【复材专家系列8】 Redox-Active Functional Materials for New Applications Switchable, Addressable and Tuneable
Professor Charl
F.J. Faul
Materials Chemistry
University of
Bristol, UK
时 间:2018年07月18日(周三) 10:30
地 点:曹光彪高科技大楼7楼远望庐
邀请人:彭华新教授
Abstract: Use of synthetic organic approaches for the preparation
of novel aniline-based materials allow us to exploit their tuneable conductive,
redox and optical properties. We have thus explored the use of such and
related materials in two key areas:
Functional
1D Wires: We are exploiting
this functional aniline-based platform to prepare novel redox-active cationic surfactants, and investigating their supramolecular organisation into self-assembled nanowires in solution, and actively tuning
their packing parameter to address assembly in a reversible fashion. We are
furthermore expanding our activities to the fabrication of novel OFET devices, thus continuing to
explore structure-property-function relationships.
Functional
3D Materials:
Applying these reactions for the formation of conjugated microporous polymers provided routes to
efficient and highly selective and tunable
CO2
capture, and
energy storage. Using 2-photon polymerisation-based direct laser writing (DLW),
finely controlled 3D-printed conjugated structures can be prepared to form
actively tuneable photonic crystals.
报告人简介:
Charl F. J. Faul
is Professor of Materials Chemistry and Director of Graduate Recruitment for
the School of Chemistry, University of Bristol, UK. He received his PhD from
the University of Stellenbosch, South Africa, in 2000. He is Adjunct Professor at the Department of Chemistry, Tsinghua University, Beijing, since November
2013. Prof. Faul
is a synthetic materials chemist with a multidisciplinary international
research group focussing on the design and synthesis of functional nanostructured materials. His activities range from
fundamental to application-driven areas, where hierarchical and ionic
self-assembly and the design and synthesis of electroactive nanomaterials are explored. Applications are
actively pursued in the areas of energy and gas storage, and electroactive materials and devices (nanowire-based field-effect transistors,
actuators for robotics, and 3D-printed addressable photonic structures).
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浙大复材专家系列讲座 第8期
InCSI Special Composites
Seminar (No.8)