姜兆霞

1、學習經歷

中國海洋大學，勘查技術與工程，學士學位，青島，2008.06

中國科學院地質與地球物理研究所，固體地球物理學，博士學位，北京，2014.06

2、工作經歷

2009.10-2010.01 西班牙Córdoba大學訪問學者

2012.05-2012.08 義大利Molise大學訪問學者

2012.06-2012.07 法國艾克斯-馬賽大學訪問學者

2015.10-2016.10 澳大利亞國立大學，訪問學者

2014.06-2017.11 中國科學院地質與地球物理研究所，博士後

2017.12-至今中國海洋大學，副教授

3、學術兼拳料微職

美國地球物理學會（AGU），會員

中國地球科學聯合會（CGU），會員

《Geophysical Research Letters》、《Quaternary International》、《Compostites Part B》、《第四紀研究》等審稿人

1、學科方向：海洋地質學、古地磁學

2、近期研究興趣：

1）洋陸過渡帶構造磁學研究：依託古地磁方法，以洋底基岩樣品和我國東部陸相岩石為研究載體，建立傳統岩石礦物學與古地磁學相結合的綜合研究體系，多尺度（從巨觀到微鍵捆紙觀尺度）、多參數（礦物結構、成分、磁學性質等）研究基岩的形成過程及其記錄的古地磁場信息。從古地磁學、岩石學、礦物學等多角度剖析太平洋、茅乘奔熱印度洋與我國大陸之間的洋-陸構造過程以及邊緣海形成機制。

2）海洋氣候演化研究：利轎危用磁性地層學手段，為邊緣海沉積物建立可靠的年齡框架。在此基礎求奔灑端上，依託傳統的古地磁學方法和技術，將磁性礦物的形成過程和載磁機理和賦存狀態相結合，以此反演海洋環境及構造過程，開展海洋氣候演化及構造反演的綜合研究。

4、主持的重要科研項目

1）國家自然科學基金青年基金項目，“華南紅層的重磁化機制研究”（41504055，2015.01-2018-12），項目負責人

2）中國博士後基金一等資助，“赤鐵礦碎屑剩磁傾角淺化機制研究”（2014M560112，2014.09-2016.12），項目負責人

3）中國博士後基金特別資助，“套用紅層構建地磁場相對強度的可挨捆遷行性研究”（2015T80131,2015.09-2017.12），項目負責人

主要論文目錄

1、論文收錄情況：已發表論文30餘篇，被SCI收錄29篇，其中第一作者SCI收錄10篇，核心論文3篇。

2、代表性文章列表如寒恥滲下：

2017

[1]Jiang ZX, Liu QS, Dekkers MJ, Zhao X, Roberts AP, Yang ZY, Jin CS, Liu JX, 2017. Remagnetization mechanisms in Triassic red beds from South China. Earth and Planetary Science Letters 479, 219-230.

[2]Cao L, Jiang ZX, Du YH, Yin XM, Xi SB, Wen W, Roberts AP, Wee TS, Xiong YM, Liu QS and Gao XY，2017. Origin of Magnetism in Hydrothermally Aged 2-Line Ferrihydrite Suspensions. Environmental Science & Technology, 51(5): 2643-2651.

[3]Liu ZF, Ma J, Wei G, Liu QS, Jiang ZX, Ding X, Peng S, Ouyang, TP, 2017. Magnetism of a red soil core derived from basalt, northern Hainan Island, China: volcanic ash vs pedogenesis. Journal of Geophysical Research 122, 1677-1696.

[4]Ao H, Dekkers MJ, Roberts AP, Rohling EJ, An Z, Liu X, Jiang ZX, Qiang XK, Xu Y, Chang H, 2017. Mineral magnetic record of the Miocene-Pliocene climate transition on the Chinese Loess Plateau, North China. Quaternary Research, 1-10.

2016

[5]Jiang ZX, Liu QS, Zhao X, Roberts AP, Heslop D, Barrón V, Torrent J, 2016. Magnetism of Al-magnetite reduced from Al-hematite, Journal of Geophysical Research, 121, doi:10.1002/2016JB012863.

[6]Jiang ZX, Liu QS, Dekkers MJ, Barrón V, Torrent J, Roberts AP, 2016. Control of Earth-like magnetic fields on the transformation of ferrihydrite to hematite and goethite, Scientific Reports,6, doi:10.1038/srep30395.

[7]Hu PX, Jiang ZX, Liu QS, Heslop D, Roberts AP, Torrent J, and Barrón V, 2016. Estimating the concentration of aluminumsubstituted hematite and goethite using diffuse reflectance spectrometry and rock magnetism: feasibility and limitations. Journal of Geophysical Research, 121, doi:10.1002/2015JB012635.

[8]Jin CS, Liu QS, Hu PX, Jiang ZX, Li CG, Han P, Yang H, Liang WT, 2016. An integrated natural remanent magnetization acquisition model for the Matuyama-Brunhes reversal recorded by the Chinese loess. Geochemistry, Geophysics, Geosystems, doi: 10.1002/2016GC006407.

[9]Oliva-Urcia, B., A. Muñoz, J. Larrasoaña, A. Luzón, A. Pérez, Á. González,Jiang ZX, Q. Liu, and T. Román-Berdiel, 2016. Response of alluvial systems to Late Pleistocene climate changes recorded by environmental magnetism in the Añavieja Basin (Iberian Range, NE Spain). Geologica Acta, 14, 139-154.

[10]Liu, QS, C. Zhang, J. Torrent, V. Barrón, P. Hu, Jiang ZX, and Z. Duan, 2016. Factors controlling magnetism of reddish brown soil profiles from calcarenites in Southern Spain: Dust input or in-situ pedogenesis? Frontiers in Earth Science, 4, 1-12.

[11]Claudio Colombo, Giuseppe Palumbo, Erika Di Iorio, Filippo Russo, Fabio Terribile, Jiang ZX, Qingsong Liu, 2016. Soil development in a Quaternary fluvio-lacustrine paleosol sequence in Southern Italy, Quaternary International, 96, 1623-32.

[12]姜兆霞, 劉青松, 2016. 赤鐵礦的定量化及其氣候意義. 第四紀研究, 36, 676-689.

2015

[13]Jiang ZX, Liu QS, Dekkers MJ, Tauxe L, Qin HF, Barrón V, Torrent J, 2015. Acquisition of chemical remanent magnetization during experimental ferrihydrite–hematite conversion in Earth-like magnetic field—implications for paleomagnetic studies of red beds, Earth and Planetary Science Letters, 428:1-10

[14]Jiang ZX, Liu QS, Zhao XY, Jin CS, Liu CC, Li SH, 2015. Thermal magnetic behaviour of Al-substituted haematite mixed with clay minerals and its geological significance. Geophysical Journal International, 200(1):130-143

[15]Qingsong Liu, Chunsheng Jin, Pengxiang Hu, Jiang ZX, Kunpeng Ge, Roberts Andrew P., 2015. Magnetostratigraphy of Chinese loess–paleosol sequences, Earth-Science Reviews, 150: 139-167

[16]Youliang Su, Guoqiang Chu, Qingsong Liu, Jiang ZX, Xing Gao, Haberzettl, Torsten, 2015. A 1400 year environmental magnetic record from varved sediments of Lake Xiaolongwan (Northeast China) reflecting natural and anthropogenic soil erosion, Geochemistry, Geophysics, Geosystems, 16(9): 3053-3060

[17]Qingsong Liu, Youbin Sun, Xiaoke Qiang, Ryuji Tada, Pengxiang Hu, Zongqi Duan, Jiang ZX, Jianxing Liu , Kai Su, 2015. Characterizing magnetic mineral assemblages of surface sediments from major Asian dust sources and implications for the Chinese loess magnetism, Earth Planets and Space, 6(17):1-13

[18]Claudio Colombo, Giuseppe Palumbo, Erika Di Iorio, Xin Song, Jiang ZX, Qingsong Liu, Ruggero Angelico, 2015. Influence of hydrothermal synthesis conditions on size, morphology and colloidal properties of Hematite nanoparticles, Nano-Structures & Nano-Objects, 2:19-27

[19]Kai Su, Qingsong Liu, Jiang ZX, Zongqi Duan, 2015. Mechanism of magnetic property changes of serpentinites from ODP Holes 897D and 1070A, Science in China, 58(5): 815-829

2014

[20]Jiang ZX, Liu QS, Colombo C, Barrón V, Torrent J，2014. Quantification of Al-goethite from diffuse reflectance spectroscopy and magnetic methods, Geophysical Journal International, 196, 131-144.

[21]Jiang ZX, Liu QS, Dekkers MJ, Colombo C, Yu YJ, Barrón V, Torrent J, 2014. Ferro and antiferromagnetism of ultrafine-grained hematite.Geochemistry, Geophysics, Geosystems, 15(6), 2699-2712

[22]Liu JX, Shi XF, Liu QS, Ge SL, Liu YG, Yao ZQ, Zhao QL, Jin CS, Jiang ZX, Shengfa Liu, Shuqing Qiao, Xiaoyan Li, Chuanshun Li, Chunjuan Wang, 2014. Magnetostratigraphy of a greigite-bearing core from the South Yellow Sea: Implications for remagnetization and sedimentation, Journal of Geophysical Research, doi: 10.1002/2014JB011206

2013

[23]Jiang ZX, Rochette P, Liu QS, Gattacceca J, Yu YJ,Barrón V, Torrent J, 2013. Pressure demagnetization of synthetic Al substituted hematite and its implications for planetary studies, Physics of Earth and Planetary Interiors, 224, 1-10.

[24]Jeong D, Yu YJ, Liu QS, Jiang ZX, Koh GW, Koh DC, 2013. Geomagnetic field intensity determination from pleistocene trachytic lava flows in Jeju Geopark, Geochemistry, Geophysics, Geosystems, DOI: 10.1002/2013GC005028

2012

[25]Jiang ZX, Liu QS, 2012. Magnetic characterization and paleoclimatic significances of late Pliocene-early Pleistocene sediments at site 882A, northwestern Pacific Ocean, Science in China, 55, 323-331.

[26]Jiang ZX, Liu QS, Barrón V, Torrent J, 2012, Magnetic discrimination between Al-substituted hematites synthesized by hydrothermal and thermal dehydration methods and its geological significance, Journal Geophysical Research, 117, B02102, doi:10.1029/2011JB008605

[27]Liu QS, Larrasoaña JC, Torrent J, Roberts AP, Rohling EJ, Liu ZF, and Jiang ZX, 2012. New constraints on climate forcing and variability in the circum-Mediterranean region from magnetic and geochemical observations of sapropels S1, S5 and S6, Palaeogeography, Palaeoclimatology, Palaeoecology, 333-334, 1-12.

[28]姜兆霞, 劉青松, 2012. 影響赤鐵礦中鋁替代量的因素及其環境意義探討, 第四紀研究, 32(004): 608-614

2011

[29]姜兆霞，劉青松, 2011.上新世末期-更新世早期西北太平洋ODP882A孔沉積物的磁學特徵及其古氣候意義.中國科學：地球科學，41，1242-1252

[30]Bailey I., Liu QS, Swann GEA, Jiang ZX, Sun YB, Zhao X, Roberts AP., 2011. Aeolian dust fertilization and biogeochemical cycles in the sub-Arctic northwest Pacific during the late Pliocene intensification of northern hemisphere glaciation, Earth and Planetary Science Letters, 307, 253-265.

2010

[31]Liu QS, Hu PX, Torrent J, Barrón V, Zhao XY, Jiang ZX, Su YL, 2010. Environmental magnetic study of a Xeralf chronosequence in northwestern Spain: indications for pedogenesis, Palaeogeography, Palaeoclimatology, Palaeoecology,293, 144-156.

[32]Liu QS, Torrent J, Morrás H, Hong A, Jiang ZX, Su YL, 2010. Superparamagnetism of two modern soils from the northeastern Pampean region, Argentina, and its paleoclimatic indications, Geophysical Journal International, 183, 695-705.

[2]Cao L, Jiang ZX, Du YH, Yin XM, Xi SB, Wen W, Roberts AP, Wee TS, Xiong YM, Liu QS and Gao XY，2017. Origin of Magnetism in Hydrothermally Aged 2-Line Ferrihydrite Suspensions. Environmental Science & Technology, 51(5): 2643-2651.

[3]Liu ZF, Ma J, Wei G, Liu QS, Jiang ZX, Ding X, Peng S, Ouyang, TP, 2017. Magnetism of a red soil core derived from basalt, northern Hainan Island, China: volcanic ash vs pedogenesis. Journal of Geophysical Research 122, 1677-1696.

[4]Ao H, Dekkers MJ, Roberts AP, Rohling EJ, An Z, Liu X, Jiang ZX, Qiang XK, Xu Y, Chang H, 2017. Mineral magnetic record of the Miocene-Pliocene climate transition on the Chinese Loess Plateau, North China. Quaternary Research, 1-10.

2016

[5]Jiang ZX, Liu QS, Zhao X, Roberts AP, Heslop D, Barrón V, Torrent J, 2016. Magnetism of Al-magnetite reduced from Al-hematite, Journal of Geophysical Research, 121, doi:10.1002/2016JB012863.

[6]Jiang ZX, Liu QS, Dekkers MJ, Barrón V, Torrent J, Roberts AP, 2016. Control of Earth-like magnetic fields on the transformation of ferrihydrite to hematite and goethite, Scientific Reports,6, doi:10.1038/srep30395.

[7]Hu PX, Jiang ZX, Liu QS, Heslop D, Roberts AP, Torrent J, and Barrón V, 2016. Estimating the concentration of aluminumsubstituted hematite and goethite using diffuse reflectance spectrometry and rock magnetism: feasibility and limitations. Journal of Geophysical Research, 121, doi:10.1002/2015JB012635.

[8]Jin CS, Liu QS, Hu PX, Jiang ZX, Li CG, Han P, Yang H, Liang WT, 2016. An integrated natural remanent magnetization acquisition model for the Matuyama-Brunhes reversal recorded by the Chinese loess. Geochemistry, Geophysics, Geosystems, doi: 10.1002/2016GC006407.

[9]Oliva-Urcia, B., A. Muñoz, J. Larrasoaña, A. Luzón, A. Pérez, Á. González,Jiang ZX, Q. Liu, and T. Román-Berdiel, 2016. Response of alluvial systems to Late Pleistocene climate changes recorded by environmental magnetism in the Añavieja Basin (Iberian Range, NE Spain). Geologica Acta, 14, 139-154.

[10]Liu, QS, C. Zhang, J. Torrent, V. Barrón, P. Hu, Jiang ZX, and Z. Duan, 2016. Factors controlling magnetism of reddish brown soil profiles from calcarenites in Southern Spain: Dust input or in-situ pedogenesis? Frontiers in Earth Science, 4, 1-12.

[11]Claudio Colombo, Giuseppe Palumbo, Erika Di Iorio, Filippo Russo, Fabio Terribile, Jiang ZX, Qingsong Liu, 2016. Soil development in a Quaternary fluvio-lacustrine paleosol sequence in Southern Italy, Quaternary International, 96, 1623-32.

[12]姜兆霞, 劉青松, 2016. 赤鐵礦的定量化及其氣候意義. 第四紀研究, 36, 676-689.

2015

[13]Jiang ZX, Liu QS, Dekkers MJ, Tauxe L, Qin HF, Barrón V, Torrent J, 2015. Acquisition of chemical remanent magnetization during experimental ferrihydrite–hematite conversion in Earth-like magnetic field—implications for paleomagnetic studies of red beds, Earth and Planetary Science Letters, 428:1-10

[14]Jiang ZX, Liu QS, Zhao XY, Jin CS, Liu CC, Li SH, 2015. Thermal magnetic behaviour of Al-substituted haematite mixed with clay minerals and its geological significance. Geophysical Journal International, 200(1):130-143

[15]Qingsong Liu, Chunsheng Jin, Pengxiang Hu, Jiang ZX, Kunpeng Ge, Roberts Andrew P., 2015. Magnetostratigraphy of Chinese loess–paleosol sequences, Earth-Science Reviews, 150: 139-167

[16]Youliang Su, Guoqiang Chu, Qingsong Liu, Jiang ZX, Xing Gao, Haberzettl, Torsten, 2015. A 1400 year environmental magnetic record from varved sediments of Lake Xiaolongwan (Northeast China) reflecting natural and anthropogenic soil erosion, Geochemistry, Geophysics, Geosystems, 16(9): 3053-3060

[17]Qingsong Liu, Youbin Sun, Xiaoke Qiang, Ryuji Tada, Pengxiang Hu, Zongqi Duan, Jiang ZX, Jianxing Liu , Kai Su, 2015. Characterizing magnetic mineral assemblages of surface sediments from major Asian dust sources and implications for the Chinese loess magnetism, Earth Planets and Space, 6(17):1-13

[18]Claudio Colombo, Giuseppe Palumbo, Erika Di Iorio, Xin Song, Jiang ZX, Qingsong Liu, Ruggero Angelico, 2015. Influence of hydrothermal synthesis conditions on size, morphology and colloidal properties of Hematite nanoparticles, Nano-Structures & Nano-Objects, 2:19-27

[19]Kai Su, Qingsong Liu, Jiang ZX, Zongqi Duan, 2015. Mechanism of magnetic property changes of serpentinites from ODP Holes 897D and 1070A, Science in China, 58(5): 815-829

2014

[20]Jiang ZX, Liu QS, Colombo C, Barrón V, Torrent J，2014. Quantification of Al-goethite from diffuse reflectance spectroscopy and magnetic methods, Geophysical Journal International, 196, 131-144.

[21]Jiang ZX, Liu QS, Dekkers MJ, Colombo C, Yu YJ, Barrón V, Torrent J, 2014. Ferro and antiferromagnetism of ultrafine-grained hematite.Geochemistry, Geophysics, Geosystems, 15(6), 2699-2712

[22]Liu JX, Shi XF, Liu QS, Ge SL, Liu YG, Yao ZQ, Zhao QL, Jin CS, Jiang ZX, Shengfa Liu, Shuqing Qiao, Xiaoyan Li, Chuanshun Li, Chunjuan Wang, 2014. Magnetostratigraphy of a greigite-bearing core from the South Yellow Sea: Implications for remagnetization and sedimentation, Journal of Geophysical Research, doi: 10.1002/2014JB011206

2013

[23]Jiang ZX, Rochette P, Liu QS, Gattacceca J, Yu YJ,Barrón V, Torrent J, 2013. Pressure demagnetization of synthetic Al substituted hematite and its implications for planetary studies, Physics of Earth and Planetary Interiors, 224, 1-10.

[24]Jeong D, Yu YJ, Liu QS, Jiang ZX, Koh GW, Koh DC, 2013. Geomagnetic field intensity determination from pleistocene trachytic lava flows in Jeju Geopark, Geochemistry, Geophysics, Geosystems, DOI: 10.1002/2013GC005028

2012

[25]Jiang ZX, Liu QS, 2012. Magnetic characterization and paleoclimatic significances of late Pliocene-early Pleistocene sediments at site 882A, northwestern Pacific Ocean, Science in China, 55, 323-331.

[26]Jiang ZX, Liu QS, Barrón V, Torrent J, 2012, Magnetic discrimination between Al-substituted hematites synthesized by hydrothermal and thermal dehydration methods and its geological significance, Journal Geophysical Research, 117, B02102, doi:10.1029/2011JB008605

[27]Liu QS, Larrasoaña JC, Torrent J, Roberts AP, Rohling EJ, Liu ZF, and Jiang ZX, 2012. New constraints on climate forcing and variability in the circum-Mediterranean region from magnetic and geochemical observations of sapropels S1, S5 and S6, Palaeogeography, Palaeoclimatology, Palaeoecology, 333-334, 1-12.

[28]姜兆霞, 劉青松, 2012. 影響赤鐵礦中鋁替代量的因素及其環境意義探討, 第四紀研究, 32(004): 608-614

2011

[29]姜兆霞，劉青松, 2011.上新世末期-更新世早期西北太平洋ODP882A孔沉積物的磁學特徵及其古氣候意義.中國科學：地球科學，41，1242-1252

[30]Bailey I., Liu QS, Swann GEA, Jiang ZX, Sun YB, Zhao X, Roberts AP., 2011. Aeolian dust fertilization and biogeochemical cycles in the sub-Arctic northwest Pacific during the late Pliocene intensification of northern hemisphere glaciation, Earth and Planetary Science Letters, 307, 253-265.

2010

[31]Liu QS, Hu PX, Torrent J, Barrón V, Zhao XY, Jiang ZX, Su YL, 2010. Environmental magnetic study of a Xeralf chronosequence in northwestern Spain: indications for pedogenesis, Palaeogeography, Palaeoclimatology, Palaeoecology,293, 144-156.

[32]Liu QS, Torrent J, Morrás H, Hong A, Jiang ZX, Su YL, 2010. Superparamagnetism of two modern soils from the northeastern Pampean region, Argentina, and its paleoclimatic indications, Geophysical Journal International, 183, 695-705.