一、论坛简介 I. Introduction to the Forum华东师范大学青年科学家（学者）国际论坛（生态与环境分论坛）是生态与环境科学学院在学校统一部署下开展的，旨在为海内外高层次优秀青年学者搭建一个学术交流的平台。分论坛通过专题报告和学术研讨，围绕国际学术前沿，探讨学科热点问题，促进学术交流与合作。本次论坛将采用线上视频方式于2021年4月9日-11日举办。The International Forum of Young Scientists (Scholars) (Sub-Forum for Ecology and Environmental Science) is regularly organized by the School of Ecological and Environmental Sciences (SEES), East China Normal University. This sub-forum provides an academic platform for exchanging research progresses and ideas among outstanding young scientists, focusing on the hotspot issues of science and technology in ecology and environmental science. Based on the applications, we will invite young scientists to present speeches on the forum. The forum of this year will be hosted online from April 9 to 11, 2021.二、论坛举办主题和日程安排II. Theme and schedule of the Forum领域与方向：生态与进化、环境科学与工程以及相关领域和方向。日程安排：论坛拟定于2021年4月9日-11日召开，详细日程另行通知。Fields and disciplines: Ecology and evolution, Environmental science and engineering, and related fields.Schedule: The forum is planned to be held from April 9 to 11, 2021. The detailed agenda of the forum will be announced later.三、 报名条件 III. Registration conditions青年科学家（学者）：年龄一般在40周岁以下，具有海内外知名高校、研究机构博士学位，在所从事的学科前沿领域取得突出的学术成果，并具有重要影响力。Young scientists should be aged below 40, with a PhD degree from a prestigious Chinese or foreign university or research institution, and have made outstanding academic achievements in ecology, environmental science and technology. 四、报名方式IV. Registration information即日起，有意参加论坛的优秀人才可在华东师范大学人才招聘平台—青年论坛—报名中进行注册申请，平台网址：http://www. jobs.ecnu.edu.cn。From now on, applicants can register it online in our website (http://: www.jobs.ecnu.edu.cn). 报名申请截止时间：2021年3月25日Deadline for online application: March 25, 2021.生态与环境科学学院将根据申请情况邀请部分青年科学家参加本次线上论坛。SEES will invite some of the young scientists to attend the online forum.五、联系方式V. Contact information（1）华东师范大学人事处人才引进办公室Recruitment Office at the Personnel Department of ECNU电话：+86-21- 34756886；Telephone: +86-21- 34756886联系人：王老师；Contact: Mr. Wang (cwang@bio.ecnu.edu.cn)（2）生态与环境科学学院School of Ecological and Environmental Sciences联系人：宋老师，联系电话：021-54341162，联系邮箱：rczp@des.ecnu.edu.cnContact: Ms. Song, Tel: 021-54341162, Email: rczp@des.ecnu.edu.cn.附：学校及学院简介Attached: A Brief Introduction to the School and the University华东师范大学坐落于上海，是国家“211工程”和“985工程”重点建设大学。2017年学校进入国家世界一流大学建设A类高校行列。学校始终秉承“智慧的创获，品性的陶熔，民族和社会的发展”这一崇高大学理念，恪守“求实创造，为人师表”的校训精神，正全面开启“扎根中国大地，建设一流大学”的新征程！East China Normal University (ECNU) in Shanghai is one of the most prestigious universities in China and is sponsored by the national programs “Project 211” and “Project 985.” In 2017, the university achieved the ranks of first-class universities in China to build A-class universities. The university always adheres to the noble university philosophy of "Creativity, Character, Community" and the motto spirit of "Pursue what we have not been taught, and practice what we are going to teach".生态与环境科学学院成立于2014年，其前身环境科学系创办于1986年，是在环境科学研究所（创建于1978年）的基础上组建而成。学院拥有一级学科博士点2个（生态学、环境科学与工程），博士后流动站2个（生态学、环境科学与工程），本科专业3个（生态学、环境科学、环境生态工程）。学科发展效果显著，其中生态学科是上海市重点学科、国家重点学科，2017年教育部指定建设一流学科，生态学、环境科学与工程均入选上海市高峰学科（IV类），环境科学与生态学进入ESI全球排名前0.3%，环境科学专业、生态学专业分别在2019年、2020年获批国家级一流专业建设。学院建设有浙江天童森林生态系统国家野外科学观测研究站、上海市城市化生态过程与生态恢复重点实验室两个重点研究基地，上海有机固废生物转化工程技术研究中心和上海市教委实验教学示范中心（生态与环境实验教学中心），共建自然资源部大都市区生态空间修复工程技术创新中心、上海城市困难立地绿化工程技术研究中心、长江口三角洲河口湿地生态系统教育部/上海市野外科学观测研究站、普陀山森林生态系统定位观测研究站。经过30多年的建设，学院形成了以学科相融合为特色的生态—环境—工程学科群。The School of Ecological and Environmental Sciences (SEES) was established in 2014. It stems from the creation of the Institute of Environmental Science in 1978 and the later foundation of the Department of Environmental Science in 1986 by East China Normal University (ECNU). The SEES has built up a complete educational and training system for bachelor, master, and doctoral students in the fields of Ecology, Environmental Science, and Environmental Engineering. It currently has 2 doctoral programs (Ecology, Environmental Science and Engineering), 2 post-doctoral stations (Ecology, Environmental Science and Engineering) and 3 undergraduate majors (Ecology, Environmental Science, Environmental Eco-Engineering). SEES has made remarkable progresses in the development of academic discipline. In 2017, Ecology, the key discipline of the State and Shanghai, was appointed by the Ministry of Education of China to construct the first-class discipline of the world. Both Ecology and Environmental Science & Engineering are approved as the Peak Disciplines by the Education Commission of Shanghai. Environmental Science and Ecology were ranked at the top of 0.3% in the ESI global-ranking system. Environmental Science and Ecology were approved for National First-Class Professional Construction in 2019 and 2020. The SEES has established several key research bases, including Zhejiang Tiantong National Forest Ecosystem Observation and Research Station, the Shanghai Key Lab for Urban Ecological Processes and Eco-Restoration (SHUES), Shanghai Engineering and Technology Research Center for Organic Solid Waste Biotransformation, and Experimental Teaching Demonstration Center of Shanghai Education Commission (Ecological and Environmental Experimental Teaching Center), as well as Yangtze River Estuary Wetland Ecosystem Research Station of Ministry of Education and Shanghai City, Land and Resources Technology Innovation Center for Ecological Space Restoration Engineering in the Metropolitan Area, Shanghai Urban Difficult Site Greening Engineering Technology Research Center, and the Putuo Forest Ecosystem Research Station of Zhoushan Archipelago. The SEES is characterized by the cluster of Ecology, Environmental science, and Environmental Engineering after more than 30 years of development.华东师范大学网站：http://www.ecnu.edu.cn/生态与环境科学学院网站：http://www.sees.ecnu.edu.cn/East China Normal University website: http://www.ecnu.edu.cn/School of Ecological and Environmental Sciences website: http://www.sees.ecnu.edu.cn/华东师范大学生态与环境科学学院2021年3月School of Ecological and Environmental SciencesEast China Normal UniversityMarch 2021

【写在前面的话】故事从校园常见的一种植物来说起吧~下面这个植物，俗名“马褂木”，学名鹅掌楸。鹅掌楸 (Liriodendron chinense)[照片来自网络. 侵删]而它还有个兄弟，叫北美鹅掌楸。同属的它们，前者仅分布在中国，而后者仅分布在北美东部，是典型的东亚-北美间断分布属植物。北美鹅掌楸 (Liriodendron tulipifera)[照片来自网络. 侵删]达尔文在给Asa Gray的一封信中，写道：“没有什么比东亚与北美东部之间的区系相似性大于北美东部与北美西部区系相似性这一现象更令我惊讶”。"Nothing has surprised me more than the greater generic & specific affinity with E. Asia than with W. America. Can you tell me (& I will promise to inflict no other question) whether climate explains this greater affinity? or it is one of the many utterly inexplicable problems in Bot. Geography? Is E. Asia nearly as well known as West America? so that does the state of knowledge allow a pretty fair comparison?"https://www.darwinproject.ac.uk/letter/DCP-LETT-1973.xml东亚-北美间断分布属植物一共有52个属。看看它们的照片，是不是长得很像？[照片来自网络. 侵删]尽管这些属在数百万年以前已形成间断分布，目前仅分布在东亚和北美东部，且在属的水平保留着相似且保守的气候生态位，但在当前与未来气候变化背景下，由于北美和东亚两个地区在气候变化、人类干扰强度等的差异，这些间断分布的物种未来的命运如何呢？【正文】为了比较东亚-北美间断分布属植物物种灭绝风险的区域差异，本研究以东亚-北美52个间断分布属的554个植物物种为研究对象，利用物种分布模型评估和比较在本世纪末不同二氧化碳排放场景下(RCP2.6和RCP8.5)气候和土地覆盖变化对这些物种灭绝风险的影响。研究结果表明，在本世纪末RCP8.5情景下，东亚和北美东部分别有49%和39%的间断分布属物种将面临灭绝风险。无论是否考虑物种的迁移，东亚地区具有灭绝风险的物种数量和比例都高于北美东部，而且区域灭绝风险的差异在低排放场景下(RCP2.6)更加明显(图1)。在属水平上也得到相似的结论(图2)。值得注意的是，在RCP8.5情景下，本研究预测分别有19个 (不考虑迁移)和 13个(考虑迁移)物种将在东亚地区发生区域灭绝。图1. 在RCP2.6和RCP8.5情景下，东亚和北美东部丧失大于30%、50%和80%当前适宜生境的物种比例和物种数。左列和右列是分别不考虑和考率物种迁移的情况下。图2. 在考虑物种迁移的情况下，属水平上间断分布属灭绝风险在东亚和北美东部地区的比较。系统发育树末端为属名，属名后括号的数字分别表示东亚(内部)和北美东部(外部)该属的物种数。饼图中的颜色表示不同适宜生境变化范围内的物种数占总物种数的百分比，内、外饼图分别为东亚和北美东部。研究发现，相比于北美东部，东亚地区具有更多小分布范围的间断分布属物种(更多的属分布在1:1线的下面，图3 a-c)。从适宜生境丧失来看，东亚地区间断分布属适宜生境的丧失也大于北美地区(图3 d-e)。此外，两个地区的物种适宜生境的丧失均随物种当前分布范围的增加而降低(图4)，说明分布范围小的物种更容易灭绝。图3. 东亚-北美间断分布属当前分布范围(a)、未来分布范围(b-c)和适宜生境丧失(d-e)之间的关系。图4. 在RCP2.6和RCP8.5情景下，物种适宜生境丧失与物种当前分布范围之间的关系。左列和右列分别是东亚和北美东部。对影响这些灭绝风险的环境因子的比较发现，驱动间断分布属物种灭绝风险的主要环境变量在两个大陆区域存在差异。在东亚，物种的灭绝风险主要受到年温度范围的变化和农田扩张的影响，而年降水是影响北美东部物种灭绝的主要因素。综上所述，东亚地区更强的气候和土地覆盖变化以及更多狭域分布的物种，导致这些间断分布属的物种在东亚地区具有更高的灭绝风险。本研究结果强调了不同区域环境变化的差异可能会导致具有相似生态位的物种具有不同的灭绝风险，在当前的和未来的气候变化与人类活动影响下，将面临完全不同的命运。全文链接：http://dx.doi.org/10.1111/gcb.15525Song, H., Ordonez, A., Svenning, J-C., Qian, H., Yin, X., Mao, L., Deng, T. and Zhang, J. Regional disparity in extinction risk: comparison of disjunct plant genera between eastern Asia and eastern North America. Global Change Biology in press doi:10.1111/gcb.15525作者：宋厚娟

主讲人：刘佳佳（青年研究员）  开始时间：3月12日 13：30主持人：张健讲座地点：资环楼148会议室主办单位：生态与环境科学学院、科技处 内容摘要： 自进入人类世以来，人类活动对当前生物多样性格局产生了巨大影响。因此，揭示人类主导景观中的生物多样性丧失机制需要考虑人类活动的间接影响。报告将聚焦人类活动及其导致的景观片段化格局对我国植物多样性的影响，望能给观众一些启发。 报告人简介： 刘佳佳，复旦大学青年研究员。2014年于中国科学院西双版纳热带植物园获博士学位，2015-2019年在浙江大学从事博士后研究，2019年至今在复旦大学工作。现任英国生态学会Ecological Solutions and Evidence杂志Associate Editor，Forestry杂志编委。主要从事生境片段化、植物地理学及生物多样性保护方面的工作，主持国家自然科学基金面上项目、青年基金和国际(地区)合作与交流项目各一项。发表SCI收录论文20余篇，其中一作论文11篇，含Trends in Ecology and Evolution, Frontiers in Ecology and the Environment, Biological Reviews, Journal of Ecology等杂志论文。

3月初，宁波还未真正回暖，浙江天童森林生态系统国家野外科学观测研究站的助理研究员江山顶着林间的寒风出门了。“我们每月观测单位面积树木凋落物的数量，由此估算整个森林凋落物的总量，从中了解森林生态系统物质循环情况，这是我们进行‘近自然森林抚育’的一种研究方式。”“‘近自然森林抚育’是一种有别于传统森林抚育方式的全新做法，是以原生森林植被为参照，培育和经营森林。起到提高森林物种多样性，提升林木质量的作用，使森林得到高质量发展。”华东师范大学天童国家生态站工程师杨庆松博士介绍，传统森林抚育主要做法是割灌除草，就是单纯地把林区五公分以下的树木砍掉，像给森林做一次简单粗暴的“大扫除”。而这种做法造成的直接后果就是林下有价值的树种和可更新的幼苗被全部清除，林间的大型树木被不分优劣地全部保留。“这不仅没给林木留下可持续生长的空间，更是把植被的更新换代的过程全部打断。”杨庆松说，宁波市森林覆盖率48%，乔木林森林蓄积量每公顷70立方米，这两项数据均低于全省平均水平，对森林进行科学抚育至关重要。在杨庆松的带领下，记者来到了天童林场的中德林业合作营林示范样点，这里成片的常绿树种参天屹立，遒劲挺拔。尽管森林郁郁葱葱，但明媚的日光依旧能从树木高耸的枝头投射下来，为草本层的树木幼苗提供成长的能量。杨庆松指着眼前这片经过近自然经营抚育的林区对记者说，他们选中林木质量出色的个体作为“目标树”，并对它周围产生干扰的个体进行清除，这既能集中地力促进“目标树”更好地生长，又能腾出更多的林下空间，让树木幼苗得以持续更新。这样做最大的好处在于，森林植被可以在自然条件下优中选优，有效提升了植被的质量和多样性。科研人员发现，自2017年，宁波市正式开始近自然森林抚育至今，天童林场近自然经营示范点中珍贵树种幼苗的种类不断更新，数量达到此前的三倍。“这片林子的树木生长速率相比未经营区域，在这两年多时间里提升了20%，这是十分惊人的！”杨庆松笑着说。不仅如此，科研人员还在林下人工抚育出珍贵物种的幼苗，“这里有栲树、石栎、小叶栎和苦槠，后期我们会把这些苗移栽到植物种类比较缺乏的林窗下，让森林的树木种类更新起来。”科研人员们表示，有了对山林的科学规划，他们就能有效弥补森林在结构上、种类上的各种先天不足，使之高质量发展。浙江天童森林生态系统国家野外科学观测研究站是中国常绿阔叶林研究领域最为重要的科研基地之一，2018年7月，“宁波市近自然林研究中心”挂牌成立，为周边省区市提供了近自然林研究的出色科研样板。截至目前，科研人员共设立了奉化区亭下水库林场、宁波市林场（四明山）、鄞州区天童林场、慈溪市林场等4个示范林样点，示范样地总计22块。“现在，我市近自然林抚育的成果正逐步显现，森林蓄积量年增长率已达到6%以上。”宁波市自然资源和规划局国土绿化处一级主任科员杨文忠表示，近自然林抚育经营是一项长期的工作任务，2021年，浙江省林业部门将启动实施千万亩森林质量精准提升工程，特别针对近自然林抚育经营等工作，提出了提高森林的生态效益和碳汇能力的主要任务。“我们会通过目标树的经营和近自然森林抚育等工作，完成这项任务。”杨文忠说。记者：缪靖 袁蓟涛 通讯员：朱宁溪编辑：张文茜

为更好地推动浙江天童森林生态系统国家野外科学研究站学科建设和科学研究，鼓励台站科研人员共同支持台站发展，现设置我站2021年度主任基金，具体要求如下：一、申报条件及要求 1.     本年度重点资助领域为森林生物多样性维持机制和森林生态系统关键过程两个方向。2.     基金资助额度为2~4万元/项，执行时间为2021年4月至2022年12月。3.     本基金面向我站教学科研、专职科研和技术支撑人员，优先资助40周岁以下人员，申请者应具备良好的、与重点资助领域有关的研究基础，每位申请人只能申报一项。4.     凡经本基金资助的项目，取得的成果应署名“浙江天童森林生态系统国家野外科学观测研究站（ZhejiangTiantong Forest Ecosystem National Observation and Research Station）”，并标注“中央高校基本科研业务费专项资金资助”（supported by”theFundamental Research Funds for the Central Universities”）。二、申报程序及要求 1.     申请人填写华东师范大学科研创新基金项目申请书（见附件），纸质版一式三份随同申请书电子版提交至本站学术秘书处（姚芳芳，电话：021-54341126；邮箱：ffyao@des.ecnu.edu.cn；办公室：资环楼211室）。2.     申请截止日期为2021年3月31日。3.     台站负责人将组织评审确定基金资助项目。附件. 华东师范大学科研创新基金项目申请书.doc 华东师范大学浙江天童森林生态系统国家野外科学观测研究站2021年3月8日

NO.AuthorsTitle Journal 1Cui EQ, Weng ES,  Yan ER,  Xia JY*Robust leaf trait relationships across species under global environmental changes.pdf Nature Communications, 2020, 11: 29992Xia JY*, Wang J, Niu SLResearch challenges and opportunities for using big data in global change biology.pdf Globa Change Biology, 2020, 26: 6040–60613Hu ZH, Chen HYH, Yue C, Gong XY, Shao JJ, Zhou GY, Wang JW, Wang MH, Xia JY, Li YT*, Zhou XH*, Michaletz STTraits mediate drought effects on wood carbon fluxes.pdf Globa Change Biology, 2020, 26: 3429-34424Tan LS, Ge ZM*, Zhou XH*, Li SH, Li XZ, Tang JWConversion of coastal wetlands, riparian wetlands, and peatlands increases greenhouse gas emissions: A global meta‐analysis.pdf Globa Change Biology, 2020, 26: 1638-16535He D, Biswas SR, Xu MS, Yang TH, You WH, Yan ER*The importance of intraspecific trait variability in promoting functional niche dimensionality.pdf Ecography, 2020, 43: 1-11doi: 10.1111/ecog.052546He M, Zhou GY,Yuan TF, Groenigen KJ, Shao JJ*, Zhou XH*Grazing intensity significantly changes the C:N:P stoichiometry in grassland ecosystems.pdf Global Ecology and Biogeography, 2020, 29: 355-3697Zhu C, Cui EQ,  Xia JY*Both day and night warming reduce tree growth in extremely dry soils.pdf Environmental Research Letters, 2020, 15: 0940748He YH, Cheng WX, Zhou LY, Shao JJ, Liu HY, Zhou HM, Zhu K, Zhou XH*Soil DOC release and aggregate disruption mediate rhizosphere priming effect on soil C decomposition.pdf Soil Biology and Biochemistry, 2020, 144: 1077879Su X, Su X, Yang S, Zhou G, Ni M, Wang C, Qin H, Zhou X, Deng J*Drought accelerated recalcitrant carbon loss by changing soil aggregation and microbial communities in a subtropical forest.pdf Soil Biology and Biochemistry, 2020, 148: 10789810Guo C, Cornelissen JHC, Tuo B, Ci H, Yan ER*Non-negligiblecontribution of subordinates in community-level litter decomposition: deciduoustrees in an evergreen worldJournalof Ecology, 108(4): 1713–172411He YH, Yao YX, Ji YH, Deng J, Zhou GY, Liu RQ, Shao JJ, Zhou LY, Li N, Zhou XH*, Bai SHBiochar amendment boosts photosynthesis and biomass in C3 but not C4 plants: a global synthesis.pdf Global Change Biology-Bioenergy, 2020, 12: 605-61712Qiao Y, Wang J, Liu HM, Huang K, Yang QS, Lu RL, Yan LM, Wang XH,  Xia JY*Depth-dependent soil C-N-P stoichiometry in a mature subtropical broadleaf forest.pdf Geoderma, 2020, 370: 11435713Gu XY, Zhou XQ*, Zhou J, Smaill SJ*, Clinton PWSoil respiration negatively correlated with volume gains by a young Pinus radiata clone over five months.pdf Geoderma, 2020, 361(1): 11410514Liu L, Zhang J*Decoding the secret of species coexistence: a perspective from soil fungi.pdf Science China Life Sciences, 2020, 63:169-17015Zhou LY, Hong Y, Li CH, Lu CY, He YH, Shao JJ, Sun XY, Wang CY, Liu RQ, Liu HY, Zhou GY, Zhou XH*Responses of biomass allocation to multi-factor global change: A global synthesis.pdf Agriculture, Ecosystems & Environment, 2020, 304: 10711516Su X, Su X, Yang S, Zhou G, Ni M, Wang C, Qin H, Zhou X, Deng J*Drought changed soil organic carbon composition and bacterial carbon metabolizing patterns in a subtropical evergreen forest.pdf Science of the Total Environment, 2020, 736: 13956817Cheng WY, Li Z, Yan L*Uniforming spring phenology under non-uniform climate warming across latitude in China.pdf Science of the Total Environment, 2020, https://doi.org/10.1016/ j.scitotenv.2020.14317718Xue MD, Guo ZY, Gu XY, Gao HL, Weng SM, Zhou J, Gu DG, Lu HX, Zhou XQ*Rare rather than abundant microbial communities drive the effects of long-term greenhouse cultivation on ecosystem functions in subtropical agricultural soils.pdf Science of The Total Environment, 2020, 706(1): 13600419Liu CN,  Li YY, Wang R,  Chen XY*Genetic factors are less considered than demographic characters in delisting species.pdf Biological Conservation, 2020, 251: 10879120Shen GC*, Wang XH, He FLDistance‐based methods for estimating density of non‐randomly distributed populations.pdf Ecology, 2020, 101(10): e0314321Wang R, Zhang X, Shi YS, Li YY, Wu JG, He FL, Chen XY*Habitatfragmentation changes top-down and bottom-up controls of food websEcology, 2020, 101: e0306222Sun BY, Yan LM*, Jiang M, Li XG, Han GX, Xia JYReduced magnitude and shifted seasonality of CO2 sink by experimental warming in a coastal wetland.pdf Ecology, 2020, 00(00):e03236. 10.1002 /ecy. 323623Li Z, Ahlstr¨om A, Tian F, G¨artner A, Jiang M, Xia JY*Minimum carbon uptake controls the interannual variability of ecosystem productivity in tropical evergreen forests.pdf Global and Planetary Change, 2020, 195: 10334324Du Y,  Lu RL, Xia JY*Impacts of global environmental change drivers on non-structural carbohydrates in terrestrial plants.pdf Functional Ecology, 2020, 34(8): 1525-153625Zhou GY, Zhou XH*,  Liu RQ, Du ZG, Zhou LY, Li SS, Liu HY, Shao JJ, Wang JW, Nie YY, Gao J, Wang MH, Zhang MY, Wang XH, Bai SH Soil fungi and fine root biomass mediate drought‐induced reductions in soil respiration.pdf Functional Ecology, 2020, 34(12): 2634-264326Guo C, Cornelissen JHC, Tuo B, Ci H, Yan ER*Invertebratephenology modulates the effect of the leaf economics spectrum on litterdecomposition rate across 41 subtropical woody plant speciesFunctional Ecology,  34(3): 735-74627Yang J, Lu JH, Chen Y, Yan ER, Hu JH, Wang XH, Shen GC*Large Underestimation of Intraspecific Trait Variation and Its Improvements.pdf Frontier in Plant Science, 2020, 11: 5328Shen GC*, Tan SS, Sun XY, Chen YW, Li BHExperimental Evidence for the Importance of Light on Understory Grass Communities in a Subtropical Forest.pdf Frontier in Plant Science, 2020, 11: 105129Zhu C, Xia JY*Nonlinear Increase of Vegetation Carbon Storage in Aging Forests and Its Implications for Earth System Models.pdf Journal of Advances in Modeling Earth Systems, 2020, 12:  E2020ms00230430Zheng ZM*, Lu J, Su YQ, Yang QS, Lin YH, Liu HM, Yang J, Huang H*, Wang XH*Differential effects of N and P additions on foliar stoichiometry between species and community levels in a subtropical forest in eastern China.pdf Ecological Indicators, 2020, 117: 10653731Cui EQ, Bian CY, Luo YQ, Niu SL, Wang YP,  Xia JY*Spatial variations in terrestrial net ecosystem productivity and its local indicators.pdf Biogeosciences, 2020, 17: 6237–624632Zhang PP, Zhou XH, Fu YL*, Junjiong Shao JJ,  Zhou LY, Li SS,  Zhou GY,  Hu ZH, Hu JQ, Bai SH, McDowell NGDifferential effects of drought on nonstructural carbohydrate storage in seedlings and mature trees of four species in a subtropical forest.pdf Forest Ecology and Management, 2020, 469: 11815933Wang MY, Yang J, Gao HL, Xu WS, Dong MQ, Shen GC, Xu J, Xu XL, Xue JM, Xu CY, Zhou XQ*Interspecific plant competition increases soil labile organic carbon and nitrogen contents.pdf Forest Ecology and Management, 2020, 462(15): 11799134Zhang Z, Wang XM, Liao S, Zhang JH, Li HQ*Phylogenetic reconstruction of Ficus subg. Synoecia and its allies (Moraceae), with implications on the origin of the climbing habit.pdf Taxon, 2020, 69(5): 927-94535Li QY, Hu XH, Liu DC, Ouyang A, Tong X, Wang YJ, Wang R*, Chen XYHigh diversity and strong variation in host specificity of seed parasitic acorn weevils.pdf Insect Conservation and Diversity, 2020, DOI: 10.1111/ icad.1246236Xu XN, Xia JY, Zhou XH, Yan LM*Experimental evidence for weakened tree nutrient use and resorption efficiencies under severe drought in a subtropical monsoon forest.pdf Journal of Plant Ecology, 2020, 13: 649–65637Liu L, Zhu K, Wurzburger N, Zhang J*Relationships between plant and soil microbial diversity vary across taxonomic groups and spatial scales.pdf Ecosphere, 2020, 11(1): e0299938Zhang JH, Zeng JC, Wang XM, Chen SF, Albach DC, Li HQ*A revised classification of leaf variegation types.pdf Flora, 2020, 272: 15170339Zhang XJ, Song K*, Pan YJ, Gao ZW, Pu FG, Lu JH, Shang KK, Da LJ, Ellen CResponses of leaf traits to low temperature in an evergreen oak at its upper limit.pdf Ecological Research, 2020, 35: 900-91140Wang JW, Xu TL, Sereke GW, Wang R, Li YY*Novel 28 microsatellite loci using high-throughput sequencing for an endangered species on Metasequoia glyptostroboides (Cupressaceae)8.pdf Molecular Biology Reports, 2020, 47: 2991-299641ZhangXT, Wang G, Zhang SC, Chen S,  Wang YB,Wen P, Ma XK, Shi Y, Qi R, Yang Y, Liao ZY, Lin J, Lin JS, Xu XM, Chen XQ, XuXD, Deng F, Zhao LH, Lee YL, Wang R, Chen XY, Lin YR, Pereira RAS,Zhang J, Tang HB, Chen J*, Ming R*Genomesof banyan fig and pollinator wasp provide insights into fig-wasp coevolutionCell,2020, 183: 875–88942SuYJ, Guo QH*, Hu TY……Wang XH, MaKPAnupdated vegetation map of China (1:1000000).pdf ScienceBulletin, 2020, 13: 1125–113643Li SP,Wang P*, Chen Y, Wilson MC, Yang X, Ma C, Lu J, Chen XY, Wu J, Shu WS, Jiang L*Islandbiogeography of soil bacteria and fungi: similar patterns, but differentmechanisms.pdf TheISME Journal, 2020, 14: 1886–189644HeP, Gleason SM, Wright IJ, Weng E, Liu H, Zhu S, Lu M, Luo Q, Li R, WuG, Yan ER, Song Y, Mi X, Hao G, Reich PB, Wang Y, Ellsworth DS, YeQ*Growing-seasontemperature and precipitation are independent drivers of global variation inxylem hydraulic conductivityGlobaChange Biology, 26(3): 1833–184145LembrechtsJ*, Aalto J, Ashcroft M, …, Zhang J, Zhang ZC, et alSoilTemp:a global database of near-surface temperature.pdf GlobaChange Biology, 2020, 26(11): 6616–662946Xing DL*, He FL Analyticalmodels for β-diversity and the power-law scaling of β-deviation.pdf Methodsin Ecology and Evolution, 2020;00:1–10; DOI: 10.1111/ 2041-210X.1353147KaysR*, Arbogast BS, Baker-Whatton M, Beirne C, Boone HM, Bowler M, Burneo SF, CoveMV, Ding P, Espinosa S, Gonçalves ALS, Hansen CP, Jansen PA, Kolowski JM,Knowles TW, Lima MGM, Millspaugh J, McShea WJ, Pacifici K, Parsons AW, PeaseBS, Rovero F, Santos F, Schuttler SG, Sheil D, Si X, Snider M,Spironello WRAnempirical evaluation of camera trap study design: how many, how long, and when?.pdf Methodsin Ecology and Evolutio, 2020, 11: 700–71348FengG, Zhang J*, Girardello M, Pellissier V, Svenning JCForestcanopy height co-determines taxonomic and functional richness, but notfunctional dispersion of mammals and birds globally.pdf GlobalEcology and Biogeography, 2020, 29(8): 1350–135949ZhuJ, Zhang Y*, Yang X, Chen N, Li SP, Wang P, Jiang L*Warmingalters plant phylogenetic and functional community structure.pdf Journalof Ecology, 2020, 108: 2406–241550YangC*, Si X, Liang W, Møller APSpatialvariation in egg polymorphism among cuckoo hosts across four continents.pdf CurrentZoology, 2020, 66: 477–48351QianH*, Zhang J, Sandel B, Jin YPhylogeneticstructure of angiosperm trees in local forest communities along latitudinal andelevational gradients in eastern North America.pdf Ecography,2020, 43: 419–43052WangP, Li SP, Yang X, Zhou J, Shu W*, Jiang L*Mechanismsof soil bacterial and fungal community assembly differ among and within islands.pdf EnvironmentalMicrobiology, 2020, 22: 1559–157153StuartJD*, Iveren A, Kamariah AS,…Xing DL… et al.ForestGEO:Understanding forest diversity and dynamics through a global observatory.pdf Biologicalconservation, 2020, 253: 1–2454QiaoX, Zhang J,  Wang Z,  Xu Y, Zhou T, Mi X*, Cao M, Ye W, Jin G, HaoZ, Wang X, Wang X, Tian S, Li X, Xiang W, Liu Y, Shao Y, Xu K, Sang W*,Zeng F, Ren H, Jiang M, Ellison AM*Foundationspecies across a latitudinal gradient in China.pdfEcology,2020, 00(00):e03234. 10.1002/ecy.323455ThomasK, Lucas WM, Monica H, Sascha MBK, Marcus AH, Adrian H*Recovery in methanotrophic activity does not reflect on the methane-driven interaction network after peat mining.pdf Appliedand Environmental Microbiology, 2020, doi:10.1128/ AEM.02355–2056YuR, Lyu MH, Lu JH Yang Y*, Shen GC*, Li F*Spatialcoordinates correction based on multi-Sensor low-altitude remote sensing imageregistration for monitoring forest dynamics.pdf IEEEAccess, 2020, 8: 18483–1849657WangN, Mao L, Yang X, Si X, Wang Y, Eiserhardt WL, Feng G*Highplant species richness and stable climate lead to richer but phylogeneticallyand functionally clustered avifaunas.pdf Journalof Biogeography, 2020, 47: 1945–195458ZhaoY, Dunn R, Zhou H, Si X*, Ding P*Islandarea, not isolation, drives taxonomic, phylogenetic and functional diversity ofants on land-bridge islands.pdf Journalof Biogeography, 2020, 47: 1627–163759Sascha MBK, Astrid N, Vilma OC, Ewen M, Geert JTK, Lambertus APL, Christoph CT*No tangibleeffects of field-grown cisgenic potatoes on soil microbial communities.pdf Frontiersin Bioengineering and Biotechnology, 2020, 8: 60314560LiY, Liu X, Xu W, Bongers FJ, Bao W, Chen B, Chen G, Guo K, Lai J, Lin D, Mi X,Tian X, Wang X, Yan J, Yang B, Zheng Y, Ma K*Effectsof diversity, climate and litter on soil organic carbon storage in subtropicalforests.pdf ForestEcology and Management, 2020, 476: 11857961LiuB, Biswas S, Yang J, Liu ZH, He H, Liang Y*, Lau MK, Fang YT, Han SJStronginfluences of stand age and topography on post-fire understory recovery in aChinese boreal forest.pdf ForestEcology and Management, 2020, https://doi.org/10.1016/ j.foreco.2020.11830762ZhangYB, Wu HD, Yang J, Song XY, Yang D, He FL, Zhang LJ*Environmentalfiltering and spatial processes shape the beta diversity of liana communitiesin a valley savanna in southwest China.pdf AppliedVegetation Science, 2020, 23(4): 482–49463DaiD, Ali A, Huang X, Teng MJ, Wu CG, Zhou ZX, Liu Y* Soilavailable phosphorus loss caused by periodical understory management reduceunderstory plant diversity in a northern subtropical Pinus massoniana plantation chronosequence.pdf Forests,2020, 11: 23164YanX, Diez J, Huang K, Li SP, Luo X, Xu X, Su F, Jiang L, Guo H*, Hu SBeyondresource limitation: an expanded test of the niche dimension hypothesis formultiple types of niche axes.pdf Oecologia,2020, 193: 689–69965YangX, Wang Y, Si X, Feng G*Speciestraits linked with range shifts of Chinese birds.pdf GlobalEcology and Conservation, 2020, 21: e0087466XuYG, Liu HJ, Zhang KM, Zhu SS*, Yang M*Allelopathicplants: 28. Genus Panax L..pdf AllelopathyJournal, 2020, 51(1): 21–4067HuR, Sun P, Yu H*, Cheng YF, Wang R, Chen XY*, Kjellberg FSimilitudesand differences between two closely related Ficus species in thesynthesis by the ostiole of odors attracting their host-specific pollinators: Atranscriptomic based investigation.pdf ActaOecologica, 2020, 105: 10355468ZhangZ, Liao S, Li HQ*, Zhang DS*Identificationsand typifications of Ficus pubigera var. maliformis and related names.pdf Phytotaxa,464 (1): 102–108 

序  号 作  者 论文题目 杂志名称卷、期、页 1 张健，宋坤，宋永昌* 法瑞学派的发展历史及其对当代植被生态学的影响.pdf 植物生态学报, 2020, 44(7): 699–714 2 周贵尧, 周灵燕, 邵钧炯, 周旭辉 极端干旱对陆地生态系统的影响: 进展与展望.pdf植物生态学报, 2020, 44: 515-525 3 夏建阳*, 鲁芮伶, 朱辰, 崔二乾, 杜莹, 黄昆, 孙宝玉 陆地生态系统过程对气候变暖的响应与适应.pdf植物生态学报, 2020, 05: 494-5144 李媛媛*, 刘超男, 王嵘, 罗水兴, 农寿千, 王静雯, 陈小勇 分子标记在濒危物种保护中的应用.pdf 生物多样性, 2020, 28(3): 367-3755 张首和, 曾雅雯, 何義, 陈越, 陆嘉辉, 刘何铭, 徐明杰, 王希华* 浙江天童国家森林公园常绿阔叶林凋落叶养分含量的时空分布特特征.pdf 生态学报, 2020, 20: 7335-7342 6 于文波, 黎绍鹏*基于现代物种共存理论的入侵生态学概念框架.pdf生物多样性, 2020, 28, doi:10.17520/biods.20202437 白 杨, 陈声文, 钱海源, 余顺海, 徐谊明, 张芷昕,沈 超, 陈雨奇, 张美琪, 余建平*, 朱瑞良* 钱江源国家公园叶附生苔类植物的物种多样性.pdf生物多样性, 2020, 28 (2): 231–2378 宋坤，郭雪艳，王泽英，黄莎莎，严佳瑜，叶建华，乐莺，严明，吴梅，达良俊* 上海城市近自然森林的重建动态.pdf生态学杂志, 2020, 39(4): 1075-10819 杨庆松, 刘何铭, 朱彤彤, 张首和, 王希华* 浙江天童国家森林公园常绿阔叶林种间关联和种-生境关联.pdf华东师范大学学报（自然科学版）, 2020, 03: 110-11910 罗鼎晖, 李翔, 骆蓓菁, 许洺山, 妥彬, 阎恩荣, 由文辉* 大金山岛常绿阔叶林和落叶阔叶林中小型土壤动物群落特征.pdf生态与农村环境学报, 2020, 03: 349-35711 邓杰*, 陈雪初, 黄莹莹, 张军毅蓝藻群体颗粒驱动元素地球化学循环研究进展.pdf微生物学报, 2020, 09: 1992-194012 赵琦琳, 田文斌, 郑忠,史青茹,由文辉, 阎恩荣* 浙江天童木本植物水力结构与树高的关联性.pdf生态学报, 2020, 19: 6905-691113 任刚, 李恩, 赵世烨, 江燕琼, 王莎莎, 唐思贤,* 胡慧建* 棕背伯劳羽色多态与MC1R基因的相关性.pdf生物多样性, 2020, 06: 688-69414 熊武建, 孙红梅, 刘盼盼, 冯璐, 关开朗, 廖文波*, 由文辉* 濒危植物驼峰藤的扦插繁殖及野外回归.pdf中山大学学报(自然科学版), 2020, 02: 145-15115 岳雪华, 范深厚, 杜雪柯, 胡嘉琪, 张扬, 李媛媛*巨杉健康和感病叶片表面微生物组成和多样性比较.pdf福建农林大学学报(自然科学版), 2020, 01: 10-17

如何比较不同区域的β多样性是近年来生态学中一个充满争议的话题。其中，一个广泛使用的零模型（Kraft et al., 2011, Science）由于其生态学含义不明、受样本量的影响、对个体水平数据的需求等原因，在实际应用中面临诸多限制与挑战。近日，我院邢丁亮青年研究员基于前期研究积累，构建了β多样性的理论解析模型，解决了该零模型应用中的若干关键问题，相关结果以“Analytical models for β-diversity and the power-law scaling of β-deviation”为题，发表于生态学主流期刊Methods in Ecology and Evolution 。通过构建解析模型，该研究首先阐明了相关零模型的生态学含义，即通过比较实际观测β多样性与零模型而产生的标准化效应值（βdev）度量的是“给定区域物种多度分布情况下，物种空间非随机分布格局对β多样性的影响”，正确解释βdev的生态学含义有助于澄清此前研究中的相关争议。其次，在实际应用中，βdev的计算受局域群落数量的影响，不同区域取样强度不一致时不能直接比较；理论研究发现，βdev与群落数之间呈指数为0.5的幂律关系（图1），从而提供了修正样本量影响的简单方法。最后，该理论模型扩展了原零模型的应用范围，原零模型为计算机模拟模型，需要每个物种在每个群落中的详细多度数据；新的理论模型只需要物种在群落中是否出现的信息以及整体集合群落所有物种的总多度，从而为进一步研究大尺度β多样性格局提供了方向。

2020年12月26日上午9：00，生态与环境科学学院第三十五期光华学术论坛在资环楼148举行，本期论坛由生环学院刘宇老师主持。主持人刘宇老师01|卢晓蓉 The relationship between plant and microbial diversity in three dimensions首先是来自黎绍鹏老师课题组的卢晓蓉同学，她的口头报告题目为《The relationship between plant and microbial diversity in three dimensions》。通过对亭下林场、四明山林场和育王林场的植物和微生物在类群、富集度和规律性三个维度进行比较后得出结论：细菌多样性和植物多样性显著相关，可以通过植物系统发育的多样性来预测真菌多样性。生环学院卢晓蓉同学02|刘巷序 Temporal trends between bird diversity and ecosystem services in urban green spaces of Shanghai第二位做口头报告的是来自斯幸峰老师课题组的刘巷序同学，她的报告题为《Temporal trends between bird diversity and ecosystem services in urban green spaces of Shanghai》。通过研究留鸟的多样性变化来看多种绿地生态系统服务的相关变化，发现支持类生态系统服务与留鸟关系最为密切，留鸟中的棕背伯劳、强脚树莺等鸟种可用于监测城市生态系统服务的变化。生环学院刘巷序同学03|江莎 Assessing congruence and surrogate among taxa in nature reserves in China第三位报告人是来自何芳良老师课题组的江莎同学，报告题目是《Assessing congruence and surrogate among taxa in nature reserves in China》。分享内容为：除birds-lichens、 macrofungi-retiles、macrofungi-insect外，类群与类群之间的物种丰富度是正相关的；在angiosperms和其他类群之间有中强度的正相关关系；MAP（mean annual precipitation）是一个检测物种丰富度的关键因子。生环学院江莎同学04|胡瑞 The effect climate change on seed germination and rhizosphere microbial composite of on critically endangered Abies beshanzuensis最后一位口头报告人是来自刘宇老师课题组的胡瑞同学，她的报告题为《The effect climate change on seed germination and rhizosphere microbial composite of on critically endangered Abies beshanzuensis》。介绍内容为：通过人工气候培养箱试验来探讨增温对Abies beshanzuensis萌发的潜在影响；以及不同海拔地区Abies beshanzuensis根际微生物组成。生环学院胡瑞同学05|陆金忠 Role of algal accumulations on the partitioning between N2 production and dissimilatory nitrate reduction to ammonium in eutrophic lakes论坛第二部分进展快报，第一位报告的是来自陈雪初老师课题组的陆金忠同学，他的报告题为《Role of algal accumulations on the partitioning between N2 production and dissimilatory nitrate reduction to ammonium in eutrophic lakes》。主要介绍了在富营养化的湖泊中，藻类颗粒的加入促进了DNRA速率，但不促进N2的产生；高浓度的OC是DNRA优于反硝化和厌氧氨氧化的先决条件，而这两者更依赖于NO3−水平；C/N比值与DNRA速率成正相关。生环学院陆金忠同学06|柳昭莹 A single bacterial genus maintains root growth in a complex microbiome第二位进展快报的同学是来自周小奇老师课题组的柳昭莹同学，她报告的题目是《A single bacterial genus maintains root growth in a complex microbiome》。首先分享文献《复杂微生物组中的单个细菌属维持植物根生长》，随后介绍了长期温室种植对亚热带农业土壤微生物群落结构和多样性的影响。生环学院柳昭莹同学07|高燕 Land-use intensity alters networks between biodiversity, ecosystem functions, and services第三位报告人是来自王嵘老师课题组的高燕同学，报告题目是《Land-use intensity alters networks between biodiversity, ecosystem functions, and services》。介绍了土地利用强度对生物多样性、生态系统功能和服务改变的程度。生环学院高燕同学08|赛碧乐 Animal body size distribution influences the ratios of nutrients supplied to plants第四位进展快报的汇报人是来自阎恩荣老师课题组的赛碧乐同学，她的报告题为《Animal body size distribution influences the ratios of nutrients supplied to plants》。介绍了体型不同的食草动物不仅使用不同的景观，而且通过粪便释放出的氮与磷的比例也不同，这种差异会影响向植物提供的营养比例。生环学院赛碧乐同学09|池云怡 Symbiosis of a P2-family phage and deep-sea Shewanella putrefaciens第五位汇报人是来自邓杰老师课题组的池云怡同学，她报告的题目是《Symbiosis of a P2-family phage and deep-sea Shewanella putrefaciens》。介绍了一个P2噬菌体和腐败希瓦氏菌的共生关系。生环学院池云怡同学10|贾真 Global ecological predictors of the soil priming effect最后一位报告人是来自周旭辉老师课题组的贾真同学，她的报告题目是《Global ecological predictors of the soil priming effect》。介绍了表面启动效应在全球普遍存在，并受SOC含量的控制；土壤干旱度高、担子菌相对丰度高、植被盖度低、土壤有机碳含量低、土壤基础微生物呼吸速率低的土壤，土壤启动效应明显。在世界范围内，盐渍化是土壤表层表层效应的一个重要的负驱动因素。生环学院贾真同学各位同学汇报结束后，刘宇老师组织现场投票，在场同学积极参与，现场选出了卢晓蓉、赛碧乐、贾真三位同学获得第三十五期光华论坛“最佳汇报奖”。第35期光华论坛“最佳汇报奖”获得者文：汤繁 图：庞育兰 来源：生态与环境科学学院

2020年11月28日上午，生态与环境科学学院第三十三期光华学术论坛在资环楼148举行，本期论坛由生环学院黎绍鹏老师主持。主持人黎绍鹏老师01 |王攀登Biogeography of nitrogen-cycling related genes and microbes in Pearl River Estuary首先是来自中山大学生态学院博士后王攀登老师为大家作的题为《Biogeography of nitrogen-cycling related genes and microbes in Pearl River Estuary》的口头报告。分享的内容是珠江河口中氮循环功能基因和微生物的空间分布格局，得出珠江河口沉积物中具有极其高的微生物物种的多样性；氨氮是影响微生物多样性的主导因素；珠江河口沉积物中参与反硝化和亚硝酸盐异化还原为铵过程的功能基因的多样性和丰度较其它氮循环功能基因高；氮循环功能基因的多样性和丰度的空间分布格局不一致；反硝化过程和亚硝酸盐异化还原为铵过程具有较高的功能冗余的结论。中山大学王攀登老师02 |赵郁豪Ant diversity and community structure on fragmented habitat islands第二位是生环学院的赵郁豪博士，他的口头报告题目为《Ant diversity and community structure on fragmented habitat islands》。该报告研究了零碎生境岛屿蚂蚁多样性与群落结构情况。生环学院赵郁豪同学03 |朱辰Nonlinear increase of vegetation carbon storage in aging forests and its implications for Earth system models第三位报告人是来自夏建阳老师课题组的朱辰博士，报告题目为《Nonlinear increase of vegetation carbon storage in aging forests and its implications for Earth system models》。研究了老龄林植被碳储量的非线性增长及其对地球系统模型的影响。生环学院朱辰同学04 |李倩雅High diversity and strong variation in host specificity of seed parasitic acorn weevils第四位口头报告人是来自陈小勇老师课题组的李倩雅同学，她的报告题为《High diversity and strong variation in host specificity of seed parasitic acorn weevils》。通过研究种子寄生昆虫橡实象甲的多样性，得出二斑栗实象(C. bimaculatus) 是该区域中最优势的OTU；该区域中鉴定出的Curculio OTUs具有不同的寄主特异性，且差异较大；绝大多数Curculio OTUs的寄主特异性较高；多数Curculio OTUs偏好攻击同属或近缘属的植物物种的结论。生环学院李倩雅同学现场气氛活跃，同学们集思广益，头脑风暴，踊跃提问。05 |姚怡先The effects of biochar and nitrogen amendment on soil greenhouse gas fluxes and its underlying mechanism论坛第二部分第一位口头报告的汇报人是来自伏玉玲老师课题组的姚怡先同学，汇报题为《The effects of biochar and nitrogen amendment on soil greenhouse gas fluxes and its underlying mechanism》，分享了生物炭和氮素改良剂对土壤温室气体通量的影响及其机理研究。生环学院姚怡先同学06 |顾志壮Woody litter protects peat carbon stocks during drought本次论坛第一位进展快报的汇报人是来自周旭辉老师课题组的顾志壮同学，他的汇报题为《Woody litter protects peat carbon stocks during drought》。说明了泥炭地中木材的补充可以激发其抗旱机制森林碳捕获与泥炭地存储相结合，可以改善宿主生态系统土壤碳储量的保护。生环学院顾志壮同学07 |左涵灵A comprehensive quantification of global nitrous oxide sources and sinks第二位进展快报的汇报人是来自周小奇老师课题组的左寒灵同学，汇报题为《A comprehensive quantification of global nitrous oxide sources and sinks》，分享了全球氧化亚氮源汇的综合量化。生环学院左涵灵同学08 |舒丽Assemblage time series reveal biodiversity change but not systematic loss第三位进展快报的汇报人是来自张健老师课题组的舒丽同学，汇报题为《Assemblage time series reveal biodiversity change but not systematic loss》，讲述了集合时间序列揭示了生物多样性的变化，而不是系统性的损失。生环学院舒丽同学09 |杨柏钰 The interspecific growth–mortality trade-off is not a general framework for tropical forest community structure论坛第二部分最后一位进展快报的汇报人是来自阎恩荣老师课题组的杨铂钰同学，汇报题为《 The interspecific growth–mortality trade-off is not a general framework for tropical forest community structure》，阐述了种间生长与死亡的权衡并不是热带森林群落结构的一般框架。生环学院杨柏钰同学各位同学的汇报结束后，主持人黎绍鹏老师组织现场投票，在场同学积极参与，现场选出了赵郁豪、杨铂钰、左涵灵三位同学获得第三十三期光华学术论坛“最佳汇报奖”。第33期光华论坛“最佳汇报奖”获得者最后，老师与同学们合影留念庆祝本期光华论坛顺利举行。文：郗家瑞图：邹宏硕 来源：生态与环境科学学院

讲座题目： Hybridizing Mechanism and MaxEnt: Ecological Theory for the Anthropocene主讲人：John Harte（教授）开始时间：11月26日上午10：30讲座地点：腾讯会议（或VooV Meeting）, ID：848 818 218主办单位：生态与环境科学学院、科技处报告人简介： John Harte is a Professor of the Graduate School of University of California, Berkeley, America. He received a BA in physics from Harvard University in 1961 and a PhD in theoretical physics from the University of Wisconsin in 1965. He was an NSF Postdoctoral Fellow at CERN, Geneva, during 1965–66 and a Postdoctoral Fellow at the University of California, Lawrence Berkeley Laboratory, during 1966–68. During the next 5 years, he was an Assistant Professor of Physics at Yale University and has been at Berkeley since 1973. He has served on six National Academy of Sciences Committees and has authored over 200 scientific publications, including eight books.Harte’s research focuses on the effects of human actions on, and the linkages among, biogeochemical processes, ecosystem structure and function, biodiversity, and climate. His work spans a range of scales from plot to landscape to global and utilizes field investigations, mathematical modeling, and theory development. Two themes, feedback and scaling, weave through much of his research.报告内容简介: At the frontier of research in many fields, from ecology to economics, many of the most exciting problems today have to do with “complex systems”. These are systems characterized by feedbacks, nonlinearities, and a myriad of non-identical subunits, that are resistant to traditional reductionist methods of scientific investigation. Using ecology as an example, I show how a mathematical method based on information theory provides a promising foundation for constructing complex systems theory. Ecosystems display pervasive patterns in 1. the scaling of species richness with area, 2. the distributions of abundance across species, 3. The distribution of individuals within species over space, 4. the distribution of metabolic rates or body sizes across individuals, 5. the relationship between size and abundance, 6. the distribution of species richness across higher taxonomic categories, and 7. the distribution of edges across nodes in trophic networks. A theory of ecology based on the maximum entropy principle, predicts all these patterns remarkably accurately in relatively static ecosystems but the theory fails in ecosystems that are responding to anthropogenic stresses, or are undergoing rapid diversification or succession. Hybridizing mechanism with MaxEnt, however, results in a theory capable of describing dynamic ecosystems that are changing in response to disturbance. I conclude that complexity science in the decades ahead may have its roots in information theory.