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HUANG Shaopeng

Professor

shaopeng#szu.edu.cn

Tingshi Lab (听石实验室) Huiwen Building (汇文楼)Yuehai Campus of the SZU

Research Interests

Geothermal Physics. Geothermal Energy, Global Climate Change, Lunar and Deep Space Exploration


Education

1986.09-1990.04,Ph.D,CAS Institute of Geology, Tectonics

1983.08-1986.07,Master,CAS Institute of Geology, Tectonics

1978.09-1982.07,Bachelor,Chengdu College of Geology, Radio-geophysical Exploration


Working Experience

2024.08-present,Professor, Institute of Advance Study, Shenzhen University

2018.09-2024.10,Professor, College of Civil and Transportation

2010.02-2019.04,Professor, College of School of Human Settlements and Civil Engineering,Xian Jiaotong University

2008.01-2009.08,Professor,Institute of Urban Environment, Chinese Academy of Sciences

2007.04-2007.07,Visiting Professor, Research Institute for Humanity and Nature, Kyoto, Japan

1992.10-2018.08,Postdoc (1992-1996), Research Scientist (1996-2018), Department of Earth and Environmental Sciences, University of Michigan

1986.07-1995.09,Assistant (1986-1990), Associate Research Professor (1992-1995), Institute of Geology, Chinese Academy of Sciences

1982.07-1983.08,Engineer, Team 321 of the Fujian Geological Bureau, Longyan, China


Research Grants

Constructionofthree lunar exploration laboratories, Shenzhen Municipal Foundation, Grant2106-440300-04-03-901272,46,650k RMB,2022.07-2025.06,Co-PI.

Study on the lithospheric thermal structure, the formation mechanism of geothermal systems, and the assessment of geothermal resource of the Guangdong-Hong Kong-Macao Greater Bay Area, National Natural Science Foundationof China,GrantU20A2096,3,110k RMB,2021.01-2025.12,PI.

Feasibility study of the Shenzhen University demonstration project on the geothermal utilization, Shenzhen Natural Science Foundation, Grant20200827003238001,300k RMB,2021.1-2022.12,PI.

Moon-based observation on the energy balance of Earth system,National Natural Science Foundationof China,Grant41590855,3,005k RMB, 2016.01-2020.12, PI.

Geothermal resource and the Cenozoic magmatism of the volcanic areas in Inner Mongolia,National Natural Science Foundationof China,Grant41374089,800k RMB,2014.01-2017.12,PI.


Academic Services

Vice Chair (2011-2015), Chair (2015-2019), and Ex-Chair (2019-2023), International Heat Flow Commission (IHFC), International Association of Seismology and Physics of the Earth's Interior (IASPEI)


Publications

[1] Z. Wei, S. Huang, J. Xu, C. Yuan, M. Zhang, C. Wang, Geochemical evolution of geothermal waters in the Pearl River Delta region, South China: Insights from water chemistry and isotope geochemistry, Journal of Hydrology: Regional Studies 51 (2024) 101670.

[2] Z. Wei, S. Huang, C. Wang, Geochemistry and sources of boron and strontium of geothermal waters from the Pearl River Delta region, South China: Implications for water-rock interactions, Journal of Geochemical Exploration 262 (2024) 107492.

[3] X. Li, S. Huang, T. Hergert, A. Henk, Q. Du, Contemporary crustal kinematics in the Guangdong-Hong Kong-Macao Greater Bay Area, SE China: Implications for the geothermal resource exploration, Journal of Asian Earth Sciences 263 (2024) 106041.

[4]张敏,魏正安,黄少鹏,王帅,何沛欣,覃夏南,唐灵,广东龙门地区岩溶热储特征及地热系统成因,深圳大学学报理工版41(1) (2024).

[5]唐科,黄少鹏,魏正安,张敏,赵欣楠,刘远周,广东惠州地区钻孔岩芯热导率测试与分析,深圳大学学报理工版41(1) (2024).

[6] M. Song, Y. Zhong, C. Ding, Y. Liu, S. Huang, Q. Li, Regolith mineral detection and abundance estimation based on the LMS spectral data of Chang'E-5 lander, Scientia Sinica Physica, Mechanica & Astronomica 53(3) (2023) 239607.

[7] Z. Meng, X. Dong, J. Lei, J. Ping, Z. Cai, X. Zhang, S. Huang, Y. Zhang, Constructing A Complete Brightness Temperature Dataset of the Moon with Chang’e-2 Microwave Radiometer Data, IEEE Transactions on Geoscience and Remote Sensing (2023).

[8] Y. Liu, T. Wang, Y. Jia, M. Song, C. Ding, S. Huang, Thermal environment of the Chang'E-5 landing site and its effect on the external temperature of the lander, Scientia Sinica Physica, Mechanica & Astronomica 53(3) (2023) 239608.

[9] Y. Liu, S. Huang, In-situ measurements of thermal environment on the Moon's surface revealed by the Chang'E-4 and Chang'E-5 missions, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing (2023).

[10] C. Ding, Q. Li, J. Xu, Z. Lei, J. Li, Y. Su, S. Huang, Moon-Based Ground Penetrating Radar Derivation of the Helium-3 Reservoir in the Regolith at the Chang'E-3 Landing Site, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing 16 (2023) 2764-2776.

[11]徐讲湾,黄少鹏,魏正安,李勇义,粤港澳大湾区地热异常空间分布特征的GIS分析,深圳大学学报理工版40(5) (2023).

[12]魏正安,黄少鹏,王成善,张敏,粤港澳大湾区地下热水地球化学特征 及其热储含义, Acta Geoscientica Sinica 44(1) (2023).

[13]汪浩,黄少鹏,冀中坳陷雄县地热开采区地热资源的成因机制,科学技术与工程23(17) (2023) 7203-7211.

[14] W. Zhu, S. Liu, S. Huang, Heat Flow in the Asian Continent and Surrounding Areas, International Journal of Terrestrial Heat Flow and Applied Geothermics 5(1) (2022) 01-08.

[15] J. Lei, Z. Meng, Y. Wang, S. Huang, J. Ping, Z. Cai, Y. Zhang, Potential applications of CE-2 microwave radiometer data in understanding basaltic volcanism in heavily ejecta-contaminated Mare Frigoris, Remote Sensing 14(11) (2022) 2725.

[16] T. Ke, S. Huang, W. Xu, X. Tang, X. Li, Evaluation of the multi-doublet performance in sandstone reservoirs using thermal-hydraulic modeling and economic analysis, Geothermics 98 (2022) 102273.

[17] Y. FAN, H. LI, J. ZHANG, Q. WANG, T. REN, M. ZHANG, S. HUANG, X. QIN, Research on the in-situ stress state and the geothermal-controlling structure of the Huangshadong Geothermal Field in the Southeast Coast of China, Chinese Journal of Geophysics 65(10) (2022) 3944-3961.

[18] C. Ding, S. Xiong, J. Li, Y. Su, S. Huang, Yutu-2 radar observation of the lunar regolith heterogeneity at the Chang’E-4 landing site, Astronomy & Astrophysics 664 (2022) A43.

[19] C. Ding, Y. Su, Z. Lei, Z. Zhang, M. Song, Y. Liu, R. Wang, Q. Li, C. Li, S. Huang, Electromagnetic signal attenuation characteristics in the lunar regolith observed by the lunar regolith penetrating radar (LRPR) onboard the Chang’e-5 lander, Remote Sensing 14(20) (2022) 5189.

[20]孟治国,常文清,沈朝,平劲松,黄少鹏,蔡占川,张渊智,史密斯海月球长期科研站选址与潜在科学目标分析,深空探测学报(中英文) 9(5) (2022) 521-531.

[21]范艳霞,李海龙,张军龙,王强茂,任天翔,张敏,黄少鹏,秦向辉,东南沿海黄沙洞地热田地应力与控热构造研究,地球物理学报65(10) (2022) 3944-3961.

[22] W. Xu, S. Huang, J. Zhang, Y. Zuo, Y. Zhou, T. Ke, R. Yu, Y. Li, Geothermal gradient and heat flow of the Erlian Basin and adjacent areas, Northern China: Geodynamic implication, Geothermics 92 (2021) 102049.

[23] T. Ke, S. Huang, W. Xu, X. Li, Study on heat extraction performance of multiple-doublet system in Hot Sedimentary Aquifers: Case study from the Xianyang geothermal field, Northwest China, Geothermics 94 (2021) 102131.

[24]丁春雨,刘凯军,黄少鹏,苏彦,李佳威,微波雷达在嫦娥探月工程中的应用,地质学报95(9) (2021) 2805-2822.

[25] J. Zhang, S. Huang, Y. Zuo, Y. Zhou, Z. Liu, W. Duan, X. Wei, Terrestrial heat flow in the baiyinchagan sag, erlian Basin, northern China, Geothermics 86 (2020) 101799.

[26]余如洋,黄少鹏,张炯,许威,柯婷婷,左银辉,周勇水,二连盆地白音查干凹陷和乌里雅斯太凹陷岩石热导率测试与分析,岩石学报36(2) (2020) 621-634.

[27] L. Zhi, H. Shaopeng, J. Zhangdong, Sequential relationship between atmospheric CO 2 concentration and surface air temperature on orbital and millennial scales, Quaternary Sciences 39(5) (2019) 1276-1288.

[28] W. Xu, S. Huang, J. Zhang, R. Yu, Y. Zuo, Y. Zhou, J. Chang, Exploitation, Present-day geothermal regime of the uliastai depression, Erlian Basin, North China, Energy Exploration 37(2) (2019) 770-786.

[29] X. Tang, Y. Zuo, B. Kohn, Y. Li, S. Huang, Cenozoic thermal history reconstruction of the Dongpu Sag, Bohai Bay Basin: Insights from apatite fission‐track thermochronology, Terra Nova 31(3) (2019) 159-168.

[30] W. Duan, S. Huang, C. Nie, Entrance pupil irradiance estimating model for a moon-based Earth radiation observatory instrument, Remote Sensing 11(5) (2019) 583.

[31]张育平,黄少鹏,杨甫,王兴,余如洋,李毅,荀迎九,周聪,关中盆地西安凹陷深层地热U型对接井地温特征,中国煤炭地质6 (2019).

[32]彭友兵,程海,陈凯,黄少鹏,过去千年中国东部持续性严重干旱事件的模拟研究,第四纪研究39(2) (2019) 282-293.

[33]刘植,黄少鹏,金章东,轨道及千年尺度上大气CO 2浓度与温度变化的时序关系,第四纪研究39(5) (2019) 1276-1288.

[34]柯婷婷,黄少鹏,许威,余如洋,张炯,唐晓音,关中盆地沣西地区地热对井采灌开发模式的数值模拟,第四纪研究39(5) (2019) 1252-1263.

[35] X. TANG, S. HUANG, G. ZHANG, S. YANG, S. HU, Lithospheric thermal structure of the Pearl River Mouth Basin, northern South China Sea, Chinese Journal of Geophysics 61(9) (2018) 3749-3759.

[36] X. Tang, S. Huang, S. Yang, G. Jiang, M. Ji, S. Hu, Tectono-thermal evolution of the liwan sag, deepwater area in the Zhujiang River Mouth basin, northern South China sea, Acta Oceanologica Sinica 37(2) (2018) 66-75.

[37] Z. Liu, S. Huang, Z. Jin, Breakpoint lead-lag analysis of the last deglacial climate change and atmospheric CO2 concentration on global and hemispheric scales, Quaternary International 490 (2018) 50-59.

[38] Z. Liu, S. Huang, Z. Jin, A last deglacial climate dataset comprising ice core data, marine data, and stalagmite data, Data in brief 21 (2018) 1764-1770.

[39] S. Huang, Apollo 15 Lunar Surface Temperature Series-Inadvertent First Long-Term Record of Earth Climate System Energy Budget, AGU Fall Meeting Abstracts, 2018, pp. P23E-3496.

[40] W. Duan, S. Huang, C. Nie, Conceptual design of a Moon-based Earth radiation observatory, International Journal of Remote Sensing 39(18) (2018) 5834-5849.

[41] V. Cermak, S. Huang, D. Ravat, M. Verdoya, Heat Flow: Recent Advances, International Journal of Earth Sciences 107(1) (2018) 1-3.

[42]余如洋,柯婷婷,许威,李毅,李小军,汪浩,黄少鹏,雄安新区地热井温度测量与分析, 2018年中国地球科学联合学术年会论文集 (2018).

[43]唐晓音,黄少鹏,张功成,杨树春,胡圣标,南海北部陆缘珠江口盆地岩石圈热结构,地球物理学报61(9) (2018) 3749-3759.

[44]唐晓音,黄少鹏,杨树春,姜光政,纪沫,胡圣标,南海北部珠江口盆地深水区荔湾凹陷构造-热演化,海洋学报37(2) (2018) 66-75.

[45]柯婷婷,余如洋,许威,唐晓音,黄少鹏,西安交通大学西咸校区中深层地热资源潜力评估, 2018年中国地球科学联合学术年会论文集 (2018).

[46] X. Tang, S. Yang, J. Zhu, Z. Long, G. Jiang, S. Huang, S. Hu, Tectonic subsidence of the Zhu 1 Sub-basin in the Pearl River Mouth Basin, northern South China Sea, Frontiers of earth science 11(4) (2017) 729-739.

[47] Y. Song, X. Wang, S. Bi, J. Wu, S. Huang, Effects of solar radiation, terrestrial radiation and lunar interior heat flow on surface temperature at the nearside of the Moon: Based on numerical calculation and data analysis, Advances in Space Research 60(5) (2017) 938-947.

[48] Z. Liu, X. Liu, S. Huang, Cyclostratigraphic analysis of magnetic records for orbital chronology of the Lower Cretaceous Xiagou Formation in Linze, northwestern China, Palaeogeography, Palaeoclimatology, Palaeoecology 481 (2017) 44-56.

[49]张炯,黄少鹏,傅饶,唐晓音,大地电磁测深在火山区地热研究中的应用,岩石学报33(1) (2017) 279-290.

[50]杨梅华,左银辉,黄少鹏,张炯,傅饶,周勇水,常俊合,乌里雅斯太凹陷现今地温场研究,中国地球科学联合学术年会论文集 (2017).

[51]段文涛,黄少鹏,唐晓音,张炯,利用ANSYS WORKBENCH模拟火山岩浆活动热扩散过程,岩石学报33(1) (2017) 267-278.

[52] X.-Y. TANG, S.-P. HUANG, S.-C. YANG, G.-Z. JIANG, S.-B. HU, Correcting on logging-derived temperatures of the Pearl River Mouth Basin and characteristics of its present temperature field, Chinese Journal of Geophysics 59(8) (2016) 2911-2921.

[53] S. Huang, J. Liao, J. Guang, J. Wu, S. Bi, X. Tang, J. Kuang, Towards Moon-based monitoring of energy budget of the earth climate system, 2016 IEEE International Geoscience and Remote Sensing Symposium (IGARSS), IEEE, 2016, pp. 3726-3729.

[54] H. Guo, G. Liu, Y. Ding, Y. Zou, S. Huang, L. Jiang, J. Gensuo, M. Lv, Y. Ren, Z. Ruan, Moon-based earth observation for large scale geoscience phenomena, 2016 IEEE International Geoscience and Remote Sensing Symposium (IGARSS), IEEE, 2016, pp. 3705-3707.

[55]张炯,刘植,段文涛,付饶,余如洋,黄少鹏,音频大地电磁测深法在西咸地热勘探中的应用,中国地球科学联合学术年会论文集 (2016).

[56]熊永柱,陈峰,黄少鹏,基于遥感技术的腾冲地热异常区识别,成都理工大学学报:自然科学版43(1) (2016) 109-118.

[57]唐晓音,黄少鹏,杨树春,姜光政,胡圣标,南海珠江口盆地钻井BHT温度校正及现今地温场特征,地球物理学报59(8) (2016) 2911-2921.

[58] L. Zhi, H. Shaopeng, Multiple time scales of variations of atmospheric CO2 concentration and global climate, Quaternary sciences 35(6) (2015) 1458-1470.

[59]刘植,黄少鹏,不同时间尺度下的大气CO 2浓度与气候变化,第四纪研究35(6) (2015) 1458-1470.

[60]胡圣标,黄少鹏,中国陆地大地热流, in:汪集暘(Ed.),地热学及其应用,北京, 2015, pp. 64-122.

[61] C. Pan, H. Wang, S. Huang, H. Zhang., The Great East Japan Earthquake and Tsunami Aftermath: Preliminary Assessment of Carbon Footprint of Housing Reconstruction, in: Y. Kontar, V. Santiago-Fandino, T. Takahashi (Eds.), Tsunami Events and Lessons Learned: Environmental and Societal Significance, Springer Science+Business Media Dordrecht, 2014, pp. 435-450.

[62] P. Fen, H. Shaopeng, S. Qingjin, C. Yuxiang, J. Yonghe, Satellite thermal infrared remote sensing in geothermal prospecting in volcanic areas: A case study of the Xilingol volcanic field, Inner Mongolia, China, Chinese Journal of Geology 49(3) (2014) 899-914.

[63]王海波,黄少鹏,任永飞,何亮亮,肖波,西安城市地温与气温变化初步分析,地质科学49(3) (2014) 874-887.

[64]彭芬,黄少鹏,时庆金,程玉祥,荆勇河,卫星热红外遥感技术在火山区地热探测中的应用——以内蒙古锡林郭勒火山区为例,地质科学49(3) (2014) 899-914.

[65]庞忠和,黄少鹏,胡圣标,赵平,何丽娟,中国地热研究的进展与展望(1995—2014),地热能(6) (2014) 3-8.

[66]黄少鹏,中国地热能源开发的机遇与挑战,中国能源36(9) (2014) 4-8.

[67]黄少鹏,热流随深度的变化——地热研究中一个永恒的议题, 2014年中国地球科学联合学术年会 (2014).

[68]何亮亮,黄少鹏,肖波,王海波,利用长期地温监测数据研究土壤浅层热扩散率的变化, 2014年中国地球科学联合学术年会 (2014).

[69]冯民,黄杰,涂勇,黄少鹏,新疆于田阿什库勒火山群若干新的野外地质证据,岩石学报(12) (2014) 3512-3520.

[70]段文涛,黄少鹏,时庆金,陈希,岩浆侵入体冷却过程的数值模拟研究, 2014年中国地球科学联合学术年会 (2014).

[71] C. Zhan, J. Cao, Y. Han, S. Huang, X. Tu, P. Wang, Z. An, Spatial distributions and sequestrations of organic carbon and black carbon in soils from the Chinese loess plateau, Science of the Total Environment 465 (2013) 255-266.

[72] F. Peng, Y.Z. Xiong, Y.X. Cheng, Q.C. Fan, S.P. Huang, Towards Application of remote sensing technology in geothermal prospecting in Xilingol in eastern Inner Mongolia, NE China, Advanced Materials Research, Trans Tech Publications Ltd, 2013, pp. 3628-3631.

[73] F. Peng, Y. Xiong, Y. Cheng, Q. Fan, S. Huang, Towards Application of Remote Sensing Technology in Geothermal Prospecting in Xilingol in Eastern Inner Mongolia, NE China, in: Q.J. Xu, Y.H. Ju, H.H. Ge (Eds.), Progress in Environmental Science and Engineering, Pts 1-42013, pp. 3628-3631.

[74] Y. Xiong, S. Huang, F. Chen, H. Ye, C. Wang, C. Zhu, The Impacts of Rapid Urbanization on the Thermal Environment: A Remote Sensing Study of Guangzhou, South China, Remote Sensing 4(7) (2012) 2033-2056.

[75] S. Huang, Geothermal energy in China, Nature Climate Change 2(8) (2012) 557-560.

[76]熊永柱,黄少鹏,城市热环境数据库与可视化共享平台研究,测绘通报(S1) (2012) 537-539.

[77] J. Meng, J. Liu, S. Huang, Soil carbon sequestration of Chinese Loess Plateau and Northeast Phaeozem Region, 2011 International Conference on Electrical and Control Engineering, IEEE, 2011, pp. 3632-3635.

[78] J. Liu, J. Meng, S. Huang, Spatial distribution and estimating of soil organic carbon on Jingyu county, Jilin province, 2011 International Conference on Electrical and Control Engineering, IEEE, 2011, pp. 3638-3641.

[79] J. Liu, J. Meng, S. Huang, The development and prospect of biochar carbon sequestration based on agriculture and forestry resources in China, 2011 Second International Conference on Mechanic Automation and Control Engineering, IEEE, 2011, pp. 6970-6972.

[80] S. Huang, W. Jiyang, HEAT FLOW PATTERN IN PANXI PALEORIFT ZONE, SW CHINA AND ITS MECHANIAL IMPLICATIONS,地震学报10(3) (2011) 289-299.

[81]任永飞,潘翠,王海波,黄少鹏,中美地热资源开发利用现状对比= A,中国环境科学学会学术年会论文集,中国环境科学,北京, 2011.

[82]潘翠,任永飞,王海波,黄少鹏,东日本大地震及海啸灾后住宅重建的能耗分析,中国环境科学学会学术年会论文集,北京, 2011.

[83]孟静静,刘静宇,黄少鹏,土壤碳汇能力衰退的生物炭修复,中国环境科学学会学术年会论文集,中国环境科学学会学术年会论文集,北京, 2011.

[84]刘静宇,孟静静,黄少鹏,丁志强,盛静卫,吉林省靖宇县表层土壤有机碳储量及其分布规律分析,中国环境科学学会学术年会论文集 (2011).

[85] H. Ye, K. Wang, S. Huang, F. Chen, Y. Xiong, X. Zhao, Urbanisation effects on summer habitat comfort: a case study of three coastal cities in southeast China, International Journal of Sustainable Development and World Ecology 17(4) (2010) 317-323.

[86] R. Wawrzaszek, K. Seweryn, J. Grygorczuk, M. Banaszkiewicz, T. Rybus, L. Wisniewski, C.R. Neal, S. Huang, Results of the mole penetration tests in different materials, EGU General Assembly Conference Abstracts, 2010, p. 7348.

[87] L. Pan, H. Ye, S.-P. Huang, G. Li, H. Zhang, Technology, Greenhouse gas emission from municipal solid waste treatment in Beijing, Environmental Science 33(9) (2010) 116-172.

[88] S. Huang, A. Zhisheng, The importance of long-term ground temperature monitoring in earth science, Journal of Earth Environment 1(1) (2010) 1-7.

[89] S. Huang, J. Liu, Geothermal energy stuck between a rock and a hot place, Nature 463(7279) (2010) 293-293.

[90]叶红,潘玲阳,陈峰,汪凯,黄少鹏,城市家庭能耗直接碳排放影响因素——以厦门岛区为例,生态学报(14) (2010) 3802-3811.

[91]潘玲阳,叶红,黄少鹏,李国学,张红玉,北京市生活垃圾处理的温室气体排放变化分析,环境科学与技术(9) (2010).

[92]孟静静,刘静宇,黄少鹏,低碳经济下的生物炭研究,低碳陕西学术研讨会论文集2010, pp. 88-92.

[93]刘静宇,孟静静,黄少鹏,生物炭增汇减排作用及其发展前景展望,低碳陕西学术研讨会论文集 (2010).

[94]李祥余,黄少鹏,叶红,熊永柱,陈峰,汪凯,潘玲阳,厦门站气温非均一性订正及其变化特征对比分析,地理科学30(5) (2010) 796-801.

[95]黄少鹏,安芷生,长期地温监测在地球科学研究中的重要意义,地球环境学报1(1) (2010) 1-7.

[96]黄少鹏,以西部大开发为契机启动陕西地热新能源工程,低碳陕西学术研讨会论文集2010.

[97]陈峰,熊永柱,黄少鹏,叶红,大气水分含量的空间异质性及其对地表温度反演的影响,国土资源遥感2 (2010).

[98]陈峰,邱全毅,熊永柱,黄少鹏,基于线性光谱模型的混合像元分解方法与比较,遥感信息4 (2010).

[99] R. Wawrzaszek, K. Seweryn, J. Grygorczuk, M. Banaszkiewicz, J. Gurgurewicz, C. Neal, S. Huang, N. Kömle, The heat-flow probe hardware component (HPHC) of the LGIP package, Lunar and Planetary Science Conference, 2009, p. 1511.

[100] S. Huang, M. Taniguchi, M. Yamano, C.-h. Wang, Detecting urbanization effects on surface and subsurface thermal environment—A case study of Osaka, Science of the total environment 407(9) (2009) 3142-3152.

[101] S. Huang, T. review, Starting Biochar Carbon Sequestration Projects Opening New Channel for Energy Saving and Pollutant Reduction, Science Technology Review 27 (2009) 18.

[102]李祥余,何清,黄少鹏,李帅,吴新萍,薛福民,田宏强,康国胜,郑伟,南疆一次强沙尘暴前后塔中近地面各气象要素的变化特征,高原气象28(3) (2009) 652-662.

[103]黄少鹏,阿波罗月球热流测量的意外收获:地球气候变化信息,中国地球物理· (2009).

[104]黄少鹏,启动生物炭碳汇工程开辟节能减排新途径,科技导报27(0915) (2009) 18-18.

[105] K. Seweryn, R. Wawrzaszek, J. Grygorczuk, B. Dabrowski, M. Banaszkiewicz, C. Neal, S. Huang, N. Kömle, Modelling of passive and active L-GIP thermal measurements in the lunar regolith, Lunar and Planetary Science Conference, 2008, p. 1957.

[106] W. Kiefer, S. Huang, C. Neal, M. Wieczorek, The Thermal Structure and Evolution of the Moon: Apollo Heat Flow Results, Unresolved Questions, and Future Measurement Objectives, Lunar and Planetary Science Conference, 2008, p. 1683.

[107] S. Huang, H.N. Pollack, P.Y. Shen, A late Quaternary climate reconstruction based on borehole heat flux data, borehole temperature data, and the instrumental record, Geophysical Research Letters 35(13) (2008).

[108] S. Huang, W. Kiefer, C. Neal, N. Kömle, M. Banaszkiewicz, M. Wieczorek, S. Tanaka, Three Deployment Options for the Heat Flow Component of the Long-lived Lunar Geophysics Instrument Package, Lunar and Planetary Science Conference, 2008, p. 1162.

[109] S. Huang, Surface temperatures at the nearside of the Moon as a record of the radiation budget of Earth’s climate system, Advances in Space Research 41(11) (2008) 1853-1860.

[110] L. He, S. Hu, S. Huang, W. Yang, J. Wang, Y. Yuan, S. Yang, Heat flow study at the Chinese Continental Scientific Drilling site: Borehole temperature, thermal conductivity, and radiogenic heat production, Journal of Geophysical Research-Solid Earth 113(B2) (2008).

[111]黄少鹏,在全球气候变化和都市化双重作用下的城市热环境,中国科学院新建研究所人才交流研讨会,中国科学院人事教育局、院地合作局,北京, 2008, pp. 125-135.

[112] C. Neal, L. Hood, S. Huang, S. Sakimoto, W. Kiefer, J. Weinberg, The Case for a Long-lived Global Lunar Geophysical Network-2: Magnetic and Heat Flow Data, Lunar and Planetary Science Conference, 2007, p. 2428.

[113]黄少鹏,关于启动生物炭碳汇工程,化节能减排的巨大压力为农工双赢城乡和谐发展的机遇的思考,中国科学院城市环境研究所,厦门, 2007.

[114] M. Wieczorek, S. Huang, A reanalysis of Apollo 15 and 17 surface and subsurface temperature series, 37th Annual Lunar and Planetary Science Conference, 2006, p. 1682.

[115] H.N. Pollack, S.P. Huang, J.E. Smerdon, Five centuries of climate change in Australia: the view from underground, Journal of Quaternary Science 21(7) (2006) 701-706.

[116] C.R. Neal, L. Hood, S. Huang, Y. Nakamura, Scientific Rationale for Deployment of a Long-Lived Network on the Moon, Requested by the NRC Committee on the Scientific Context for the Exploration of the Moon (2006).

[117] S. Huang, C. Li, J. Li, J. Wang, Y. Shi, A prospective project of the Chang'E Program: Engaging the Moon in the study of terrestrial climate change, 36th COSPAR Scientific Assembly, 2006, p. 1411.

[118] S. Huang, 1851–2004 annual heat budget of the continental landmasses, J Geophysical Research Letters 33(4) (2006).

[119] S. Huang, Land warming as part of global warming, Eos, Transactions American Geophysical Union 87(44) (2006) 477-480.

[120] S. Huang, Detecting change in Earth's radiation budget from the surface temperature time series from the Apollo 15 landing site, 36th COSPAR Scientific Assembly, 2006, p. 2542.

[121] S. Huang, Climate blog could score with newer hockey stick, Nature 433(7028) (2005) 800-800.

[122]黄少鹏,李崇银,汪集旸,石耀霖,李建平,关于在“嫦娥探月”二期工程中增设以研究地球气候变化为主要目的的长期月表温度和辐射观测项目的建议,密歇根大学、中国科学院地质研究所、中国科学院大气物理研究所、中国科学院研究生院,北京, 2005.

[123] S. Huang, The moon: a new platform for terrestrial climate research, 35th COSPAR Scientific Assembly, 2004, p. 2185.

[124] S. Huang, Merging information from different resources for new insights into climate change in the past and future, Geophysical Research Letters 31(13) (2004).

[125] H.N. Pollack, D.Y. Demezhko, A.D. Duchkov, I.V. Golovanova, S.P. Huang, V.A. Shchapov, J.E. Smerdon, Surface temperature trends in Russia over the past five centuries reconstructed from borehole temperatures, Journal of Geophysical Research-Solid Earth 108(B4) (2003).

[126] H.N. Pollack, D.Y. Demezhko, A.D. Duchkov, I.V. Golovanova, S. Huang, V.A. Shchapov, J.E. Smerdon, Geodesy and Gravity/Tectonophysics (ETG)-ETG 2-Surface temperature trends in Russia over the past five centuries reconstructed from borehole temperatures (DOI 10.1029/2002J B002154), Journal of Geophysical Research-Part B-Solid Earth 108(4) (2003).

[127] H.N. Pollack, D.Y. Demezhko, A.D. Duchkov, I.V. Golovanova, S. Huang, V.A. Shchapov, J.E. Smerdon, Surface temperature trends in Russia over the past five centuries reconstructed from borehole temperatures, Journal of Geophysical Research: Solid Earth 108(B4) (2003).

[128] H. Beltrami, J.E. Smerdon, H.N. Pollack, S. Huang, Continental heat gain in the global climate system, Geophysical Research Letters 29(8) (2002) 8-1-8-3.

[129] H.N. Pollack, S.P. Huang, Climate reconstruction from subsurface temperatures, Annual Review of Earth and Planetary Sciences 28 (2000) 339-365.

[130] S. Huang, H.N. Pollack, P.-Y. Shen, Temperature trends over the past five centuries reconstructed from borehole temperatures, Nature 403(6771) (2000) 756-758.

[131] H.N. Pollack, S.P. Huang, Taking Earth's temperature - Response, Geotimes 44(1) (1999) 4-4.

[132] H.N. Pollack, S.P. Huang, P.Y. Shen, Climate change record in subsurface temperatures: A global perspective, Science 282(5387) (1998) 279-281.

[133] H.N. Pollack, S.P. Huang, Underground temperatures reveal changing climate, Geotimes 43(8) (1998) 16-19.

[134] H.N. Pollack, S.P. Huang, Taking Earth's temperature - Response, Geotimes 43(12) (1998) 4-4.

[135] H.N. Pollack, S. Huang, P.-Y. Shen, Climate change record in subsurface temperatures: a global perspective, Science 282(5387) (1998) 279-281.

[136] H.N. Pollack, S. Huang, Underground temperatures reveal changing climate, Geotimes 43(8) (1998) 16-19.

[137] S. Huang, H. Pollack, Global borehole temperature database for climate reconstruction, IGBP PAGES/World Data Center-A for Paleoclimatology data contribution series 44 (1998).

[138]汪集旸,黄少鹏,中国大陆地区大地热流与岩石圈热结构, in:朱光亚、周光召(Ed.),中国科学技术文库(院士卷)3,科学技术文献出版社,北京, 1998, pp. 2664-2667.

[139]黄少鹏,全球大地热流-岩石生热率关系综合分析,地球物理学报(S1) (1998) 26-33.

[140] S. Huang, H.N. Pollack, P.Y. Shen, Late Quaternary temperature changes seen in world‐wide continental heat flow measurements, Geophysical Research Letters 24(15) (1997) 1947-1950.

[141] J.-Y. WANG, S. HUANG, C. Mo-Xiang, Terrestrial heat flux map, in: X.C. Yuan (Ed.) Geophysical Atlas in China, Geological Publishing House, Beijing, 1996.

[142] P.Y. Shen, H.N. Pollack, S. Huang, Inference of ground surface temperature history from borehole temperature data: a comparison of two inverse methods, Global and Planetary Change 14(1-2) (1996) 49-57.

[143] H.N. Pollack, P.Y. Shen, S.P. Huang, Inference of ground surface temperature history from subsurface temperature data: Interpreting ensembles of borehole logs, Pure and Applied Geophysics 147(3) (1996) 537-550.

[144] W. Jiyang, H. Shaopeng, C. Moxiang, Distribution diagram and instructions of Chinese heat flow, in: X. Yuan (Ed.), Geophysical Atlas of China, Geological Publishing House, Beijing, 1996, pp. 199-191.

[145] W. Jiyang, X. Liangping, H. Shaopeng, HEAT TRANSFER AND GROUNDWATER ACTIVITY IN SEDIMENTARY BASINS, Quaternary Sciences 16(2) (1996) 147-158.

[146] S. Huang, P.Y. Shen, H.N. Pollack, Deriving century‐long trends of surface temperature change from borehole temperatures, Geophysical Research Letters 23(3) (1996) 257-260.

[147]熊亮萍,黄少鹏,沉积盆地中热的传递和地下水活动,第四纪研究(2) (1996) 147-158.

[148]汪集旸,黄少鹏,陈墨香, 34大地热流密度图, in:袁学诚(Ed.),中国地球物理图集.国际岩石圈委员会(ICL)出版物第201号,地质出版社,北京, 1996.

[149]刘寿彭,左愚,黄少鹏, 39华北地区综合地球物理图, in:袁学诚(Ed.),中国地球物理图集.国际岩石圈委员会(ICL)出版物第201号,地质出版社,北京, 1996.

[150]刘寿彭,左愚,黄少鹏, 40东南沿海地区综合地球物理图, in:袁学诚(Ed.),中国地球物理图集.国际岩石圈委员会(ICL)出版物第201号,地质出版社,北京, 1996.

[151]刘寿彭,左愚,黄少鹏, 41祁连山地区综合地球物理图, in:袁学诚(Ed.),中国地球物理图集.国际岩石圈委员会(ICL)出版物第201号,地质出版社,北京, 1996.

[152]刘寿彭,左愚,黄少鹏, 42长江中下游地区综合地球物理图, in:袁学诚(Ed.),中国地球物理图集.国际岩石圈委员会(ICL)出版物第201号,地质出版社,北京, 1996.

[153]刘寿彭,左愚,黄少鹏, 43秦岭-大巴山地区综合地球物理图, in:袁学诚(Ed.),中国地球物理图集.国际岩石圈委员会(ICL)出版物第201号,地质出版社,北京, 1996.

[154]刘寿彭,左愚,黄少鹏, 44南岭地区综合地球物理图, in:袁学诚(Ed.),中国地球物理图集.国际岩石圈委员会(ICL)出版物第201号,地质出版社,北京, 1996.

[155]刘寿彭,左愚,黄少鹏, 45西南三江地区综合地球物理图, in:袁学诚(Ed.),中国地球物理图集.国际岩石圈委员会(ICL)出版物第201号,地质出版社,北京, 1996.

[156]刘寿彭,左愚,黄少鹏, 46新疆地区综合地球物理图, in:袁学诚(Ed.),中国地球物理图集.国际岩石圈委员会(ICL)出版物第201号,地质出版社,北京, 1996.

[157]刘寿彭,左愚,黄少鹏, 47青藏地区综合地球物理图, in:袁学诚(Ed.),中国地球物理图集.国际岩石圈委员会(ICL)出版物第201号,地质出版社,北京, 1996.

[158]黄少鹏,汪集旸,陈墨香, 35莫霍面温度分布图, in:袁学诚(Ed.),中国地球物理图集.国际岩石圈委员会(ICL)出版物第201号,地质出版社,北京, 1996.

[159]黄少鹏,汪集旸,陈墨香, 36热岩石圈厚度图, in:袁学诚(Ed.),中国地球物理图集.国际岩石圈委员会(ICL)出版物第201号,地质出版社,北京, 1996.

[160] P.Y. Shen, H.N. Pollack, S. Huang, K. Wang, Effects of subsurface heterogeneity on the inference of climate-change from borehole temperature data - model studies and field examples from Canada, Journal of Geophysical Research-Solid Earth 100(B4) (1995) 6383-6396.

[161] W. Ji-yang, H. Shao-peng, Terrestrial Heat Flow and Geothermal Energy in the Continental Area of China, Geothermal Energy in Asia1995, p. 83.

[162] S. Huang, H.N. Pollack, J.-y. Wang, V. Cermak, Ground surface temperature histories inverted from subsurface temperatures of two boreholes located in Panxi, SW China, Journal of Southeast Asian Earth Sciences 12(1-2) (1995) 113-120.

[163] S. Huang, H. Pollack, S. Boyu, Reading paleoclimate from borehole temperature profiles: Principles and examples, Quaternary Sciences 3 (1995) 213-22.

[164]汪集旸,黄少鹏,中国大陆大地热流分布及岩石圈热结构, 1995.

[165]黄少鹏, H.N. Pollack,从钻孔温度看气候变化:——方法介绍及实例,第四纪研究(3) (1995) 213-222.

[166] J. Wang, S. Huang, Heat flow pattern and its implication for tectonics in the continental area of China, in: M. Yamano, M. Gupta (Eds.), Terrestrial Heat Flow and Geothermal Energy in Asia, Oxford & IBH Publishing Co.PVT.LTD, New Delhi, 1994, pp. 367-378.

[167] S.-P. HUANG, J.-Y. WANG, Heat flow distribution and Thermal Structure of the Continental Area of China, Advances in Geoscience (2), Beijing: China Ocean Press1992.

[168] S. HUANG, J. WANG, Thermal regime of the continental area of China inferred from heat flow, Curie depth and Moho surface, International geological congress, 1992.

[169] S. Huang, J. Wang, Variations of heat flow and Pn-velocity in the continental area of China, Acta Seismologica Sinica 5(4) (1992) 729-738.

[170] S. Huang, Heat flow and the crust-thickness variations in the continent of China, Chinese J. Geophys. 35 (1992) 441-450.

[171]黄少鹏,汪集旸,中国大陆地区大地热流与Pn波速度的变化,地震学报14(1) (1992) 42-42.

[172]黄少鹏,我国大陆地区大地热流与地壳厚度的变化,地球物理学报35(4) (1992) 441-441.

[173] W. Ji-Yang, H. Shao-Peng, The thickness of the thermal lithosphere in the Panxi Paleorift Zone, southwestern China, Terrestrial heat flow and the lithosphere structure, Springer, Berlin, Heidelberg1991, pp. 308-316.

[174] S.P. Huang, J.Y. Wang, Several heat-flow values from deep drill holes in the northwest depression of the Sichuan basin, SW China, Chinese Science Bulletin 36(1) (1991) 47-51.

[175] S. Huang, W. Jiyang, On variations of heat flow and Pn velocity—A case study from the continental area of China, Journal of geodynamics 13(1) (1991) 13-28.

[176]黄少鹏,汪集旸, Several heat flow values from deep drill holes in the northwest depression of the Sichuan Basin, SW China,中国科学通报:英文版(1) (1991) 47-51.

[177] J. Wang, S. Huang, Thermal Structure of the Lithosphere in the Panzhihua Xichang Paleorift Zone, SW China, in: T.J. Wiley, D.G. Howell, F.L. Wong, S. Wang, Y. Zhou (Eds.) Earth Sci.Series, China Ocean Press, Houston Texas, 1990, pp. 367-378.

[178] W. Jiyang, H. Shaopeng, Compilation of terrestrial heat flow data in the China continent region, Seismology and Geology (in Chinese with English abstract), 1990, p. 351ü366.

[179]熊亮萍,黄少鹏,攀西古裂谷实测热流值的地形校正,地球科学:中国地质大学学报15(2) (1990) 203-210.

[180]汪集旸,黄少鹏,中国大陆地区大地热流数据汇编(第二版),地震地质12(4) (1990) 351-351.

[181]黄少鹏,熊亮萍,攀西古裂谷实测热流值的地形校正,地球科学15(2) (1990) 203-203.

[182]黄少鹏,汪集旸,四川盆地川西北拗陷几个深孔热流测试,科学通报35(10) (1990) 773-773.

[183]黄少鹏,中国大陆地区大地热流分布特征初探,中国科技大学研究生院、中国科学院地质研究所,中国科学院研究生院、中国科学院地质研究所,北京, 1990, p. 100.

[184] J.Y. Wang, S.P. Huang, DETERMINATION OF THE THICKNESS OF LITHOSPHERE BY GEOTHERMAL DATA, Chinese Science Bulletin 34(5) (1989) 417-420.

[185] J.Y. Wang, S.P. Huang, Statistical-analysis of continental heat-flow data from China, Chinese Science Bulletin 34(7) (1989) 582-587.

[186] W. Jiyang, C. Moxiang, W. Ji'an, D. Xiao, H.J. Shaopeng, Institute of Geology, Academia Sinica, China, Ocean Press, Beijing, Terrestrial heat flow in eastern China and its implications for geotectonics, Advances in Geoscience (1989) 386-399.

[187] S. Huang, THE DISTRIBUTION OF HEAT FLOW DATA IN THE CONTINENTAL AREA OF CHINA AND ITS PRELIMINARY STUDIES [J], Seismology Geology 3 (1989).

[188] S. Huang, Variations of terrestrial heat-flow in longitudinal and latitudinal directions - review of continental heat-flow data from China, Japan and its surroundings and the United-States, Chinese Science Bulletin 34(9) (1989) 761-765.

[189]汪集旸,黄少鹏, Statistical analysis of continental heat flow data from China, Science Bulletin 34(7) (1989) 582-587.

[190]黄少鹏,中国大陆地区热流数据的分布及其初步分析,地震地质11(3) (1989) 17-17.

[191] J.Y. Wang, S.P. Huang, Compilation of heat-flow data for continental area of China, Scientia Geologica Sinica (2) (1988) 196-206.

[192] S. Huang, J. Wang, COMPILATION OF HEAT FLOW DATA FOR CONTINENTAL AREA OF CHINA [J], Chinese Journal of Geology 2 (1988).

[193]汪集旸,汪缉安,黄少鹏,张文仁,周友松,金昕,攀西古裂谷地区深部热流,地球科学-中国地质大学学报3 (1988).

[194]汪集旸,黄少鹏,中国大陆地区热流数据统计分析,科学通报33(17) (1988) 1326-1329.

[195]汪集旸,黄少鹏,中国大陆地区大地热流数据汇编,地质科学2 (1988) 196-204.

[196]汪集旸,黄少鹏,利用地热资料确定岩石圈厚度——以攀西地区为例,科学通报33(1) (1988).

[197]黄少鹏,汪集旸,攀西古裂谷区地表热流分布特征及其力学含义,地震学报3 (1988).

[198]黄少鹏,汪集旸,中国大陆地区大地热流分布特征初探, in:王思敬(Ed.),中国科学院地质研究所集刊(2),科学出版社,北京, 1988.

[199]黄少鹏,大地热流沿经,纬向的变化——中国大陆,日本及其周围海域和美国大陆热流数据分析,科学通报33(18) (1988) 1405-1408.

[200] J.Y. Wang, S.P. Huang, Linear relationship between heat-flow and heat-production in Panxi paleorift zone, southwestern China, Geophysical Research Letters 14(3) (1987) 272-274.

[201] S.P. Huang, L.P. Xiong, On the topographic correction of near-surface heat-flow, Scientia Geologica Sinica (2) (1987) 174-182.

[202] J.-y. Wang, J.-a. Wang, S.-p. Huang, W.-t. Zhang, Y.-s. Zhou, X. Jin, Heat flow measurements in Panzhihua-Xichang (Panxi) paleorift zone, southwestern China, Chinese Science Bulletin 10 (1986) 763-766.

[203] J.-Y. WANG, J.-A. WANG, S.-P. HUANG, Heat flow studies in Panxi paleorift zone, southwestern China, International meeting on geothermics and geothermal energy, 1986.

[204]汪集晹,汪缉安,黄少鹏,张文仁,周友松,金昕,攀西古裂谷大地热流测量,科学通报10 (1986).

[205]黄少鹏,攀西古裂谷大地热流,中国科技大学研究生院、中国科学院地质研究所,中国科技大学研究生院,北京, 1986.

[206]黄少鹏,热流和隆起对裂谷热过程的制约,地震地质译丛3 (1985).


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