Materials World Network: Modulation of Electron Oscillation Characteristics of Nanostructured Conducting Polymer Films during Electrochemical Switching

材料世界网：电化学开关过程中纳米结构导电聚合物薄膜电子振荡特性的调制

• 批准号: 1007900
• 负责人: Omowunmi Sadik
• 金额: $ 33万
• 依托单位: SUNY at Binghamton
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2010
• 资助国家: 美国
• 起止时间: 2010-07-15 至 2014-05-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1007900&HistoricalAwards=false
• 关键词: Materials; World; Network; Modulation; Electron

The goal of this project is to probe the mechanism of how the electroactivity of conducting polymers can be significantly influenced by the sequestered nanoparticles surface plasmons, which can then be modulated by electrochemical switching. A fundamental understanding of the new synergistic properties that may arise from these studies can enable the development of plasmonic devices. Polymer-nanoparticle interactions are important in many areas of research-from sensors to microelectronics and photovoltaics. The investigators have developed the technology for nanostructured poly(amic acid) films that are electroactive and transparent by preventing its imidization to polyimide, while retaining its carboxylic acid and amine functionalities. They study the fundamentals of conducting polymer-metal nanoparticles synergies. A range of new conducting poly(amic acid)/metal composite films will be developed and characterized. The effect of composition and microstructure on the optical and electrochemical properties of the polymer/metal composite materials will be studied. The materials to be developed and the transferable skills of the investigators will be shared between SUNY-Binghamton and their partners at the University of the Western Cape in South Africa during exchange visits. The final goal is to develop low cost sensors for environmentally important compounds.This project integrates research and training. It will also combine the complementary expertise of the SUNY advanced sensors and smart materials group with the South Africa's electrochemistry group in a study that has significant implications to understand the synergy between polymers and nanoparticles. The research benefits arising from the complementary expertise of these two international teams: development and precision characterization of conducting membranes that are electroactive and transparent at SUNY-Binghamton, and electrochemistry capabilities at the U. of the Western Cape. The investigators will conduct electrochemistry and sensors workshop at the University of the Western Cape with the goal of developing materials for research training, classroom instruction and outreach to the community. US students will spend time doing research at the U. of the Western Cape developing new, smart devices, which are easy to fabricate but do not require complicated electronics to modulate the switching action. This project will promote the application of low-cost electrochemical sensors in addressing global, environmental pollution, particularly for developing countries.This award is co-funded by the Division of Materials Research and the Office of International Science and Engineering.

该项目的目标是探讨隔离的纳米颗粒表面等离子体如何显着影响导电聚合物的电活性，然后可以通过电化学开关对其进行调节。对这些研究可能产生的新协同特性的基本了解可以促进等离激元器件的开发。聚合物-纳米粒子相互作用在许多研究领域都很重要——从传感器到微电子和光伏。研究人员开发了纳米结构聚酰胺酸薄膜技术，通过防止其酰亚胺化为聚酰亚胺，同时保留其羧酸和胺官能团，该薄膜具有电活性和透明性。他们研究了聚合物-金属纳米颗粒协同作用的基础原理。将开发和表征一系列新型导电聚（酰胺酸）/金属复合薄膜。研究成分和微观结构对聚合物/金属复合材料光学和电化学性能的影响。纽约州立大学宾厄姆顿分校及其在南非西开普大学的合作伙伴将在互访期间共享待开发的材料和研究人员的可转移技能。最终目标是为对环境重要的化合物开发低成本传感器。该项目集研究和培训于一体。它还将在一项研究中将纽约州立大学先进传感器和智能材料小组与南非电化学小组的互补专业知识结合起来，该研究对于了解聚合物和纳米粒子之间的协同作用具有重要意义。这项研究得益于这两个国际团队的互补专业知识：纽约州立大学宾厄姆顿分校的电活性和透明导电膜的开发和精确表征，以及西开普大学的电化学能力。研究人员将在西开普大学举办电化学和传感器研讨会，目的是开发用于研究培训、课堂教学和社区推广的材料。美国学生将花时间在西开普大学进行研究，开发新型智能设备，这些设备易于制造，但不需要复杂的电子设备来调节开关动作。该项目将促进低成本电化学传感器的应用，以解决全球环境污染问题，特别是发展中国家的环境污染问题。该奖项由材料研究部和国际科学与工程办公室共同资助。