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教师主页 科研项目 研究领域 学术成果 教学 科研分享 新闻动态 疼痛医学中心 成果介绍 软件 毕业去向 加入我们 联系我们 MARK JAMES HOPWOOD Google Scholar 副教授 海洋科学与工程系 Mark Hopwood，南方科技大学海洋科学与工程系副教授。Hopwood博士于2015年在英国南安普顿大学获得海洋和地球科学博士学位，其导师Peter Statham是痕量金属超净技术方面领先的研究学者，而该技术是研究海洋中超低浓度金属所必需的技术。同年，Hopwood博士加入了德国GEOMAR基尔亥姆霍兹海洋研究中心，在Eric Achterberg教授课题组——全球最大的海洋化学研究组完成了博士后研究工作。同时还在美国北卡罗莱纳大学威尔明顿分校进行交流学习。2017年，Hopwood博士被任命为智利高纬度海洋生态系统动态研究中心的副研究员（瓦尔迪维亚，智利）。2019年，Hopwood博士获得了德国科学基金会（DFG）资助的独立研究项目，用于研究格陵兰岛和南极洲区域的冰-洋相互作用。2021年4月，Hopwood博士作为助理教授加入南方科技大学，同年12月破格提升为副教授。 Hopwood教授已经累计参与9个科考航次并在斯瓦尔巴德岛、格陵兰和南极洲上进行了累计10个月的极地科学考察。在Nature Communications、Nature Geoscience、Geophysical Research Letters等海洋学一流期刊上共发表文章50篇。Hopwood教授目前是Journal of Geophysical Research: Oceans (AGU) 期刊的副编辑。 Hopwood教授目前教授两门课程（春季学期开设的本科生课程OCE108碳中和概论和秋季学期开设的研究生课程OCE5030海洋生物地球化学循环，同时兼任学校射箭社团的教练。Hopwood教授的研究团队目前也在中国科学院大学大亚湾生物综合实验站（深圳）开展大规模（100,000 升）实验，研究负排放技术的潜力如提高海洋碱度，以便在海洋中安全地储存更多的二氧化碳。 Mark老师还利用自己的业余时间，作为海阔体育的助教，教授小朋友们海洋科学的相关知识和浆板技能，从而让小朋友们感受到海洋科学的魅力。 个人简介 个人简介 研究领域 海洋生物地球化学、极地环境、海洋养分、痕量金属 教学 主要教授课程：研究生课程OCE5030海洋生物地球化学循环（秋季学期）、本科生课程OCE108碳中和概论（春季学期）。 学术成果 查看更多 在研项目 POLAR BEAST cruise (5 weeks) – a polar cruise investigating Arctic/Atlantic connectivity via the EGC EUROFLEETS Ice Disko cruise (2 weeks) – biogeochemistry of icebergs in Disko Bay NSFC RFIS Investigating cobalt dynamics in the cryosphere (Arctic and Antarctic) 发表论文 Krisch, S. et al.The effect of ice cavities on ice sheet nutrient export: A case study at Nioghalvfjerdsbrae, the 79°N Glacier. Nat. Commun. (Accepted) Vergara-Jara, M. J. et al.A mosaic of phytoplankton responses across Patagonia, the SE Pacific and SW Atlantic Ocean to ash deposition and trace metal release from the Calbuco 2015 volcanic eruption. Ocean Sci. Discuss.2020, 1–42 (2020). (Accepted) Browning, T. J. et al.Iron regulation of North Atlantic eddy phytoplankton productivity. Geophys. Res. Lett.(2021) doi:10.1029/2020gl091403. Geißler, F. et al.Lab-on-chip analyser for the in situ determination of dissolved manganese in seawater. Sci. Rep.11, (2021). Cantoni, C. et al.Glacial drivers of marine biogeochemistry indicate a future shift to more corrosive conditions in an Arctic fjord. J. Geophys. Res. Biogeosciencesn/a, e2020JG005633 (2020). Bach, L. T. et al.Factors controlling plankton community production, export flux, and particulate matter stoichiometry in the coastal upwelling system off Peru. Biogeosciences17, (2020). Krisch, S. et al.The influence of Arctic Fe and Atlantic fixed N on summertime primary production in Fram Strait, North Greenland Sea. Sci. Rep.10, 15230 (2020). Browning, T. J. et al.Nutrient regulation of late spring phytoplankton blooms in the midlatitude North Atlantic. Limnol. Oceanogr.(2019) doi:10.1002/lno.11376. Hopwood, M. J.et al. Review article: How does glacier discharge affect marine biogeochemistry and primary production in the Arctic? Cryosph. (2020) doi:10.5194/tc-14-1347-2020. Vieira, L. H. et al.Unprecedented Fe delivery from the Congo River margin to the South Atlantic Gyre. Nat. Commun.(2020) doi:10.1038/s41467-019-14255-2. Hopwood, M. J. et al.Fe(II) stability in coastal seawater during experiments in Patagonia, Svalbard, and Gran Canaria. Biogeosciences (2020) doi:10.5194/bg-17-1327-2020. Straneo, F. et al.The case for a sustained Greenland Ice sheet-Ocean Observing System (GrIOOS). Frontiers in Marine Science(2019) doi:10.3389/fmars.2019.00138. Höfer, J. et al.The role of water column stability and wind mixing in the production/export dynamics of two bays in the Western Antarctic Peninsula. Prog. Oceanogr.(2019) doi:10.1016/j.pocean.2019.01.005. Hopwood, M. J.et al. Non-linear response of summertime marine productivity to increased meltwater discharge around Greenland. Nat. Commun. 9, 3256 (2018). Hopwood, M. Iron from ice. Nat. Geosci.(2018) doi:10.1038/s41561-018-0167-8. Hopwood, M. J.et al. Photochemical vs. Bacterial Control of H2O2 Concentration Across a pCO2 Gradient Mesocosm Experiment in the Subtropical North Atlantic. Frontiers in Marine Science vol. 5 105 (2018). Menzel Barraqueta, J.-L. et al.Aluminium in the North Atlantic Ocean and the Labrador Sea (GEOTRACES GA01 section): roles of continental inputs and biogenic particle removal. Biogeosciences2018, 1–28 (2018). Hopwood, M. J., Rapp, I., Schlosser, C. & Achterberg, E. P. Hydrogen peroxide in deep waters from the Mediterranean Sea, South Atlantic and South Pacific Oceans. Sci. Rep.7, (2017). Hopwood, M. J. et al.A Comparison between Four Analytical Methods for the Measurement of Fe(II) at Nanomolar Concentrations in Coastal Seawater. Frontiers in Marine Science vol. 4 192 (2017). Geißler, F. et al.Evaluation of a ferrozine based autonomous in situ lab-on-chip analyzer for dissolved iron species in coastal waters. Front. Mar. Sci.4, (2017). Hopwood, M. J., Cantoni, C., Clarke, J. S., Cozzi, S. & Achterberg, E. P. The heterogeneous nature of Fe delivery from melting icebergs. Geochemical Perspect. Lett.3, 200–209 (2017). Meire, L. et al.High export of dissolved silica from the Greenland Ice Sheet. Geophys. Res. Lett.43, 9173–9182 (2016). Hopwood, M. J.et al. Seasonal Changes in Fe along a Glaciated Greenlandic Fjord. Front. Earth Sci. 4, (2016). Hopwood, M. J., Statham, P. J., Skrabal, S. A. & Willey, J. D. Dissolved iron(II) ligands in river and estuarine water. Mar. Chem.173, 173–182 (2015). Hopwood, M. J.,Bacon, S., Arendt, K., Connelly, D. P. & Statham, P. J. Glacial meltwater from Greenland is not likely to be an important source of Fe to the North Atlantic. Biogeochemistry 124, (2015). Willey, J. D., et al.The role of fossil fuel combustion on the stability of dissolved iron in rainwater. Atmos. Environ.107, 187–193 (2015). Hopwood, M. J., Statham, P. J. & Milani, A. Dissolved Fe(II) in a river-estuary system rich in dissolved organic matter. Estuar. Coast. Shelf Sci.151, 1–9 (2014). Hopwood, M. J., Statham, P. J., Tranter, M. & Wadham, J. L. Glacial flours as a potential source of Fe(II) and Fe(III) to polar waters. Biogeochemistry118, 443–452 (2014). Vergara-Jara, M. J. et al., A mosaic of phytoplankton responses across Patagonia, the southeast Pacific and the southwest Atlantic to ash deposition and trace metal release from the Calbuco volcanic eruption in 2015. Ocean Sci. 17, 561–578 (2021) Krisch, S. et al., The 79°N Glacier cavity modulates subglacial iron export to the NE Greenland Shelf. Nat. Commun. 12, 3030 (2021). Zhu, K. et al., Influence of pH and Dissolved Organic Matter on Iron Speciation and Apparent Iron Solubility in the Peruvian Shelf and Slope Region. Environ. Sci. Technol. (2021) Krahmann, G. et al., Climate-Biogeochemistry Interactions in the Tropical Ocean: Data collection and legacy. Front. Mar. Sci. (2021) van Genuchten G. M. et al., Decoupling of particles and dissolved iron downstream of Greenlandic glacier outflows, Earth and Planetary Science Letters 576 (2021) Wallmann, K. et al., Biogeochemical feedbacks may amplify ongoing and future ocean deoxygenation: a case study from the Peruvian oxygen minimum zone, Biogeochemistry 159 (1), 45-67 (2022) Krisch, S. et al., Arctic–Atlantic exchange of the dissolved micronutrients Iron, Manganese, Cobalt, Nickel, Copper and Zinc with a focus on Fram Strait, Global Biogeochemical Cycles (2022) Slater, D. A. et al., Characteristic depths, fluxes and timescales for Greenland’s tidewater glacier fjords from subglacial discharge‐driven upwelling during summer, Geophysical Research Letters (2022) van Genuchten G. M. et al., Solid-phase Mn speciation in suspended particles along meltwater-influenced fjords of West Greenland, Geochimica et Cosmochimica Acta 326, 180-198 (2022) Liu T. et al., Sediment release in the Benguela Upwelling System dominates trace metal input to the shelf and eastern South Atlantic Ocean, Global Biogeochemical Cycles (2022) Krisch S. et al., Quantifying ice-sheet derived lead (Pb) fluxes into the ocean; a case study at Nioghalvfjerdsbrae, Geophysical Research Letters, (2022) Hunt H. R. et al., Distinguishing the influence of sediments, the Congo River, and water-mass mixing on the distribution of iron and its isotopes in the Southeast Atlantic Ocean, Marine Chemistry, (2022) Chen X. G. et al., Dissolved, labile and total particulate trace metal dynamics on the northeast Greenland Shelf, Global Biogeochemical Cycles, (2022) Kittu L. R. et al., Coastal N2 fixation rates coincide spatially with N loss in the Humboldt Upwelling System off Peru, Global Biogeochemical Cycles, (2023) Stuart-Lee A. E. et al., Influence of glacier type on bloom phenology in two southwest Greenland fjords, Estuarine, Coastal and Shelf Science, (2023) Zhu K. et al., Influence of Changes in pH and Temperature on the Distribution of Apparent Iron Solubility in the Oceans, Global Biogeochemical Cycles, (2023) Oliver H. et al., Greenland Subglacial Discharge as a Driver of Hotspots of Increasing Coastal Chlorophyll Since the Early 2000s, Geophysical Research Letters, (2023) Meire L. et al., Glacier retreat alters downstream fjord ecosystem structure and function in Greenland, Nature Geoscience, (2023) Krause J. et al., Glacier‐derived particles as a regional control on marine dissolved Pb concentrations, J. Geophys. Res. Biogeosciences (2023) Vonnahme T. et al., Impact of winter freshwater from tidewater glaciers on fjords in Svalbard and Greenland; A review, Progress in Oceanography (2023) Liu T. et al., Trace metal (Cd, Cu, Pb and Zn) fluxes from the Congo River into the South Atlantic Ocean are supplemented by atmospheric inputs, Geophysical Research Letters, (2023) Gu, Y. et al., Spatial and temporal variations in the micronutrient Fe across the Peruvian shelf from 1984-2017, Progress in Oceanography (2024) 搜索 复制 加入团队 岗位职责：协助外国教授建立化学实验室并进行日常运行管理和维护。日常工作包括保持化学试剂采购、协助购置新实验设备、组织施行常规实验室工作培训、协助进行常规样本分析、协调学生的实验室使用、组织样本和设备的全球运输等。课题组将主要着眼于海岸海洋学（营养物质、金属和有机化合物分析），并与南方科技大学化学海洋学方向的其他成员密切合作。基于申请者的背景，本职位将在未来提供一些可能的职业发展机会，例如，国外出差（参与大西洋或太平洋科研航次）、参与科研论文发表、及/或为课题组/海洋科学与工程系编写宣传材料等。 岗位要求： 取得化学、生物、海洋学、海洋科学或环境科学方向的学士学位。持有硕士或以上的相关专业学位，或者具有专业的工作经验的申请人优先。 英语口语流畅沟通的能力。汉语书面和口语交流能力较高。有在国外工作或学习的经验者优先。 有责任心，工作勤奋积极，较强的团队精神和独立的工作能力。 查看更多 联系我们 联系地址 南方科技大学工学院南楼406 办公电话 电子邮箱 mark@sustech.edu.cn