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Bioinspired Materials NCCR

A National Center of Competence in Research

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  • Module 2: Responsive materials by self-assembly

Research Research

  • Module 1: Mechanically responsive materials
  • Module 2: Photonic materials
  • Module 3: Bio-interfaces across scales
  • Translation projects
  • Other research projects
  • Research stories
  • Publications & Datasets
    • Datasets
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    • Module 1: Mechanically responsive materials
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    • Module 3: Interactions of responsive materials with cells
    • Module 4: Dynamics of interacting cell-material systems
    • Other projects
  • Open Science
    • Open Access
    • Open Research Data
    • Copyright and licenses

Confinement induced stable liquid phases mimicking the behavior in cell membrane lipid bilayers

Active between 01.06.2014 and 31.05.2018

Main investigator

BRADER_Joseph.jpg
BRADER Joseph

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Involved people

BOTT_Matthias_2014.jpeg
BOTT Matthias

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  • Related publications
      Power functional theory for the dynamic test particle limit
      Brader Joseph M, Schmidt Matthias
      Journal of Physics: Condensed Matter (2015)

       

      Effective interactions in active Brownian suspensions
      Farage T. F. F., Krinninger P., Brader J. M.
      Physical Review E (2015)

       

      Communication: Green-Kubo approach to the average swim speed in active Brownian systems
      Sharma A., Brader J. M.
      The Journal of Chemical Physics (2016)

       

      Phase separation on the sphere: Patchy particles and self-assembly
      Bott M. C., Brader J. M.
      Physical Review E (2016)

       

      Active Brownian particles at interfaces: An effective equilibrium approach
      Wittmann René, Brader Joseph M.
      EPL (Europhysics Letters) (2016)

       

      Escape rate of active particles in the effective equilibrium approach
      Sharma A., Wittmann R., Brader J. M.
      Physical Review E (2017)

       

     
ABOUT US
  • Mission and Vision
  • Organization
  • People
  • Ethics charter
  • Contact
  • Open positions
  • Alumni
EQUAL OPPORTUNITIES
  • Funding programs
  • Mentoring opportunities
  • Childcare
  • Success stories
  • Gender equality policy
  • #NCCRwomen
RESEARCH
  • Module 1: Mechanically responsive materials
  • Module 2: Photonic materials
  • Module 3: Bio-interfaces across scales
  • Translation projects
  • Other research projects
  • Research stories
  • Publications & Datasets
  • Good scientific practices
  • Completed projects
  • Open Science
INNOVATION & TECHNOLOGY TRANSFER
  • Proof-of-concept grant
  • Industrial Associates Program
  • Idea disclosure
  • Startups
EDUCATION
  • Elementary and high school
  • A researcher in my class
  • Summer Internships for Undergraduates
  • Doctoral training
  • Postdoctoral training
NEWS & EVENTS
  • News
  • Seminars
  • Roundtables
  • Agenda
MEDIA
  • Documents
  • Social Media
  • Stories
  • FAQ
Contact

NCCR Bio-Inspired Materials

University of Fribourg

Chemin des Verdiers 4

CH-1700 Fribourg

+41 26 300 9266

myriam.marano@unifr.ch

bioinspired-materials.ch

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