梁培
sex
1
title
其他
department
光学与电子科技学院
college

college2

degree
博士
recruit":0,"firstDiscipline1
光学工程
secondaryDiscipline1
电子科学与技术
firstDiscipline2
电子信息
secondaryDiscipline2

executive

officePhone
**
mobilePhone

emailAddress
plianghust@126.com
businessAddress
赛博南楼207-1
individualResume
Liang Pei（梁培）\rMail (1982 .07 ) Nationality：Wuhan Affiliation：China Jiliang University（中国计量大学）\rEmail：plianghust@126.com Telephone：150 5818 1796\r\rResearch Interesting\t\r?\tResearch on spectral detection technology, instrument and detection system, including SERS and SEF； \r?\tMulti - scale multi - physical field coupling algorithm； \r?\tLow dimensional semiconductor materials material device synthesis and characterization technology, energy collection and conversion materials research;\rEducation &Work Experiences\r2005/09-2009/7 \tPh. D in Solid state electronics and microelectronics (Super advisor: Prof. Jianjun, Jiang), School of Optics and Electronics Information，Huazhong University of Science and Technology, Wuhan, China\r2009/07-2012/07 \tLecturer, College of optical science and Engineering, China Jiliang University \r2010/10-2010/12 \tVisiting scholar, APCTP, Pohang university of technology\r2012/07-Till Now\tAssociate professor, College of optical science and Engineering, China Jiliang University\r2014/09-2014/12 \tVisiting scholar, APCTP, NTU (Nanyang Technological University)\r2017/08-2017/10 \tVisiting scholar, APCTP, NTU (Nanyang Technological University)\rBrief introduction of my research\rIn recent years, we mainly focus on the synthesis of nanomaterials and structures and their applications in energy and SERS detection and SEF detection. In addition, combined with spectroscopy, especially Raman spectroscopy, the surface enhanced Raman spectroscopy and surface enhanced fluorescence technology have been systematically studied in chemical reaction process, trace material detection and identification. His major areas of expertise include first principles calculations and multi-scale and multi-physical field calculations and programming, chemical reaction processes and phase transition processes based on Raman spectroscopy and their kinetic processes. As the first author or corresponding author, he has published more than 60 SCI papers including Advanced Materials, ACS Nano, Advanced Science, JMCA, etc., with a total of 1,800 citations. At the same time, it pays attention to the combination of scientific research and industry. In the field of optics and space lighting and electronic control system, the total fund of enterprise cooperation projects has exceeded 7 million yuan in the past five years, helping enterprises to complete the application for intellectual property rights and high-tech enterprises, and carrying out several cooperation projects of industry and college.\r
researchTopic
1、2021年1月-2021年12月，一种稳力智能现场校准装置，企业委托课题，总经费：120万元，主持；\r2、2021年1月-2021年12月，数据挖掘型网络招聘平台开发代码评估与测试，企业委托课题，总经费：10万元，主持；\r3、2021年1月-2021年12月，微流控纸芯片分析测试仪，企业委托课题，总经费：5万元，主持；\r4、2020年1月-2021年12月，基于机器视觉的塑料包装袋缺陷检测，企业委托课题，总经费：40万元，主持；\r5、2018年1月-2019年12月，一种稳力值智能现场校准装置设计与实现，企业委托课题，总经费：30万元，主持；\r6、2021年1月-2023年12月，高通量农残现场快速检测系统研发，浙江省公益技术研究计划，总经费：10万元，主持；
awards

researchProject
1、2021年1月-2021年12月，一种稳力智能现场校准装置，企业委托课题，总经费：120万元，主持；\r2、2021年1月-2021年12月，数据挖掘型网络招聘平台开发代码评估与测试，企业委托课题，总经费：10万元，主持；\r3、2021年1月-2021年12月，微流控纸芯片分析测试仪，企业委托课题，总经费：5万元，主持；\r4、2020年1月-2021年12月，基于机器视觉的塑料包装袋缺陷检测，企业委托课题，总经费：40万元，主持；\r5、2018年1月-2019年12月，一种稳力值智能现场校准装置设计与实现，企业委托课题，总经费：30万元，主持；\r6、2021年1月-2023年12月，高通量农残现场快速检测系统研发，浙江省公益技术研究计划，总经费：10万元，主持；
publications
[1] D. Zhang, L. Tang, J. Chen, Z. Tang, P. Liang, Y. Huang, M. Cao, M. Zou, D. Ni, J. Chen, Z. Yu, S. Jin, Controllable Self-Assembly of SERS Hotspots in Liquid Environment, Langmuir, (2021).\r[2] W. Li, Z. Liu, H. Yang, Z. Wang, Z. Chen, P. Liang, J. Wang, X. Shen, Doping–Induced Polymorph Transformation to Boost Ultrafast Sodium Storage in Hierarchical CoSe2–Carbon Arrays, Materials Today Energy, (2021).\r[3] J. Xia, D. Wang, P. Liang, D. Zhang, X. Du, D. Ni, Z. Yu, Vibrational (FT-IR, Raman) analysis of tea catechins based on both theoretical calculations and experiments, Biophysical Chemistry, 256 (2020).\r[4] Y. Wang, P. Liang, H. Yang, W. Li, Z. Wang, Z. Liu, J. Wang, X. Shen, Hollow CoP nanoparticles embedded in Two–Dimensional N–doped carbon arrays enabling advanced Li–SeS2 batteries with rapid kinetics, Materials Today Energy, 17 (2020) 100423.\r[5] D. Wang, P. Liang, Y. Dong, H. Shu, L. Wang, Z. Liu, Intrinsic point defects in lead-free organic inorganic hybrid double perovskite (OIHDP) (MA)2KBiCl6, Organic Electronics, 81 (2020).\r[6] D. Wang, P. Liang, Y. Dong, H. Shu, Z. Liu, Electronic and optical properties of layered Ruddlesden Popper hybrid X2(MA)n-1SnnI3n+1 perovskite insight by first principles, Journal of Physics and Chemistry of Solids, (2020).\r[7] Q. Tan, X. Chen, H. Wan, B. Zhang, X. Liu, L. Li, C. Wang, Y. Gan, P. Liang, Y. Wang, J. Zhang, H. Wang, L. Miao, J. Jiang, P.A. van Aken, H. Wang, Metal-organic framework-derived high conductivity Fe3C with porous carbon on graphene as advanced anode materials for aqueous battery-supercapacitor hybrid devices, Journal of Power Sources, 448 (2020).\r[8] T. Shi, Z. Tang, P. Liang, X. Zhang, D. Zhang, Q. Shao, J. Huang, Z. Yu, Y. Xu, H. Chen, ZrO2@Ag@SiO2 Sandwich Structure with High SERS Enhancement Effect and Stability, The Journal of Physical Chemistry C, (2020).\r[9] T. Shi, P. Liang, X. Zhang, D. Zhang, H. Shu, J. Huang, Z. Yu, Y. Xu, Synergistic enhancement effect of MoO3@Ag hybrid nanostructures for boosting selective detection sensitivity, Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 241 (2020).\r[10] P. Liang, J. Ye, D. Zhang, X. Zhang, Z. Yu, B. Lin, Controllable Droplet Breakup in Microfluidic Devices via Hydrostatic Pressure, Chemical Engineering Science, (2020).\r[11] P. Liang, Y. Cao, Q. Dong, D. Wang, D. Zhang, S. Jin, Z. Yu, J. Ye, M. Zou, A balsam pear-shaped CuO SERS substrate with highly chemical enhancement for pesticide residue detection, Microchimica Acta, 187 (2020).\r[12] J. Hu, D. Zhang, H. Zhao, B. Sun, P. Liang, J. Ye, Z. Yu, S. Jin, Intelligent spectral algorithm for pigments visualization, classification and identification based on Raman spectra, Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, (2020).\r[13] X. Du, Z. Zhang, H. Chen, P. Liang, Preparation of CeO2 nanorods-reduced graphene oxide hybrid nanostructure with highly enhanced decolorization performance, Applied Surface Science, 499 (2020) 143939 -143946.\r[14] Y. Dong, X.-q. Du, P. Liang, X.-l. Man, One-pot solvothermal method to fabricate 1D-VS4 nanowires as anode materials for lithium ion batteries, Inorganic Chemistry Communications, 115 (2020).\r[15] 张 德, 陈金磊, 倪德江, 陈玉琼, 梁 培, 余. 志., 表面增强拉曼技术在茶叶农药残留检测中的研究进展, 食品安全质量检测学报, 10 (2019) 4187-4193.\r[16] 王潇悦, 汪柯佳, 张豪哲, 汤莉莎, 梁培, 叶嘉明, 基于纸基微流控芯片的手持式食品添加剂检测仪, 分析仪器, (2019) 129-132.\r[17] 胡嘉祺, 赵汉涛, 叶俊泽, 李楠, 梁培, 基于能耗地图的低功耗小车设计及实现, 电子测量技术, 42 (2019) 10-14.\r[18] Y. Zhou, P. Liang, D. Zhang, L. Tang, Q. Dong, S. Jin, D. Ni, Z. Yu, J. Ye, A facile seed growth method to prepare stable Ag@ZrO2 core-shell SERS substrate with high stability in extreme environments, Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, (2019).\r[19] L. Zhang, P. Liang, X.-l. Man, D. Wang, J. Huang, H.-b. Shu, Z.-g. Liu, L. Wang, Fe, N co-doped graphene as a multi-functional anchor material for lithium-sulfur battery, Journal of Physics and Chemistry of Solids, 126 (2019) 280-286.\r[20] D. Zhang, P. Liang, Z. Yu, J. Xia, D. Ni, D. Wang, Y. Zhou, Y. Cao, J. Chen, J. Chen, S. Jin, Self-assembled “bridge” substance for organochlorine pesticides detection in solution based on Surface Enhanced Raman Scattering, Journal of Hazardous Materials, (2019) 121023.\r[21] D. Zhang, P. Liang, J. Ye, J. Xia, Y. Zhou, J. Huang, D. Ni, L. Tang, S. Jin, Z. Yu, Detection of systemic pesticide residues in tea products at trace level based on SERS and verified by GC–MS, Analytical and Bioanalytical Chemistry, (2019).\r[22] J. Wang, K. Xiao, B. Ouyang, L. Zhang, H. Yang, J. Liu, P. Liang, R.S. Rawat, Z.X. Shen, Simultaneous Immobilization and Conversion of Polysulfides on Co3O4–CoN Heterostructured Mediators Toward High-Performance Lithium–Sulfur Batteries, ACS Applied Energy Materials, (2019).\r[23] P. Liang, Y.-f. Zhou, B.-J. Xu, Y. Xuan, J. Xia, D. Wang, D. Zhang, J.-m. Ye, Z. Yu, S.-z. Jin, SERS-based vibration model and trace detection of drug molecules: Theoretical and experimental aspects, Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 215 (2019) 168-175.\r[24] P. Liang, Y.F. Zhou, Zhang, Y. Chang, Q.M. Dong, J. Huang, B.Q. Rao, B.Y. Chen, Z. Yu, D. Ni, Z.G. Liu, S.Z. Jin, SERS based determination of vanillin and its methyl and ethyl derivatives using flower-like silver nanoparticles on a silicon wafer, Mikrochim Acta, 186 (2019) 302.\r[25] P. Liang, L. Zhang, D. Wang, X. Man, H. Shu, L. Wang, H. Wan, X. Du, H. Wang, First-principles explorations of Li2S@V2CT hybrid structure as cathode material for lithium?sulfur battery, Applied Surface Science, (2019).\r[26] J. Huang, Y.-f. Zhou, J. Xu, P. Liang, Z.-g. Liu, J. Wang, D. Zhang, Q.-m. Dong, W.-m. Shen, S.-l. Zhuang, Unveiling the growth mechanism of SiO2/Ag hybrid nanospheres and using for Surface Enhanced Raman Scattering detection, Applied Surface Science, 463 (2019) 115-120.\r[27] Y. Chang, P. Liang, Q.-m. Dong, D. Zhang, J. Xia, Y. Zhou, Z. Yu, J. Huang, D. Ni, S. Jin, Highly sensitivity and homogeneous SERS platforms based on 3D-GNF/AgNPs hybrid structures, Materials Research Express, (2019).\r[28] Y. Cao, P. Liang, Q. Dong, D. Wang, D. Zhang, L. Tang, L. Wang, S. Jin, D. Ni, Z. Yu, Facile Reduction Method Synthesis of Defective MoO2–x Nanospheres Used for SERS Detection with High Chemical Enhancement, Analytical Chemistry, 91 (2019) 8683-8690.\r[29] 陈超, 杜国红, 曹艳亭, 黄杰, 梁培, 产生LED环形光斑的组合透镜设计与参数优化, 照明工程学报, 29 (2018) 66-71.\r[30] L. Zhang, P. Liang, H.B. Shu, X.L. Man, X.Q. Du, D.L. Chao, Z.G. Liu, Y.P. Sun, H.Z. Wan, H. Wang, Design rules of heteroatom-doped graphene to achieve high performance lithium–sulfur batteries: Both strong anchoring and catalysing based on first principles calculation, Journal of Colloid and Interface Science, 529 (2018) 426-431.\r[31] D. Zhang, P. Liang, Z. Yu, J. Huang, D. Ni, H. Shu, Q.-m. Dong, The effect of solvent environment toward optimization of SERS sensors for pesticides detection from chemical enhancement aspects, Sensors and Actuators B: Chemical, 256 (2018) 721-728.\r[32] C. Yang, P. Liang, L. Tang, Y. Zhou, Y. Cao, Y. Wu, D. Zhang, Q. Dong, J. Huang, P. He, Synergistic effects of semiconductor substrate and noble metal nano-particles on SERS effect both theoretical and experimental aspects, Applied Surface Science, 436 (2018) 367-372.\r[33] J. Wang, H. Yang, Z. Chen, L. Zhang, J. Liu, P. Liang, H. Yang, X. Shen, Z.X. Shen, Double-Shelled Phosphorus and Nitrogen Codoped Carbon Nanospheres as Efficient Polysulfide Mediator for High-Performance Lithium-Sulfur Batteries, Advanced Science, (2018) **.\r[34] X. Man, P. Liang, H. Shu, L. Zhang, D. Wang, D. Chao, Z. Liu, X. Du, H. Wan, H. Wang, Interface Synergistic Effect from Layered Metal Sulfides of MoS2/SnS2 van der Waals Heterojunction with Enhanced Li-Ion Storage Performance, The Journal of Physical Chemistry C, 122 (2018) 24600-24608.\r[35] D. Chao, C.R. Zhu, M. Song, P. Liang, X. Zhang, N.H. Tiep, H. Zhao, J. Wang, R. Wang, H. Zhang, H.J. Fan, A High-Rate and Stable Quasi-Solid-State Zinc-Ion Battery with Novel 2D Layered Zinc Orthovanadate Array, Advanced Materials, (2018) **.\r[36] Y.-j. Ai, P. Liang, Y.-x. Wu, Q.-m. Dong, J.-b. Li, Y. Bai, B.-J. Xu, Z. Yu, D. Ni, Rapid qualitative and quantitative determination of food colorants by both Raman spectra and Surface-enhanced Raman Scattering (SERS), Food Chemistry, 241 (2018) 427-433.\r[37] 陈超, 王耀国, 曹艳亭, 余静, 黄杰, 梁培, 实现LED均匀照明的透镜自由曲面设计的集成程序, 照明工程学报, 28 (2017).\r[38] H. Zheng, D. Ni, Z. Yu, P. Liang, Preparation of SERS-active substrates based on graphene oxide/silver nanocomposites for rapid zdetection of l-Theanine, Food Chemistry, 217 (2017) 511-516.\r[39] L. Zhang, P. Liang, H.-b. Shu, X.-l. Man, F. Li, J. Huang, Q.-m. Dong, D.-l. Chao, Borophene as Efficient Sulfur Hosts for Lithium–Sulfur Batteries: Suppressing Shuttle Effect and Improving Conductivity, The Journal of Physical Chemistry C, (2017).\r[40] Y.-x. Wu, P. Liang, Q.-m. Dong, Y. Bai, Z. Yu, J. Huang, Y. Zhong, Y.-C. Dai, D. Ni, H.-b. Shu, C.U. Pittman Jr, Design of a silver nanoparticle for sensitive surface enhanced Raman spectroscopy detection of carmine dye, Food Chemistry, 237 (2017) 974-980.\r[41] J. Wang, H. Yang, C. Guan, J. Liu, Z. Chen, P. Liang, Z. Shen, Space-confinement and chemisorption co-involved in encapsulation of sulfur for lithium-sulfur batteries with exceptional cycling stability, Journal of Materials Chemistry A, 5 (2017) 24602-24611.\r[42] H.J. Liang Pei, Dong Qian-min， Gong Hua-ping，Dong Yan-yan， Sun Cai-xia Innovative research on the group teaching mode based on the LabVIEW virtual environment, (2017) 234.\r[43] P. Liang, Y. Cao, B. Tai, L. Zhang, H. Shu, F. Li, D. Chao, X. Du, Is borophene a suitable anode material for sodium ion battery?, Journal of Alloys and Compounds, (2017) 152–159.\r[44] J. Huang, P. Liang, J. Xu, Y. Wu, W. Shen, B. Xu, D. Zhang, J. Xia, S. Zhuang, Qualitative and quantitative determination of coumarin using surface-enhanced Raman spectroscopy coupled with intelligent multivariate analysis, RSC Adv., 7 (2017) 49097-49101.\r\r
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