FLUXIONIC: Controlled transport of water and ions in nanoconfinement

FLUXIONIC:纳米限制中水和离子的受控传输

基本信息

  • 批准号:
    EP/Y03113X/1
  • 负责人:
  • 金额:
    $ 33.22万
  • 依托单位:
  • 依托单位国家:
    英国
  • 项目类别:
    Research Grant
  • 财政年份:
    2024
  • 资助国家:
    英国
  • 起止时间:
    2024 至 无数据
  • 项目状态:
    未结题

项目摘要

Controlling transport of liquid matter through channels with dimensions from Ångströms to nanometres is a key challenge in many areas of science and engineering. However, progress in this field is hampered by our lack of understanding, as the conventional macroscopic description of transport phenomena breaks down. Explaining the anomalous transport behaviour at the sub-nano scale necessitates close integration of experiments with atomistic model calculations. The emerging field promises huge technological and socio-economic impact. However, it is essential to train a new generation of early-stage researchers in the diverse skills that are needed to develop and apply precisely controlled nanofluidic mass transport. This, in a few words, is the aim of FLUXIONIC program: bridging Physics, Chemistry, Materials Science, and emerging nanoscale technologies. We created the network comprising academic and private partners with the major objective to offer an integrated training and a strong program of secondments to young researchers. FLUXIONIC will provide a rigorous, balanced, and timely supra-disciplinary training delivered by internationally leading scientists, with seamless opportunities to move between industry and academia. Recent exciting developments in experimental and theoretical methods to study transport of fluids and charged particles at the nanoscale mean that we are now at a stage where exploration of key processes is viable and fundamental and applied breakthroughs can be expected from our research program. The additional impact of FLUXIONIC will be structuring the EU research environment through long-term collaborations, consolidating doctoral training programs, and bridging the R&D in academia and industry. We will train young researchers for future leadership in the rapidly growing fields of nanotechnology with strong impacts on core challenges of modern society: clean water, disease treatment, sustainable production, storage and usage of energy.
控制液体物质通过从纳米到纳米尺寸的通道的传输是许多科学和工程领域的关键挑战。然而,在这一领域的进展是阻碍了我们缺乏理解,因为传统的宏观描述的输运现象打破。解释在亚纳米尺度上的反常输运行为需要将实验与原子模型计算紧密结合起来。这一新兴领域有望产生巨大的技术和社会经济影响。然而,培养新一代早期研究人员掌握开发和应用精确控制的纳米流体质量传输所需的各种技能至关重要。简而言之,这就是FLUXIONIC计划的目标:桥接物理,化学,材料科学和新兴的纳米技术。我们创建了由学术和私人合作伙伴组成的网络,主要目标是为年轻研究人员提供综合培训和强大的借调计划。FLUXIONIC将提供由国际领先科学家提供的严格,平衡和及时的跨学科培训,并提供在工业和学术界之间流动的无缝机会。最近令人兴奋的发展,在实验和理论方法来研究流体和带电粒子在纳米级的传输意味着我们现在处于一个阶段,探索关键过程是可行的,根本的和应用的突破,可以预期从我们的研究计划。FLUXIONIC的其他影响将通过长期合作构建欧盟研究环境,巩固博士培训计划,并在学术界和工业界的研发中架起桥梁。我们将培养年轻研究人员,使其在快速发展的纳米技术领域发挥未来的领导作用,这些领域对现代社会的核心挑战产生重大影响:清洁水、疾病治疗、可持续生产、能源储存和使用。

项目成果

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会议论文数量(0)
专利数量(0)

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Susan Perkin其他文献

Specific ion effects enhance local structure in zwitterionic osmolyte solutions
特定离子效应增强两性离子渗透调节物溶液中的局部结构
  • DOI:
    10.1039/d5sc00286a
  • 发表时间:
    2025-02-17
  • 期刊:
  • 影响因子:
    7.400
  • 作者:
    Kieran J. Agg;Timothy S. Groves;Shurui Miao;Y. K. Catherine Fung;Oliver L. G. Alderman;Thomas F. Headen;Terri-Louise Hughes;Gregory N. Smith;Tristan G. A. Youngs;James P. Tellam;Yao Chen;Susan Perkin;James E. Hallett
  • 通讯作者:
    James E. Hallett
Electrotunable friction with ionic liquid lubricants
离子液体润滑剂的电可调摩擦
  • DOI:
    10.1038/s41563-022-01273-7
  • 发表时间:
    2022-06-27
  • 期刊:
  • 影响因子:
    38.500
  • 作者:
    Fernando Bresme;Alexei A. Kornyshev;Susan Perkin;Michael Urbakh
  • 通讯作者:
    Michael Urbakh

Susan Perkin的其他文献

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  • 财政年份:
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  • 资助金额:
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  • 项目类别:
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