赵志芳，女， 云南省香格里拉市人。博士，教授，云南大学博士研究生导师。云南省技术创新人才。现任云南大学地球科学学院副院长，“云南省中老孟缅自然资源遥感监测国际联合实验室”主任，“自然资源部三江成矿作用及资源勘查利用重点实验室”及“云南省三江成矿作用及资源勘查利用重点实验室”副主任，“云南省高校国产高分卫星遥感地质工程研究中心”主任。中国地质学会遥感地质分会理事，国际数学地质协会（IAMG)会员，中国地质学会数据驱动与地学发展专业委员会委员，中国地质学会数学地质与地学信息专业委员会委员。先后主持完成国家基金项目2项、中国地质调查局遥感地质调查项目15项、厅局级等遥感地质项目50余项。获云南省科技进步奖三等奖2次、二等奖1次。第一作者/通讯作者发表Ore Geology Reviews、Remote Sensing等期刊论文70余篇。出版专著5部。

研究领域 : 资源与环境遥感监测、矿化蚀变遥感异常增强提取、边境地区国土资源遥感监测
讲授课程:《资源环境遥感》、《地质环境与矿产资源遥感监测》（研究生课程）
              《遥感地质学》、《遥感地质学实验》（本科生课程）
博士研究生招生：地图学与地理信息系统（遥感地质方向）
硕士研究生招生：环境地质学、第四纪地质学、地图学与地理信息系统（遥感地质方向）、资源与环境（环境地质与灾害地质方向）

教育经历:
2005.09-2008.11，中国地质大学（北京），资源与环境遥感，工学博士
2001.09-2005.01，中国地质大学（北京），地质工程，专业硕士
1988.09-1992.06，南京大学大地海洋科学系，地貌与第四纪地质学，理学学士

工作经历:
2009.10-至今，云南大学地球科学学院地质学系，教学与科研
1992.07-2009.09，云南省地质科学研究所、云南省地质矿产勘查开发局信息中心、云南省地质调查院信息中心、遥感地质应用研究
2006.12-2007.12，加拿大约克大学（York University）地球与空间工程系（Department of Earth and Space and Engineering），博士联合培养
2000.03.-2000.05.，德国联邦地质与自然资源研究院（BGR），遥感地质培训
获奖情况:
[1]2015年，获“云南省技术创新人才”称号；
[2]2015年，指导地理信息系统专业硕士研究生王锋德毕业论文“基于ASTER数据的遥感地质信息提取及综合成矿预测研究”，获“云南省优秀硕士论文”；
[3]2009年，滇西北典型成矿带1:10万遥感地质调查与遥感异常提取，云南省科技进步奖三等奖，排名第一；
[4]2005年，澜沧江流域南段矿产资源遥感预测与评价，云南省科技进步奖三等奖，排名第一；
[5]2004年,云南省矿产资源及其开发利用遥感综合调查，云南省科技进步奖二等奖，排名第六
近五年承担科研项目：
[1]2024.08-2027.07，滇东北-滇中铝土矿遥感找矿勘查关键技术及应用，云南省自然资源厅，主持，在研
[2]2024.04-2025.03，滇东南锰矿找矿遥感技术研发及示范应用,云南省地质勘查基金管理中心，主持，在研
[3]2024.03-2024.12，打非治违监管平台运行维护及重点地区数据推送服务,云南省自然资源厅，主持，在研
[4]2023.01-2025.12,云南省中老孟缅自然资源遥感监测国际联合实验室，云南省科技厅(重点研发计划)，主持，在研
[5]2022.06-2023.06， 2022年度重要区域地质灾害监测评价与综合遥感地质调查，中国自然资源航空物探遥感中心，主持，结题
[6]2020.09-2021.04,滇东南浅成低温热液型矿床成矿规律研究及找矿靶区预测-遥感地质解译，云南省地质矿产勘查开发局第二地质大队，主持，结题
[7]2020.12-2021.12,云南省打非治违技术支持服务,云南省自然资源厅，主持，结题
[8]2019.01-2022.12,风化壳淋积型镍矿矿化特征矿物波谱响应及精细化遥感找矿模型研究,国家自然科学基金委(面上项目），41872251，主持，结题
发明专利：
[1]2024.11.01,一种DS-InSAR技术同质像元选取方法及系统, 专利号：ZL 2023 1 0897024.0，周定义, 赵志芳
[2]2024.10.11,一种相位估计优化方法、装置和设备,专利号：ZL 2024 1 1027800.2,周定义;赵志芳
[3]2024.10.01,一种岩性识别方法、装置、设备及介质,发明专利，专利号：ZL 2024 1 0987520.X，章涛;赵志芳;周家喜;张瑞丝
[4]2024.09.03,一种蚀变矿物遥感定量识别方法、系统及电子设备, 发明专利，专利号：ZL 2023 1 1060147.5，陈琪;赵志芳;张新乐;张庚;代启学;牛磊
[5]2024.06.14, 一种InSAR相位解缠方法、系统、设备及介质, 发明专利，专利号：ZL 2023 1 1318313.7，周定义,赵志芳
[6]2024.06.14,一种高山峡谷地区滑坡敏感性评价方法、系统及设备，发明专利，专利号：ZL 2023 1 0899736.6, 赵志芳，周定义
[7]2024.05.10，一种基于自动生成样本的岩性识别方法、平台及介质，发明专利，专利号：ZL2024 1 0147290.6,赵志芳，章涛，张庚，陈琪 br承担教改及课程建设项目：
[1]2023.09 - 2025.09，遥感助力大理苍山洱海地学实习课程建设，云南省教育厅，主持，在研
[2]2023.01 - 2025.12,西南地区大地学示范性跨校联合实习基地建设,云南大学,主持（袁俊鹏/赵志芳），在研
[3]2023.06，腾冲野外地质实习虚拟仿真实验（省级一流课程），云南省教育厅，主持，结题(认定)
[4]2022.01 - 2024.12, 面向地学多学科交叉融合的遥感课程群教学团队,云南大学，主持，在研
[5]2019.06 - 2021.05，腾冲地质认识虚拟实习，云南大学，主持，结题
[6]2016.06 - 2018.06，面向国际化的大理 - 腾冲地质认识实习课程优化建设研究,云南大学,主持，结题
代表性学术论著：

[1]    Zhang, T., Zhao, Z.*, Dong, P., Tang, B. H., Zhang, G., Feng, L., & Zhang, X.. Rapid lithological mapping using multi-source remote sensing data fusion and automatic sample generation strategy. International Journal of Digital Earth, 2024, 17(1). https://doi.org/10.1080/

17538947.2024.2420824

[2]    Zheng Yu, Zhifang Zhao*, Min Zeng, Dingyi Zhou, Xiaotong Su, and Dingshuai Liu. Monitoring and Analysis of Surface Deformation in the Buzhaoba Open-Pit Mine Based on SBAS-InSAR Technology. Remote Sensing, 2024, 16, 22: 4177. https://doi.org/10.3390/rs16224177

[3]Yao, Y., Zhao, Z.*, , Li, Z. , Lai, Z., Wang, G. , Jiang J.. Source mechanism of the 2023 Ms 5.5 earthquake in Subei, Gansu Province revealed by relocated aftershocks and InSAR: complement to the‘shallow slip deficit’of the eastern boundary of the Altyn Tagh fault. Frontiers in Earth Science, 2024, 12:1447789. https://doi.org/10.3389/feart.2024.1447789

[4]Zhou, D., Zhao, Z.*. Optimal algorithm for distributed scatterer InSAR phase estimation based on cross-correlation complex coherence matrix. International Journal of Applied Earth Observation and Geoinformation, 2024, 134, 104214. https://doi.org/10.1016/j.jag.2024.104214

[5]Tao Zhang, Bo-Hui Tang*, Zhifang Zhao*. Mapping of Land Cover Over Highly Heterogeneous Areas in Yunnan Province With Active and Passive Remotely Sensed Data. IEEE Transactions on Geoscience and Remote Sensing, 2024, 62: 1-16. doi: 10.1109/TGRS.2024.3465590.

[6]Liu Ouyang, Zhifang Zhao* ，Dingyi Zhou，Jingyao Cao，Jingyi Qin，Yifan Cao，Yang He. Study on the Relationship between Groundwater and Land Subsidence in Bangladesh Combining GRACE and InSAR. Remote Sensing, 2024, 16,  3715. https://doi.org/10.3390/rs16193715

[7]Yang Qin , Zhifang Zhao*  , Dingyi Zhou , Kangtai Chang , Qiaomu Mou , Yonglin Yang ，  Yunfei Hu. Landslide Susceptibility Assessment in Yulong County Using Contribution Degree Clustering Method and Stacking Ensemble Coupled Model Based on Certainty Factor. Remote Sensing, 2024,16(19): 3582. https://DOI.org/10.3390/rs16193582

[8]Dingyi Zhou, Zhifang Zhao*. Fast InSAR Phase Unwrapping Method for Complex Mountainous Areas With High Noise and Large Gradient Changes. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing,2024,17,957-968. https://doi.org/10.1109/JSTARS.2024.3417417

[9]Yunfei Hu, Zhifang Zhao* ,Xinle Zhang ,Lunxin Feng ,Yang Qin ,Liu Ouyang, Ziqi Huang .Geological Study Based on Multispectral and Hyperspectral Remote Sensing: A Case Study of the Mahuaping Beryllium–Tungsten Deposit Area in Shangri-La. Sustainability, 2024, https://www.mdpi.com/2071-1050/16/15/6387

[10]Kangtai Chang, Zhifang Zhao*, Dingyi Zhou, Zhuyu Tian, Chang Wang. Prediction of Surface Subsidence in Mining Areas Based on Ascending-Descending Orbits Small Baseline Subset InSAR and Neural Network Optimization Models. Sensors, 2024, https://www.mdpi.com/1424-8220/24/15/4770

[11]Yonglin Yang, Zhifang Zhao*, Dingyi Zhou, Zhibin Lai, Kangtai Chang, Tao Fu, Lei Niu. Identification and Analysis of the Geohazards Located in an Alpine Valley Based on Multi-Source Remote Sensing Data. Sensors, 2024, https://www.mdpi.com/1424-8220/24/13/4057

[12]Geng Zhang, Zhifang Zhao*, Xinle Zhang, Xiatao Wu, Yangfan Zheng, Lunxin Feng, Ziqi Huang. Comprehensive Multi-Source remote sensing data integration for enhanced mineralization alteration extraction and geological structure interpretation in the Lala region of Sichuan Province. Ore Geology Reviews, 2024, https://doi.org/10.1016/j.oregeorev.2024.106032

[13]Dingyi Zhou, Zhifang Zhao*, Wenfei Xi, Xin Zhao, Jiangqin Chao. New method for landslide susceptibility evaluation in alpine valley regions that considers the suitability of InSAR monitoring and introduces deformation rate grading. Geo-Spatial Information Science, 2024, https://doi.org/10.1080/10095020.2023.2270218

[14]Jiangqin Chao, Zhifang Zhao*, Shiguang Xu*,Zhibin Lai, Jianyu Liu ,Fei Zhao,Haiying Yang,Qi Chen. Geothermal target detection integrating multi-source and multi-temporal thermal infrared data. Ore Geology Reviews, 2024, https://doi.org/10.1016/j.oregeorev.2024.105991

[15]Haiying Yang, Zhifang Zhao*, Haifeng Fan , Min Zeng, Jiafei Xiao , Xiqiang Liu, Shengwei Wu, Jiangqin Chao, Yong Xia. Fe-(oxyhydr)oxide participation in REE enrichment in early Cambrian phosphorites from South China: evidence from in-situ geochemical analysis. Journal of Asian Earth Sciences, 2023, https://doi.org/10.1016/j.jseaes.2023.105910

[16] Mingchun Wen, Mengshi Yang, Xin Zhao, Zhifang Zhao*. Post-construction deformation characteristics of high-fill foundations of Kunming Changshui International Airport using time-series  InSAR  technology, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 2023, DOI 10.1109/JSTARS.2023.3328321

[17]Xinle Zhang, Zhifang Zhao*,Qi Chen*,Wang Chai,Ziyang Li, Geng Zhang, Haiying Yang,Lei Niu. Mapping hydrothermal alteration of the Pulang porphyry copper deposit, SW China, using ASTER and ZY1-02D satellite data. Ore Geology Reviews, 2023, 10, 1016. https://doi.org/10.1016/j.oregeorev.2023.105605

[18]Geng Zhang, Qi Chen, Zhifang Zhao *, Xinle Zhang, Jiangqin Chao, Dingyi Zhou , Wang Chai, Haiying Yang , Zhibin Lai, Yangyidan He, Nickel Grade Inversion of Lateritic Nickel Ore Using WorldView-3 Data Incorporating Geospatial Location Information: A Case Study of North Konawe, Indonesia. Remote Sensing, 2023, 15, 3660. https://doi.org/ 10.3390/rs15143660

[19]Fei Zhao, Zhiyan Peng, Jiangkang Qian, Chen Chu, Zhifang Zhao, Jiangqin Chaog, Shiguang Xu. Detection of geothermal potential based on land surface temperature derived from remotely sensed and in-situ data. Geo-Spatial Information Science, 2023, 15, 1271. https://doi.org/10.1080/10095020.2023.2178335

[20] Zhibin Lai, Jiangqin Chao, Zhifang Zhao*, Mingchun Wen, Haiying Yang, Wang Chai, Yuan Yao, Xin Zhao, Qi Chen, Jianyu Liu. Relationship between Crustal Deformation and Thermal Anomalies in the 2022 Ninglang Ms 5.5 Earthquake in China: Clues from InSAR and RST. Remote Sensing, 2023, 15, 1271. https://doi.org/10.3390/rs15051271

[21]Haiying Yang, Zhifang Zhao*, Xiaomin Cao*, Haifeng Fan, Jiafei Xiao, Yong Xia, Min Zeng. Geochemistry of apatite individuals in zhijin phosphorites, South China: Insight into the REY sources and diagenetic enrichment. Ore Geology Reviews, 2022, 105169: https://doi.org/10.1016/j.oregeorev.2022.105169. 

[22]Qi Chen, Jisheng Xia, Zhifang Zhao*, Jiaxi Zhou*, Ruifeng Zhu, Ruisi Zhang, Xin Zhao, Jiangqin Chao, Xinle Zhang, Gen Zhang. Interpretation of hydrothermal alteration and structural framework of the Huize Pb–Zn deposit, SW China, using Sentinel-2, ASTER, and Gaofen-5 satellite data: implications for Pb–Zn exploration. Ore Geology Reviews, 2022, 150, 105154. https://doi.org/10.1016/j.oregeorev.2022.105154.

[23]ZHAO Xin*, LI Guo, ZHAO Zhi-fang*, LI Chun-xiao, CHEN Qi, YE Xian. Identifying the spatiotemporal characteristics of individual red bed landslides: a case study in Western Yunnan, China. J. Mt. Sci, 2022, 19(6): 1748-1766. https://doi.org/10.1007/s11629-022-7339-0

[24]Qi Chen, Zhi-Fang Zhao*, Ji-Sheng Xia*, Xin Zhao, Hai-Ying Yang, Xin-Le Zhang.  Improving the accuracy of hydrothermal alteration mapping based on image fusion of ASTER and Sentinel-2A data: a case study of Pulang Cu deposit, Southwest China, Geocarto International, 2022, https://doi.org/10.1080/10106049.2022.2086625.

[25]柴旺，赵志芳*，刘宇成，赖志滨，晁江琴. 普洱市木乃河工业园区普洱茶康养小镇活动构造评价[J]. 中国矿业，2022，31（S1）：173-178.

[26]柴旺，赵志芳*，段鹏，余璨. 滇东北茂租铅锌矿矿床地质特征及成矿模式[J]. 现代矿业，2022，637（5）：1-5.

[27]赵志芳，张新乐，陈琪，张瑞丝，李文昌，曹晓民.普朗斑岩型铜矿区矿化蚀变特征矿物填图及找矿潜力分析：来自资源一号０２Ｄ遥感卫星的证据[J]，沉积与特提斯地质，2022，42（1）：17-29.

[28]Dingyi Zhou, XiaoqingZuo, Zhifang Zhao^*.Constructing a Large-Scale Urban Land Subsidence Prediction Method Based on Neural Network Algorithm from the Perspective of Multiple Factors. Remote Sensing, 2022, 14, 1803, https://doi.org/10.3390/rs14081803.

[29] Qi Chen, Zhifang Zhao^*, Jiaxi Zhou, Ruifeng Zhu, JishengXia,Tao Sun, XinZhao, Jiangqin Chao. ASTER and GF-5 Satellite Data for Mapping Hydrothermal Alteration Minerals in the Longtoushan Pb-Zn Deposit, SW China. Remote Sensing,  2022, 14: https://doi.org/10.3390/rs14051253.

[30]Haiying Yang, Jiafei Xiao^*, Yong Xia, Zhifang Zhao^*, ZhuojunXie, Shan He,Shengwei Wu. Diagenesis of Ediacaran−early Cambrian phosphorite: comparisons with recent phosphate sediments based on LA-ICP-MS and EMPA. Ore Geology Reviews, 2022, https://doi.org/10.1016/j.oregeorev.2022.104813.

[31] Yuehan Qin, Xinle Zhang, Zhifang Zhao^*, Ziyang Li, Changbi Yang, Qunying Huang. Coupling Relationship Analysis of Gold Content Using Gaofen-5 (GF-5) Satellite Hyperspectral Remote Sensing Data: A Potential Method in Chahuazhai Gold Mining Area, Qiubei County, SW China. Remote Sensing, 2022, 14(1):109, https://doi.org/10.3390/rs14010109.1-20

[32] Haiying Yang，Zhifang Zhao^*, Yong Xia, Jiafei Xiao*.  REY enrichment mechanisms in the early Cambrian phosphorite from South China. Sedimentary Geology, 2021, 426, 1-27. https://doi.org/10.1016/j.sedgeo.2021.106041.

[33]Qi Chen, ZhifangZhao^*,Jiaxi Zhou, Min Zeng, Jisheng Xia, Tao Sun, Xin Zhao. New Insights into the Pulang Porphyry Copper Deposit in Southwest China:Indication of Alteration Minerals Detected Using ASTER and WorldView‐3 Data. Remote Sensing, 2021, 13:2798,1-20

[34]陈琪，赵志芳^*，姜琦刚，夏既胜，孙涛，曾诗卉. 基于ASTER与Sentinel-2A融合数据的云南普朗铜矿化蚀变信息提取[J]，地质与勘探，2021，57（4）：728-738.

[35]Zhi-Fang Zhao, Jia-Xi Zhou^*, Ying-Xiang Lu*, Qi Chen, Xiao-Min Cao, Xiao-Hu He, Xue-Hao Fu, Shi-HuiZeng, Wen-JieFeng. Mapping alteration minerals in the Pulang porphyry copper ore district, SW China, using ASTER and WorldView-3 data: Implications for exploration targeting. Ore Geology Reviews, 2021. 134,104171

[36]李益敏，刘心知，吴博闻，王东驰，袁静，赵志芳^*，基于遥感技术的不透水面动态变化研究：以瑞丽市为例[J]，云南大学学报（自然科学版）,2021,43（4）:716-724. DOI:10.7540/j.ynu.20200380

[37]Zhifang Zhao,Wenchun Wu^*,Jisheng Xia,Xuehao Fu,Yixun Fu,Shucheng Tan,Yimin Li. A safety assessment for the Guanlei Port-Qinsheng Port water corridors on the Lancang-Mekong River. International Journal of Remote Sensing, 2021, 42:6,2269-2279

[38]陈琪，赵志芳^*，曾诗卉，付学浩，冯文杰，普朗铜矿矿化遥感蚀变的成矿构造指示研究[J]，云南地质，2020（28）：30-37

[39]李益敏，袁静，赵志芳^*，基于GIS的中缅边境地区突发事件防控研究[J]，云南地理环境研究，2020(32):1-7

[40]Qi Chen, Zhifang Zhao^*, Qigang Jiang*, Jia-XiZhou,Yinggui Tian,Shihui Zeng, JialingWang. Detecting subtle alteration information from ASTER data using a multifractal-based method: A case study from Wuliang Mountain, SW China. Ore Geology Reviews, 2019, 115(103128):1-12

[41]Ji-ShenXia, Pinliang Dong, Zhi-Fang Zhao^*.Selecting inter-city transportation routes in complex terrains using quantitative methods: A case study from Northern Yunnan, China. Promet-Traffic & Transportation, 2020, 31: 456–469

[42]Junxu Chen*, Yan Lyu, Zhifang Zhao^*, Hong Liu, Hongling Zhao, Zichen Li. Using the multidimensional synthesis methods with non-parameter test, multiple time scales analysis to assess water quality trend and its characteristics over the past 25 years in the Fuxian Lake. China. Science of the Total Environment, 2019, 655: 242-254

参加会议情况：

[1]2024.11.19, 中国地质调查局昆明自然资源调查中心学术交流会，参加，报告：基于地面-星载多光谱-高光谱-重磁遥感找矿方法研究：云南及邻区遥感找矿应用

[2]Oct. 28-Nov. 03, 2024，Cooperation between Yunnnan Universtiy, China and University of Magway, Kyaukse University, Myanmar，Kunming，Presentation：Research Progress on Remote Sensing Prospecting in Southeast Asia of the Belt and Road Initiative

[3]2024.11.01-03，第十届全国应用地球化学学术会议，昆明，参加，报告：从遥感的视角看应用地球化学：地球化学遥感多光谱-高光谱反演初探

[4]2024.10.25-27，2024（第一届）全国有色金属地质大会，昆明，参加，报告：基于地面-星载多光谱-高光谱-重磁遥感的滇东南锰矿找矿方法研究 

[5]2024.09.19-22，第十七届全国矿床会议，贵阳，参加，报告：基于多光谱-高光谱的滇东南锰矿遥感找矿方法研究

[6]2024.09.06-09，第二届数据驱动与地学发展全国学术研讨会会议，北京，参加，“一带一路”东南亚境外勘查遥感应用研究进展

[7]2024.08.20-24，第二十届全国数学地质与地学信息会议，长春，参加

[8]2024.07.16-19，第十三届ics2024光谱网络会议，参加，多光谱-高光谱波谱响应及找矿预测：滇东南丘北地区低温热液型金矿矿化异常应用

[9]2024.04.26-28，第八届人工智能与大数据地球科学学术研讨会暨第二届空间地球大数据高峰论坛，成都，参加，报告：国产高光谱在金矿化异常识别中的应用：技术挑战与前景

[10]2024.01.20，中国地质调查局昆明自然资源综合调查中心转制改革五周年科技成果报告会暨第二届云岭论坛，昆明，参加，报告：多光谱-高光谱遥感蚀变岩石-矿物-元素反演研究及找矿勘查应用

[11]2023.12.24，自然资源绿色发展与生态文明建设遥感技术应用专题研讨会（腾讯会议），参加，学术报告：云南遥感找矿应用

[12]2023.12.17，第十届全国成矿理论与找矿方法学术讨论会，西安，参加，学术报告：滇东北磷矿遥感多元信息找矿勘查方法初探

[13]2023.12.08-10，2023新时代高校地球科学教学改革与创新研讨会，合肥，参加，报告：腾冲火山喷发探究式虚拟仿真实验建设

[14]2023.11.15-17，高等学校地球科学虚拟仿真、人工智能和大数据与拔尖人才培养研讨会，北京，参加，报告：腾冲火山喷发探究式虚拟仿真实验

[15]2023.09.20，中国地质学会2023年学术年会,海南琼海（博鳌论坛），参加，学术报告:基于多光谱-高光谱遥感的前期勘查指示意义分析：以香格里拉麻花坪铍钨矿区为例

[16]2023.07.21,云南省有色地质局技术培训，昆明，培训内容：遥感新技术实践与应用

[17]2023.04.20-21，云南新一轮找矿行动及深部找矿技术研讨会,昆明，参加，学术报告:基于多光谱-高光谱遥感的前期勘查指示意义分析：以香格里拉麻花坪铍钨矿区为例

[18]2023.04.14-17，中国地质学会数据驱动与地学发展专业委员会成立大会暨全国学术研讨会，珠海，参加，学术报告:基于遥感大数据的滇东南低温热液金多金属矿智能找矿探讨

[19]2023.04.07-09，第十九届全国数学地质与地学信息会议，昆明，承办，学术报告:普朗斑岩型铜矿区矿化蚀变特征矿物填图及找矿潜力分 析：来自资源一号 02D 遥感卫星的证据；教学研讨报告：云南腾冲火山地质野外教学资源及虚拟仿真课程建设

[20]2023.03.31-04.03，第十六届全国矿床会议，太原，参加，学术报告:基于国产高光谱等的滇东南浅成低温热液型金矿找矿勘查研究

[21]2023.03.26-30，中国遥感应用协会“遥感技术创新应用”高端论坛暨专家委员会常务会议，昆明，参加，学术报告:基于WorldView-3数据的红土型镍矿矿化蚀变及其富集信息反演研究-以印度尼西亚风化壳型镍矿为例

[22]2023.02.10-11，新疆地质矿产勘查开发局第八地质大队，昆明，参加，学术报告：遥感地质调查工作流程及方法、滇东南低温热液型金矿遥感勘查应用实例

[23]2022.12.10，中国地质学会2022年全国遥感地质学术年会，腾讯会议，学术报告：基于多光谱-高光谱的蚀变岩石-矿物-元素反演研究

[24]2022.01.29，热红外遥感及找矿技术研讨会，腾讯会议，参加，学术报告：基于多/高光谱的蚀变矿物-地球化学元素矿化弱异常波谱机理及增强提取研究

[25]2021.11.12-16，中国科学院人事局主办、中国科学院水利部成都山地灾害与环境研究所承办“重大山地灾害防治技术及预警全国高级研修班”课程学习，获结业证书。

[26]2021.01.29,Thirty Fourth Paper Reading Session, Myanmar Geosciences Society, Department of Geology（缅甸第三十四届地球科学网络学术交流会），参加

[27]2020.11.24-27，第十五届全国矿床会议暨2020矿业全产业链大会，杭州，参加，学术报告：基于ASTER和Sentinel-2A融合数据的矿化遥感蚀变信息提取—以普朗斑岩型铜矿区为例

[28]2020.02.18, Session of Department of Geography and the Environment, University of North Texas, USA, Presentation: Mapping alteration minerals associated with the Pulang porphyry copper ore district, SW China, using ASTER and WorldView-3 data with "PCA+S-A"  method: Implications for exploration targeting

[29]2019.11.29-12.01，2019年新时代全国高校地球科学教学改革与创新研讨会，昆明，组织

[30]2019.12.13-16，第九届全国成矿理论与找矿方法学术研讨会,南京, 参加，学术报告：风化壳淋积型稀土矿产遥感找矿模型—以滇西南某稀土矿为例

[31]2019.05.27-06.03, Organizing the academic exchange between the Department of Geology, Yunnan University, China and the Department of Geology, University of Mandalay, Myanmar.  Mandalay, Myanmar. Presentation: Statistical Analysis of Field Spectra and Contents of Alteration Minerals in Pulang Porphyry Copper Mineralization Belt

[32]2019.05.10-11, International Conference on Silk-road Disaster Risk Reduction and Sustainable Development,Beijing, China. Presentation: Research on Deformation Monitoring of Landslide Induced by Dumping Place in Mining Area Using D-InSAR