Thomas Parton
Max-Planck-Institut fur Kolloid und Grenzflachenforschung
Appearances
- DateMarch 23, 2022Chiral plasmonic properties arising from the metal nanostructures and their assemblies are desirable for a range of applications such as chiral biosensors, negative refractive materials, broadband circular polarizers…
Presenter
Speakers
Max-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - DateMarch 23, 2022Cellulose nanocrystals (CNCs) are bio-sourced rod-like colloidal particles that can spontaneously form a cholesteric (chiral nematic) liquid crystal phase in suspension, leading to vivid structurally colored films in the solid state…
Presenter
Max-Planck-Institut fur Kolloid und GrenzflachenforschungSpeakers
- Cellulose nanocrystals (CNCs) are elongated colloidal particles that spontaneously form a cholesteric liquid crystal phase in aqueous suspension. As the suspension dries, the system undergoes kinetic arrest (KA), in which the CNCs become trapped into a non-equilibrium configuration…
Presenter
Max-Planck-Institut fur Kolloid und GrenzflachenforschungSpeakers
- Daytime radiative cooling (DRC) materials offer a sustainable approach to thermal management by exploiting net positive heat transfer to deep space…
Speakers
Max-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge UniveristyPresenter
- Cellulose nanocrystals (CNCs) are bio-derived elongated nanoparticles that have attracted growing research interest over the past few decades…
Presenter
Max-Planck-Institut fur Kolloid und GrenzflachenforschungSpeakers
- Optical activity (OA) arising from chiral arrangement of metallic nanostructures is desired for a range of emergent applications such as negative-index materials, chiral biosensors, and cloaking devices…
Presenter
Speakers
Max-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - Cellulose nanocrystals (CNCs) are elongated colloidal particles that spontaneously form a cholesteric liquid crystal phase in aqueous suspension. As the suspension dries, the system undergoes kinetic arrest (KA), in which the CNCs become trapped into a non-equilibrium configuration…
Speakers
Max-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - : [CELL] Division of Cellulose and Renewable Materials
Speakers
Yale UniversityPenn State UniversityThe University of British ColumbiaThe University of British ColumbiaUSDA Forest ServiceThe University of British ColumbiaAssistant Professor, Kungliga Tekniska HogskolanProfessor, University of PennsylvaniaThe University of British ColumbiaThe University of British ColumbiaThe University of British ColumbiaMax-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - Daytime radiative cooling (DRC) materials offer a sustainable approach to thermal management by exploiting net positive heat transfer to deep space…
Speakers
Max-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - : [CELL] Division of Cellulose and Renewable Materials
Speakers
Virginia Polytechnic Institute and State UniversityLarChem LLCBoku University ViennaNorth Carolina State UniversityImperiral College LondonMax-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - Cellulose nanocrystals (CNCs) are bio-derived elongated nanoparticles that have attracted growing research interest over the past few decades…
Speakers
Max-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - : [CELL] Division of Cellulose and Renewable Materials
Speakers
Imperial College LondonCanada Research Chair, Lakehead UniversityThe University of British ColumbiaLarChem LLCBoku University ViennaUniversity of LouisvilleMax-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge UniveristyAalto UniversityEmpa Materials Science and TechnologyImperiral College London - Cellulose nanocrystals (CNCs) are elongated colloidal particles that spontaneously form a cholesteric liquid crystal phase in aqueous suspension. As the suspension dries, the system undergoes kinetic arrest (KA), in which the CNCs become trapped into a non-equilibrium configuration…
Speakers
Max-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - : [CELL] Division of Cellulose and Renewable Materials
Speakers
Yale UniversityPenn State UniversityThe University of British ColumbiaThe University of British ColumbiaUSDA Forest ServiceThe University of British ColumbiaAssistant Professor, Kungliga Tekniska HogskolanProfessor, University of PennsylvaniaThe University of British ColumbiaThe University of British ColumbiaThe University of British ColumbiaMax-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - Daytime radiative cooling (DRC) materials offer a sustainable approach to thermal management by exploiting net positive heat transfer to deep space…
Speakers
Max-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - : [CELL] Division of Cellulose and Renewable Materials
Speakers
Virginia Polytechnic Institute and State UniversityLarChem LLCBoku University ViennaNorth Carolina State UniversityImperiral College LondonMax-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - Cellulose nanocrystals (CNCs) are bio-derived elongated nanoparticles that have attracted growing research interest over the past few decades…
Speakers
Max-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - : [CELL] Division of Cellulose and Renewable Materials
Speakers
Imperial College LondonCanada Research Chair, Lakehead UniversityThe University of British ColumbiaLarChem LLCBoku University ViennaUniversity of LouisvilleMax-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge UniveristyAalto UniversityEmpa Materials Science and TechnologyImperiral College London - Cellulose nanocrystals (CNCs) are elongated colloidal particles that spontaneously form a cholesteric liquid crystal phase in aqueous suspension. As the suspension dries, the system undergoes kinetic arrest (KA), in which the CNCs become trapped into a non-equilibrium configuration…
Speakers
Max-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - : [CELL] Division of Cellulose and Renewable Materials
Speakers
Yale UniversityPenn State UniversityThe University of British ColumbiaThe University of British ColumbiaUSDA Forest ServiceThe University of British ColumbiaAssistant Professor, Kungliga Tekniska HogskolanProfessor, University of PennsylvaniaThe University of British ColumbiaThe University of British ColumbiaThe University of British ColumbiaMax-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - Daytime radiative cooling (DRC) materials offer a sustainable approach to thermal management by exploiting net positive heat transfer to deep space…
Speakers
Max-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - : [CELL] Division of Cellulose and Renewable Materials
Speakers
Virginia Polytechnic Institute and State UniversityLarChem LLCBoku University ViennaNorth Carolina State UniversityImperiral College LondonMax-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - Cellulose nanocrystals (CNCs) are bio-derived elongated nanoparticles that have attracted growing research interest over the past few decades…
Speakers
Max-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - : [CELL] Division of Cellulose and Renewable Materials
Speakers
Imperial College LondonCanada Research Chair, Lakehead UniversityThe University of British ColumbiaLarChem LLCBoku University ViennaUniversity of LouisvilleMax-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge UniveristyAalto UniversityEmpa Materials Science and TechnologyImperiral College London - Cellulose nanocrystals (CNCs) are elongated colloidal particles that spontaneously form a cholesteric liquid crystal phase in aqueous suspension. As the suspension dries, the system undergoes kinetic arrest (KA), in which the CNCs become trapped into a non-equilibrium configuration…
Speakers
Max-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - : [CELL] Division of Cellulose and Renewable Materials
Speakers
Yale UniversityPenn State UniversityThe University of British ColumbiaThe University of British ColumbiaUSDA Forest ServiceThe University of British ColumbiaAssistant Professor, Kungliga Tekniska HogskolanProfessor, University of PennsylvaniaThe University of British ColumbiaThe University of British ColumbiaThe University of British ColumbiaMax-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - Daytime radiative cooling (DRC) materials offer a sustainable approach to thermal management by exploiting net positive heat transfer to deep space…
Speakers
Max-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - : [CELL] Division of Cellulose and Renewable Materials
Speakers
Virginia Polytechnic Institute and State UniversityLarChem LLCBoku University ViennaNorth Carolina State UniversityImperiral College LondonMax-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - Cellulose nanocrystals (CNCs) are bio-derived elongated nanoparticles that have attracted growing research interest over the past few decades…
Speakers
Max-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge Univeristy - : [CELL] Division of Cellulose and Renewable Materials
Speakers
Imperial College LondonCanada Research Chair, Lakehead UniversityThe University of British ColumbiaLarChem LLCBoku University ViennaUniversity of LouisvilleMax-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge UniveristyAalto UniversityEmpa Materials Science and TechnologyImperiral College London - DateMarch 28, 2023Cellulose nanocrystals (CNCs) are elongated colloidal particles that spontaneously form a cholesteric liquid crystal phase in aqueous suspension. As the suspension dries, the system undergoes kinetic arrest (KA), in which the CNCs become trapped into a non-equilibrium configuration…
Presenter
Max-Planck-Institut fur Kolloid und GrenzflachenforschungSpeakers
- DateMarch 26, 2023Daytime radiative cooling (DRC) materials offer a sustainable approach to thermal management by exploiting net positive heat transfer to deep space…
Speakers
Max-Planck-Institut fur Kolloid und GrenzflachenforschungCambridge UniveristyPresenter
- DateMarch 27, 2023Cellulose nanocrystals (CNCs) are bio-derived elongated nanoparticles that have attracted growing research interest over the past few decades…
Presenter
Max-Planck-Institut fur Kolloid und GrenzflachenforschungSpeakers
- DateMarch 18, 2024To address widespread concerns over the impact of human activity on the environment, there is a growing desire to create functional materials from sustainable, naturally-derived feedstocks…
Organizer, Presiders
Universitat fur Bodenkultur WienMax-Planck-Institut fur Kolloid und GrenzflachenforschungThe University of British ColumbiaMax Plank Institute of Colloids and InterfacesOrganizers
- DateMarch 19, 2024To address widespread concerns over the impact of human activity on the environment, there is a growing desire to create functional materials from sustainable, naturally-derived feedstocks…
Organizers
Universitat fur Bodenkultur WienMcMaster UniversityCNRSThe University of British ColumbiaOrganizer, Presiders
Max-Planck-Institut fur Kolloid und GrenzflachenforschungMax Plank Institute of Colloids and Interfaces - DateMarch 17, 2024Cellulose nanocrystals (CNCs) are rod-shaped nanoparticles extracted from natural cellulose that can be used for diverse applications, ranging from mechanical reinforcement of composites to structurally-colored photonic films…
Presenter
Max-Planck-Institut fur Kolloid und Grenzflachenforschung - DateMarch 18, 2024Cellulose nanocrystals (CNCs) are elongated, negatively charged nanoparticles extracted from the acid hydrolysis of natural cellulose. They are known to spontaneously form a left-handed cholesteric liquid crystalline phase in suspension upon reaching a specific volume fraction…
Presenter
Speakers
Max-Planck-Institut fur Kolloid und GrenzflachenforschungCNRS