中国微米纳米技术学会第十三届学术年会.doc

中国微米纳米技术学会 CSMNT 中国微米纳米技术学会年会展位招商方案中国微米纳米技术学会第十三届学术年会13th Annual Conference of the Chinese Society of Micro-Nano Technology主办单位中国微米纳米技术学会承办单位常州大学 南京师范大学 苏州大学 江苏大学展览承办 上海卓格展览服务有限公司协办单位教育部 科技部 总装备部 国家自然科学基金委员会 工业与信息化部 中国科学技术协会会议时间 2011年9月28至30日会议地点 中国 常州会议背景： 从1994年起到学会成立，在科技部、教育部、国家自然科学基金委、总装备部（原国防科工委）的关心和支持下，已经召开了六次中国微米纳米学术年会。会议范围和规模稳步提高，也标志着我国微米纳米技术研究的规模和水平逐步提高。针对这种情况，经2006年学会常务理事会讨论，决定中国微米纳米学术年会改为每年举行。经2007年常务理事会讨论，学术年会由国内会议改为单数年举办国内会议，双数年举办国际会议，同时决定，为了保证会议论文和会议举办质量，在一定时期内，会议将稳定在一定规模。（1）2005年学术年会在大连召开，大连理工大学承办；（2）2006年学术年会在南京召开，东南大学和电子55所承办；（3）2007年学术年会在上海召开，科学院上海微系统所和上海交通大学承办； （4）2008年学术年会在北京召开，为第一次国际会议，清华大学承办；（5）2009年在哈尔滨召开，哈尔滨工业大学、黑龙江大学和中电49所承办。由教育部、科技部、总装备部、国家自然科学基金委员会、中国科学技术协会和国家纳米科学中心、精密测试技术及仪器国家重点实验室等协办的中国微米纳米技术学会第十一届学术年会在哈尔滨凯莱花园大酒店举行。参加此次会议的有中国科协书记处书记冯长根教授、国家自然基金委工程与材料学部主任黎明研究员、哈尔滨工业大学校长王树国教授、大会副主席解思深院士、学术委员会主席王立鼎院士、徐志磊院士、哈尔滨工业大学副校长韩杰才教授、大会组织委员会副主席周兆英教授、中国微米纳米技术学会副理事长兼秘书长、清华大学机械工程学院院长尤政教授、中国电子科技集团公司49所副所长吴亚林研究员、哈尔滨工业大学MEMS中心主任刘晓为教授，以及国内专家学者、科技人员、学生代表等，共300余人。（6）2010年在西安召开，西北工业大学承办。此次学术学会年会，共收集了学术论文300余篇，论文内容涉及微米纳米技术在机械、生物、医学领域的研究成果。经过专家组评审，共有84篇论文在大会上进行学术报告，105篇论文做展板展示，会议共有多家参展商参与展览。参加此次年会的有王立鼎院士、徐志磊院士、田昭武院士、国家自然基金委工程材料学部副主任黎明研究员、西北工业大学苑伟政教授、大会组织委员会副主席清华大学周兆英教授，中国微米纳米技术学会副理事长、清华大学机械工程学院院长尤政教授，以及国内专家学者、科技人员、学生代表等汇聚一堂进行学术交流。 在前几年的优势背景下，学会将于2011年9月28至30日，在常州举办中国微米纳米技术学会第十三届学术年会。年会将邀请4-5位学者在微纳米技术领域的知名学者做特邀报告。特邀不超过20名知名学者做有关专题的邀请报告。参会人员在300人至400人之间，均来自国内外各大院校及学术科研单位。此外，年会将为中国微米纳米学术界交流提供良好的平台，促进企业沟通及宣传，为企业提供与一线微纳米行业工作者接触的机会，帮助企业了解微纳米行业发展趋势以及行业需求。在年会举办时，企业会员可以在会场外设立展位，宣传自己的产品，树立本单位的企业形象，同时结交行业内的科研技术人员，为本单位的技术发展打下良好的基础。附件一：赞助单位费用条款附件二：十二届学术年会特邀学术报告和报告人简历附件一：赞助单位费用条款基础赞助（必须选择）：赞助费为10000元（学会单位会员的赞助费为7000元）包括：l 免赞助单位一位工作人员的会议注册费；l 2m2m标准展位一个；l 在会议代表的资料包中放赞助单位的资料；l 安排在相关主题的分会上做一个学术报告（报告内容需事先经学会秘书处审核）。其它赞助项目：1. 中英文入场引导牌广告1.1只选取一家赞助单位2. 企业举办专题讲座3. 全体大会主席台背景板及程序册封面注明赞助单位名称4. 全体大会主席台两边立式广告/会场内条幅5. 程序册封二彩色广告5.1只选取一家赞助单位6. 程序册封三彩色广告6.1只选取一家赞助单位7. 程序册封底彩色广告7.1只选取一家赞助单位8. 程序册插页彩色广告9. 胸牌广告9.1 在每位代表的胸牌上印赞助单位名称9.2只选取一家赞助单位10. 赞助单位在全体大会上做20分钟学术报告10.1报告内容需事先经学会审核10.2只选取一家赞助单位10.3再免赞助单位一位工作人员的会议注册费10.4全体大会主席台背景板注明赞助单位名称10.5程序册封面注明赞助单位名称10.6 程序册插页彩色广告10.7 学会官方网站全年广告位置宣传11. 茶歇赞助11.1在相关主题分会茶歇台上放置赞助单位广告11.2每个主题分会茶歇每次只选取一家赞助单位12. 自助餐赞助12.1在自助餐就餐地点放置赞助单位广告12.2每次自助餐只选取两家赞助单位13. 晚宴赞助13.1晚宴主持人鸣谢赞助方13.2赞助方负责人发言，不超过10分钟13.3晚宴主席台两边广告13.4只选取一家赞助单位13.5学会官方网站半年广告位置宣传14. 知名专家礼品（30份以内，每份价格不低于200元）14.1礼品由赞助方自行购买14.2只选取一家赞助单位。15. 赞助单位增加在分会上的学术报告15.1报告内容需事先经学会审核16. 会议资料袋（400份）16.1会议资料袋由赞助方购买制作16.2会议资料袋上的图案设计需事先经学会审核16.3只选取一家赞助单位3000元5000元/45分钟2000元3000元5000元5000元8000元3000元/版5000元20000元1000元/个次1500元/次10000元1000元5000元/个3000元说明：1. 所有广告、展板由赞助单位自行设计、制作，学会提供基色模板。2. 只选取一家或两家赞助单位的赞助项目都以“先申请，先安排”为原则。3. 如欲采用未在上面标注的赞助方式，请与我们联系。4. 学会网站广告刊例，请见学会官方网站联系方式上海卓格展览服务有限公司地 址：上海市薀川路1623弄柏丽华庭9-304室邮 编：201901电 话56436721传 真mail：网 站：附件二：十二届学术年会特邀学术报告和报告人简历l BioMEMS for eye care Abstract: As micro/nano technologies continue to mature, there are many new opportunities for miniature biomedical devices. Among them, one exciting research area of current development is microimplant. This talk will first cover our years of work on MEMS neural implants for retinal/cortical/spinal applications. Neurons, once severely damaged, do not repair or regenerate themselves, leaving permanent debilitating deficits for tens of millions of people worldwide. As our society is facing more severe population aging problems, significant growth in neural implants is predicted. One could notice that even commercially successful neural implants still have a lot of room for improvement such as size, power and flexibility. The focus is to apply micro/nanotechnology to develop miniature, flexible and highly functional neural implants for organs with difficult constraints. In addition, other MEMS implants such as intraocular pressure sensors and Glaucoma drainage device will also be discussed. Many interesting issues related to biology, biomechanics, materials, and technology will be discussed. Dr. Yu-Chong Tai graduated from UC Berkeley with a PhD degree. Immediately, he joined the department of EE at the California Institute of Technology (Caltech). Now, he is a Professor of Electrical Engineering, Mechanical Engineering and Bioengineering. His research specialty has been MEMS, sensors and actuators. He developed the first electrically-spun polysilicon micromotor while at UC Berkeley and he joined Caltech in 1989 after PhD education. At Caltech, he built the Caltech Micromachining (or MEMS) Laboratory, which is an 8,000 sq. ft. facility completely designed for MEMS research. This facility includes a clean-room lab (3,000 sq. ft), a CAD lab, a measurement/metrology lab and a bio lab. It is currently supporting more than 20 researchers (mainly graduates and postdocs) with various MEMS research projects. Examples include microphones, micro scanning mirrors, neural chips, neural probes, micro actuators, lab-on-a-chip, etc. He had extensively worked on MEMS devices for active fluid sensing and control. Successfully developed MEMS devices include pressure sensors, shear-stress sensors, hot-wire anemometers, flexible sensor skins, magnetic actuators, rubber-balloon actuators, etc. In addition, he also has research on integrated MEMS systems such as smart surface for drag-reduction in turbulence, MEMS for delta-wing aerodynamic control, and MEMS-maneuvered unmanned aerial vehicle (UAV). Continuous to his early micro flow control research, he has had a focused research effort on microfluidics and labs-on-a-chip. He has built devices like micro channels, membrane filters, micro valves, pumps, and bioreactors for bio-medical applications. For example, he has recently developed fully integrated high-performance liquid chromatography (HPLC) on-a-chip that is of commercial quality. Since several years ago, he has started an extensive program to develop micro bio-implants. For examples, he has collaborative research program with the USC Medical School on retinal implants, with Prof. Anderson at Caltech on cortical implants, and with Prof. Edgerton at UCLA on spinal cord implants. He has published more than 300 technical articles in the field of MEMS. He is the recipient of the IBM Fellowship, Ross Tucker Award, Best Thesis Award (at Berkeley), Presidential Young Investigator (PYI) Award, Packard Award, 2002 ALA Achievement Award. He was the General co-Chairman of the 2002 IEEE MEMS Conference. He is a Fellow of IEEE and IOP.l Exploring nanopatterns and microflows for cell microenvironmental regulation and monitoring Abstract: Environmental adaptation is a characteristic of all living systems. At cell levels, the adaptation behaviour of the system is still far complicated and poorly understood. Recent investigations have repeatedly shown the high potential of using nanoengineered substrates and microfluidic devices for the regulation and monitoring of cell adhesion, proliferation and differentiation activities. On one hand, a large variety of synthetic surfaces including chemical and topographic patterns could be easily produced, allowing systematic investigations on the cellular adaptation behaviors. By using both conventional and non conventional nanofabrication techniques, we were able to produce different types of patterns and demonstrated mechanical and chemical pattern influence on cell attachment, elongation and deformation as well as stem cell renewing and controlled differentiation. On the other hand, microfluidics provides unique tools for high resolution control of soluble cell factors. Our results, as well as many others, have shown that stem cells can be cultured and differentiated into different cell types under microfluidic conditions. We also applied microfluidic devices for the study of shear stress dependent gene expression and drug effects on endothelial cells. Finally, nanofabrication and microfluidics allowed us to develop a number of new characterisation and manipulation techniques which should be relevant to the cellular engineering at single cell levels. Indeed, monitoring, understanding, and controlling the environmental adaptation of cells at single cell and tissue levels are extremely challenging but a lot of material processing technologies are now available. In this talk, we will present some examples of our recent achievements to illustrate the feasibility of performing such an investigation with a more clear research strategy. Yong Chen is Research director of CNRS and group leader at the Ecole Normale Suprieure of Paris. In the past, he has been worked on semiconductor quantum structures, photonic crystals, scanning near field optical microscopy, magnetic nanostructures, and synchrotron based X-ray lithography, thermal and UV nanoimprint lithography and microfluidic devices. He is now more interested in biomaterials, population dynamics, stem cells and neuron chips. He has authored or co-authored more than 300 peer-reviewed articles (4800 citations, h-factor = 31). He has also contributed to more than 10 contracted European projects and a number of national and international projects.Finally, he is Changjian Scholar (visiting) of Peking University, Distinguished chair professor of Hong Kong Polytechnic University, and professor and Principal Investigator of Kyoto University granted by the World Premier International Research Center Initiative.l Mechanics and Multidisciplinary Study for Creating Graphene- based van der Waals Nano/microscale Devices Abstract: Elastic resonators have been the core elements for many types of nano-micro scale instruments and devices (e.g. gyroscope, mass and acceleration sensors, AFM, SNOM). A bottleneck challenge is their dramatically reduced quality factors as shrinking size due to the inevitable thermal dissipation in the elastic deforming mode. Van der Waals (vdW) oscillators invented recently 1 have the novel sliding motion mode in the micron-range that are retracted by the vdW interaction effectively in only1-nm range. Study has revealed that the latter has two orders of magnitude higher in both motion speed and quality factor, that are the two major multipliers contributing to the high-quality performance such as gyroscope. These features may promise a new class of various nano-micro devices. Graphene has many extreme properties such as the highest tensile strength, thermal and electrical conductivies, and superlubricity. The recently discovered self-retraction motion feature between two large scale sheared graphenes and the matured microfabrication technology make graphene-based vdW sliding devices a great candidate for the new type of nano-micro devices, as well as high-density/high-speed hard diskettes. Here in this presentation we reports the newly experimental and theoretical advances in this fields, including the self-retraction, motion and dissipation mechanisms, challenge in surface physics and chemistry, novel stripe/kink structure due to instability, transferring, self-assembling, and ultrahigh-speed record technology. Q.-S. Zheng, Yangtse Chair Professor, Chairman, Department Engineering Mechanics, Tsinghua University, Director, Centre for Nano-Micro Mechanics (CNMM), Tsinghua University. Research Interests：(1) Nanomechanics, nano-devices, micro/nano- bionics; (2) mechanics of heterogeneous materials, damage mechanics, constitutive equations (composites, polymers, biomaterials, teeth, polycrystals, ceramics); (3) theory of representations for tensors and tensor functions, mechanics of anisotropic behavior, rational mechanics.l Research Progresses of Micro/Nano Technology in IPE of Xian Jiaotong University Abstract: Micro/nano technology mainly refers to the manufacturing technology with feature size from micron to nanometer regime, involving microelectronics manufacturing, micro/nano electromechanical systems, optoelectronics manufacturing, ultra-precision machining, and so on. Since 1992 Professor Jiang Zhuangde has led Institute of Precision Engineering (IPE) of Xian Jiaotong University to investigate relevant micro/nano technology research. This report mainly introduces the progresses which IPE has achieved over nearly last two decades in nanotechnology, micro/nano devices and micro measuring systems, especially in nanomeasurement and traceability technology, high performance sensors, micro engine, instrument for MEMS materialsmechanical properties, micro-coordinate measuring machine, microfluidic detector, and ultra-precision machine with nanometer-level precision, etc. Prof. JIANG was born on August 4, 1955. In 1988, he obtained his master degree of machinery manufacturing in Xian Jiaotong University. At present he is the vice president of Xian Jiaotong University and the director of Institute of Precision Engineering (IPE). Also, he is a professor of two departments of mechanical engineering and instrument science & technology. His scientific interests include Micro Electro-Mechanical System (MEMS) and Micro/Nano fabrication technology, precision instrument & sensing technology, precision and ultra-precision machining technology, etc. He is a member of an expert team for advanced manufacturing of the Hi-Tech Research and Development Program of China, the standing director of Chinese Society of Micro/Nano Technology, and the director of Chinese Mechanical Engineering Society (CMES), and so on. He was financially funded by two key projects of National Natural Science Foundation of China, three key projects of the Hi-Tech Research and Development Program of China, three subprojects of the National Basic Research Program, and three projects for international academic cooperation projects, etc.He has authored and co-authored more than 210 papers in high-level journals, and obtained academic awards as follows.1) In 2009, the second prize of State Science and Technology Progress Awards of PRC. 2) In 2006, the second prize of State Technical Invention Awards of PRC. 3) In 2005, the excellent prize of Chinese Patent Award.l The Information Communication Technologies and Micro-Nano devices Abstract: Information Communication technology enabling the low carbon, green, and smart development, the trend of information communication technologies are presented in the talk, their effects on the development of traditional industries have been demonstrated. Micro-Nano devices are enabler of ICT, the recent progress of PC-RAM and MEMS sensors in SIMIT will be also presented. FENG Songlin is Professor and director of preparations committee of Shanghai Advanced Research Institute, CAS. He graduated from Wuhan University and got his Bachelor degree in 1983, he got his D.E.A. and Ph. D on material sciences from Paris VII University in 1987 an in 1990 respectively. He was professor and deputy director of Institute of Semiconductors, CAS, Professor and director of Shanghai Institute of Microsystem and Information Technology, CAS. He is an active researcher in the frontier of information technologies, and an expert member of several national scientific bodies. On the resear