主要研究方向：

    高温高压熔流体物化性质及作用，地球内部挥发分循环及斑岩矿床

简历：

(1) 教育简历：

2009.09-2013.06：               中国地质大学（武汉）        本科

2013.09-2018.06：               中国科学院大学         博士研究生

(2) 工作简历：

2018.07-2021.06：  中国科学院地球化学研究所       博士后

2021.07-至今：     中国科学院地球化学研究所     助理研究员

2024.01-至今：     中国科学院地球化学研究所    项目副研究员

2025.03-至今：      北京高压科学研究中心    访问学者

承担科研项目情况：

1、国家自然科学基金青年项目：俯冲带高导异常和岩浆作用成因启示：高温高压下含有含水矿物的天然榴辉岩脱水熔融前后电导率实验研（42002043），2021.01-2023.12 ，主持

2、中国博士后科学基面上项目：高温高压下泥质岩系列电导率实验研究及地球物理学意义（214474），2018.11-2020.08，主持

3、贵州省自然科学基金面上项目：高温高压下金伯利岩及其熔体的电导率实验研究 (黔科合基 础-ZK[2022]一般 567)，2022.04-2025.03 ，主持

4、基金委原创探索项目-重点项目： 地球深部挥发分循环及其地表效应 (42150104)，2022.01-2026.12 ，参与

5、中国科学院前沿科学重点研究项目：百万大气压金刚石压腔高压设备上矿物电学性质的原位实验测量（QYZDB-SSW-DQC009），2016.08-2020.12，参与

代表论著：

1. Sun, W.Q., Tao, R.B.*, Zhu, J.T., Wang, C., Ishii, T., Li, Y.X., 2024. K- and Na-rich davemaoite inclusion in diamond is not inherited from deeply subducted oceanic crusts. Earth and Planetary Science Letters, 637: 118741.

2. Sun, W.Q., Dai, L.D.*, Hu, H.Y., Wang, M.Q., Hu, Z.M., Jing, C.X., 2022. Experimental research on electrical conductivity of the olivine-ilmenite system at high temperatures and high pressures. Frontiers in Earth Science, 10: 861003.

3. Sun, W.Q., Dai, L.D.*, Hu, H.Y., Wang, M.Q., Hu, Z.M., Jing, C.X., 2021. Influence of saline fluids on the electrical conductivity of olivine aggregates at high temperature and high pressure and its geological implications. Frontiers in Earth Science, 9: 749896.

4. Sun, W.Q., Jiang, J.J., Dai, L.D.*, Hu, H.Y., Wang, M.Q., Yuqing Qi, Li, H.P., 2021. Electrical properties of dry polycrystalline olivine mixed with various chromite contents: Implications for the high conductivity anomalies in subduction zones. Geoscience Frontiers, 12: 101178.

5. Sun, W.Q., Dai, L.D.*, Li, H.P., Hu, H.Y., Jiang, J.J., Wang, M.Q., 2020. Electrical conductivity of clinopyroxene-NaCl-H2O system at high temperatures and   pressures: Implications for high-conductivity  anomalies  in the  deep  crust  and  subduction  zone. Journal of Geophysical Research: Solid Earth, 125: e2019JB019093.

6. Sun, W.Q., Dai, L.D.*, Li, H.P., Hu,H.Y., Liu, C.C., 2019. Effect of temperature, pressure  and chemical composition on the electrical conductivity of granulite and geophysical implications. Journal of   Mineralogical and Petrological sciences, 114: 87-98.

7. Sun, W.Q., Dai, L.D.*, Li, H.P., Hu, H.Y., Jiang, J.J., Liu, C.C., 2019. Effect of temperature, pressure  and  chemical  compositions  on  the  electrical  conductivity  of  schist:  Implications  for electrical structures under the Tibetan Plateau. Materials, 12: 961.

8. Sun, W.Q., Dai, L.D.*, Li, H.P., Hu, H.Y., Jiang, J.J., Liu, C.C., 2019. Experimental study on the electrical properties of carbonaceous slate: a special natural rock with unusually high conductivity at high temperatures and pressures. High Temperatures-High Pressures, 48: 439-454.

9. Sun, W.Q., Dai, L.D.*, Li, H.P., Hu, H.Y., Wu, L., Jiang, J.J., 2017. Electrical conductivity of mudstone (before and after dehydration at high P–T) and a test of high conductivity layers in the crust. American Mineralogist, 102: 2450–2456.

10. Sun, W.Q., Dai, L.D.*, Li, H.P., Hu, H.Y., Jiang, J.J., Hui, K.S., 2017. Effect of dehydration on the electrical conductivity of phyllite at high temperatures and pressures. Mineralogy and Petrology, 111: 853–863.

11.孙文清, 代立东*, 李和平, 胡海英, 蒋建军, 惠科石, 2015. 高温高压下地幔矿物水溶解度的研究现状. 地球物理学进展, 30:2055-2063.