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个人简介

Dr. Crick received his PhD from University College London (UCL), Department of Chemistry, in 2011, where his research was specialised in novel water repellent materials. This has since developed into a passion for materials science, and the drive toward developing ever better functional materials. After undertaking positions at UCL, Cornell University, and Imperial College London, funded respectively by the EPSRC Doctoral Prize, Fulbright Scholarship, and Ramsay Memorial Trust, Dr. Crick is took up his position at the University of Liverpool in 2016. His present research focus not only includes water repellent materials, but also incorporates a wide array of materials based fields, including biosensors and nanocomposites, with a focus on projects that can readily provide real-world impact. Ramsay Fellowship (Competitive Fellowship, The Ramsay Trust 2014) Fulbright AstraZeneca Scholar Award (US-UK Fulbright Comission 2012) Doctoral Prize (EPSRC 2011)

近期论文

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On-Demand Surface- and Tip-Enhanced Raman Spectroscopy Using Dielectrophoretic Trapping and Nanopore Sensing (Journal article - 2016) Repellent materials. Robust self-cleaning surfaces that function when exposed to either air or oil. (Journal article - 2015) Superhydrophobic silica wool-a facile route to separating oil and hydrophobic solvents from water. (Journal article - 2014) Advanced analysis of nanoparticle composites – a means toward increasing the efficiency of functional materials (Journal article - 2014) Relationship between surface hydrophobicity and water bounces – a dynamic method for accessing surface hydrophobicity (Journal article - 2013) Low Noise Nanopore Platforms Optimised for the Synchronised Optical and Electrical Detection of Biomolecules Advanced Compositional Analysis of Nanoparticle-polymer Composites Using Direct Fluorescence Imaging Ambipolar Transport in Solution-Synthesized Graphene Nanoribbons Copper-based water repellent and antibacterial coatings by aerosol assisted chemical vapour deposition On-Demand Surface- and Tip-Enhanced Raman Spectroscopy Using Dielectrophoretic Trapping and Nanopore Sensing Self-Assembled Spherical Supercluster Metamaterials from Nanoscale Building Blocks A physicochemical investigation of ionic liquid mixtures Fabrication of optimized oil-water separation devices through the targeted treatment of silica meshes Precise attoliter temperature control of nanopore sensors using a nanoplasmonic bullseye Selectively Sized Graphene-Based Nanopores for in Situ Single Molecule Sensing A general method for the incorporation of nanoparticles into superhydrophobic films by aerosol assisted chemical vapour deposition Relationship between surface hydrophobicity and water bounces – a dynamic method for accessing surface hydrophobicity Superhydrophobic polymer-coated copper-mesh; membranes for highly efficient oil–water separation Superhydrophobic surfaces as an on-chip microfluidic toolkit for total droplet control A general method for the incorporation of nanoparticles into superhydrophobic films by aerosol assisted chemical vapour deposition Superhydrophobic polymer-coated copper-mesh; membranes for highly efficient oil–water separation Superhydrophobic surfaces as an on-chip microfluidic toolkit for total droplet control Superhydrophobic photocatalytic surfaces through direct incorporation of titania nanoparticles into a polymer matrix by aerosol assisted chemical vapor deposition Aerosol assisted deposition of melamine-formaldehyde resin: Hydrophobic thin films from a hydrophilic material Aerosol assisted depositions of polymers using an atomiser delivery system

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