronic devices and system integration, energy storage devices

• Representative papers and works (*corresponding author, # co-first author)：

[1] J. Wang, Y. Huang*, B. Liu, Z. Li, J. Zhang, G. Yang, P. Hiralal, S. Jin, H. Zhou*, Flexible and Anti-Freezing Zinc-ion Batteries Using a Guar-gum/Sodium-alginate/Ethylene-glycol Hydrogel Electrolyte. Energy Storage Materials 2021, 41, 599-605.

[2] B. Liu, Y. Huang*, J. Wang, Z. Li, G. Yang, S. Jin, E. Iranmanesh, P. Hiralal*, H. Zhou*, Highly Conductive Locust Bean Gum Bio-electrolyte for Superior Long-life Quasi-solid-state Zinc-ion Batteries. RSC Advances 2021,11, 24862-24871.

[3] C. Gao, J. Wang, Y. Huang*, Z. Li, J. Zhang, H. Kuang, S. Chen, Z. Nie, S. Huang, W. Li, Y. Li, S. Jin, Y. Pan, T. Long, J. Luo, H. Zhou*, X. Wang*, A High-performance Free-standing Zn Anode for Flexible Zinc-ion Batteries. Nanoscale 2021, 13, 10100-10107.

[4] Y. Huang#, Z. Li#, S. Jin, S. Zhang, H. Wang, P. Hiralal, G. A. J. Amaratunga, H. Zhou*,Carbon Nanohorns/Nanotubes: An Effective Binary Conductive Additive in the Cathode of High Energy-density Zinc-ion Rechargeable Batteries. Carbon 2020, 167, 431-438.

[5] J. Zhang, Y. Huang*, Z. Li, C. Gao, S. Jin, S. Zhang, X. Wang, H. Zhou*, Polyacrylic Acid Assisted Synthesis of Free-standing MnO2/CNTs Cathode for Zinc-ion Batteries. Nanotechnology 2020, 31, 375401.

[6] Z. Li, Y. Huang*, J. Zhang, S. Jin, S. Zhang, H. Zhou*, One-step Synthesis of MnOx/PPy Nanocomposite as a High-performance Cathode for a Rechargeable Zinc-ion Battery and Insight into Its Energy Storage Mechanism. Nanoscale 2020, 12, 4150-4158.

[7] Y. Huang#, J. Zhang#, J. Liu, Z. Li, S. Jin, Z. Li, S. Zhang, H. Zhou*, Flexible and Stable Quasi-solid-state Zinc Ion Battery with Conductive Guar Gum Electrolyte. Materials Today Energy 2019, 14, 100349.

[8] Y. Huang#, J. Liu#, J. Zhang, S. Jin, Y. Jiang, S. Zhang, Z. Li, C. Zhi, G. Du, H. Zhou*, Flexible Quasi-solid-state Zinc Ion Batteries Enabled Highly Conductive Carrageenan Bio-polymer Electrolyte. RSC Advances 2019, 9, 16313-16319.

[9] Y. Huang#, J. Liu#, Q. Huang, Z. Zheng, P. Hiralal, F. Zheng, D. Ozgit, S. Su, S. Chen, P.-H. Tan, S. Zhang, H. Zhou*, Flexible High Energy Density Zinc-ion Batteries Enabled by Binder-free MnO2/reduced Graphene Oxide Electrode. npj Flexible Electronics 2018, 2, 21.

[10] Y. Huang, Z. Xu, J. Mai, T.-K. Lau, X. Lu, Y.-J. Hsu, Y. Chen, A. C. Lee, Y. Hou, Y. S. Meng, Q. Li*, Revisiting the Origin of Cycling Enhanced Capacity of Fe3O4 Based Nanostructured Electrode for Lithium Ion Batteries. Nano Energy 2017, 41, 426-433.

[11] Y. Huang#, H. Liu#, L. Gong, Y. Hou, Q. Li*, A Simple Route to Improve Rate Performance of LiFePO4/Reduced Graphene Oxide Composite Cathode by Adding Mg2+ via Mechanical Mixing. Journal of Power Sources 2017, 347, 29-36.

[12] Y. Huang#, H. Liu#, Y. C. Lu, Y. Hou, Q. Li*, Electrophoretic Lithium Iron Phosphate/Reduced Graphene Oxide Composite for Lithium Ion Battery Cathode Application. Journal of Power Sources 2015, 284, 236-244.

[13] Y. Huang, J. C. She*, W. J. Yang, S. Z. Deng, N. S. Xu, Control-Assembly of Layer-by-Layer Stacking Continuous Graphene Oxide Films and Its Application for Actively-Controlled Field Electron Emission Cathode. Nanoscale 2014, 6, 4250-4257.

[14] Y. Huang, W. L. Wang, J. C. She*, Z. B. Li, S. Z. Deng, Correlation Between Carbon-Oxygen Atomic Ratio and Field Emission Performance of Few-Layer Reduced Graphene Oxide. Carbon 2012, 50, 2657-2665.

[15] D. Lan, W. Wang, L. Shi, Y. Huang, L. Hu, Q. Li*, Phase Pure Sn4P3 Nanotops by Solution-liquid-solid Growth for Anode Application in Sodium Ion Batteries. Journal of Materials Chemistry A 2017, 5, 5791-5796.

[16] N. Zhang, C. Chen, X. Yan, Y. Huang, J. Li, J. Ma*, D. H. L. Ng*, Bacteria-inspired Fabrication of Fe3O4-Carbon/Graphene Foam for Lithium-Ion Battery Anodes. Electrochimica Acta 2016, 223, 39-46.

[17] N. Zhang, X. Yan, Y. Huang, J. Li, J. Ma*, D. H. L. Ng*, Electrostatically Assembled Magnetite Nanoparticles/Graphene Foam as a Binder-Free Anode for Lithium Ion Battery. Langmuir 2017, 33, 8899-8905.

[18] H. Shen, B. Liu, Z. Nie, Z. Li, S. Jin, Y. Huang, H. Zhou, A comparison study of MnO₂ and Mn₂O₃ as zinc-ion battery cathodes: an experimental and computational investigation. RSC Advances 2021,11, 14408-14414

• Mailbox：

huangy723@mail.sysu.edu.cn