Supramolecular Chemistry
Supramolecular chemistry deals with noncovalent interactions between molecules. These interactions can be highly directional, giving rise to well-defined supramolecular assemblies, or “supramolecules”. Supramolecular chemistry forms the basis of next-generation materials, which will be active, adaptive, reconfigurable, and responsive to external stimuli. Supramolecular chemistry is also at the heart of catalysis.
DNA nanotechnology
Host–guest chemistry & sensors
Metal-ligand coordination
Systems chemistry
Prof. Lia Addadi
research areas
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Biological Physics
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Bio-materials
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Biophysics of animal behavior
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Soft and living matter
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Chemical Biology
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Bio-organic chemistry
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Chemical Physics
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Light & matter
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Materials and Nanoscience
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Optical and electronic properties
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Self-assembly
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Soft matter
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Organic Chemistry
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Materials & nanochemistry
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Supramolecular chemistry
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X-ray crystallography
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Structural and Molecular Biology
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Biomineralization
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Electron microscopy
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X-ray crystallography
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Supramolecular Chemistry
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Biomolecular assemblies
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Materials
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Prof. Amnon Bar-Shir
research areas
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Biological Physics
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Bio-materials
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Chemical Biology
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Bio-conjugation & protein modifications
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Bio-organic chemistry
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Biological applications of magnetic resonance
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Chemical probes & inhibitor design
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Drug discovery & translational research
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Molecular sensors and probes
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Chemical Physics
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Magnetic resonance
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Materials and Nanoscience
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Nano-synthesis & fabrication
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Self-assembly
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Organic Chemistry
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Chemical biology & medicinal chemistry
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Materials & nanochemistry
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Sensors & biosensors
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Supramolecular chemistry
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Systems chemistry
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Structural and Molecular Biology
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Biological applications of magnetic resonance
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Supramolecular Chemistry
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Biomimicry
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Biomolecular assemblies
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Host–guest chemistry & sensors
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Materials
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Molecular-based devices
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Prof. Michael Elbaum
research areas
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Biological Physics
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Protein dynamics
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Soft and living matter
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Materials and Nanoscience
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Soft matter
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Structural and Molecular Biology
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Electron microscopy
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Nucleic acids
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Proteins & macromolecular assemblies
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Supramolecular Chemistry
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Biomolecular assemblies
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Prof. Deborah Fass
research areas
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Biological Physics
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Bio-materials
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Chemical Biology
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Drug discovery & translational research
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Structural and Molecular Biology
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Electron microscopy
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Evolution & allostery
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Proteins & macromolecular assemblies
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X-ray crystallography
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Supramolecular Chemistry
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Biomolecular assemblies
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Prof. Nir Gov
research areas
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Biological Physics
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Bio-materials
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Biophysics of animal behavior
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Cell Mechanics & mechanobiology
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Macromolecules & membranes
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Soft and living matter
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Materials and Nanoscience
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Self-assembly
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Soft matter
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Structural and Molecular Biology
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Proteins & macromolecular assemblies
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Supramolecular Chemistry
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Biomolecular assemblies
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Theory and Computations
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Ab initio and classical computational approaches
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Active matter systems
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Biopolymers
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Disordered systems
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Nonlinear dynamics & pattern formation
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Soft condensed matter
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Systems far from equilibrium
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Theoretical biological physics
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Theory of living matter
Prof. Jacob Klein
research areas
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Biological Physics
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Bio-materials
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Interfaces
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Macromolecules & membranes
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Soft and living matter
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Chemical Physics
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Molecular dynamics
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Materials and Nanoscience
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Interfaces
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Mechanical properties
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Nano-synthesis & fabrication
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Self-assembly
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Soft matter
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Surface science
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Structural and Molecular Biology
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Molecular dynamics & computational approaches
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Supramolecular Chemistry
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Biomimicry
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Biomolecular assemblies
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Materials
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Theory and Computations
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Biopolymers
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Prof. Leeor Kronik
research areas
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Chemical Physics
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Molecular dynamics
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Molecular electronics
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Spectroscopy & microscopy
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Spin physics
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Surface science
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Energy and Sustainability
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Storage & conversion
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Sustainable materials
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Materials and Nanoscience
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Advanced spectroscopy & microscopy
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Interfaces
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Mechanical properties
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Optical and electronic properties
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Surface science
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Organic Chemistry
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Molecular modeling
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Supramolecular chemistry
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Supramolecular Chemistry
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Materials
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Theory and Computations
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Ab initio and classical computational approaches
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Electronic structure & excited state methods
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Materials science
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Prof. Koby Levy
research areas
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Biological Physics
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Protein dynamics
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Chemical Biology
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Bio-conjugation & protein modifications
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Molecular modeling
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Chemical Physics
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Molecular dynamics
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Structural and Molecular Biology
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Molecular dynamics & computational approaches
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Nucleic acids
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Proteins & macromolecular assemblies
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Supramolecular Chemistry
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Biomolecular assemblies
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Theory and Computations
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Ab initio and classical computational approaches
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Biopolymers
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Disordered systems
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Molecular modelling & docking
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Prof. David Margulies
research areas
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Chemical Biology
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Bio-conjugation & protein modifications
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Bio-organic chemistry
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Chemical probes & inhibitor design
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Drug discovery & translational research
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Molecular sensors and probes
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Materials and Nanoscience
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Self-assembly
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Surface science
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Organic Chemistry
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Chemical biology & medicinal chemistry
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Metal-ligand coordination
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Sensors & biosensors
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Supramolecular chemistry
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Synthesis
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Supramolecular Chemistry
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Biomimicry
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Biomolecular assemblies
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DNA nanotechnology
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Host–guest chemistry & sensors
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Metal-ligand coordination
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Molecular-based devices
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Synthesis
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Prof. Gershom (Jan) Martin
research areas
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Chemical Biology
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Molecular modeling
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Chemical Physics
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Quantum science and technologies
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Organic Chemistry
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Catalysis
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Chemical biology & medicinal chemistry
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Metal-ligand coordination
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Molecular modeling
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Supramolecular chemistry
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Structural and Molecular Biology
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Molecular dynamics & computational approaches
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Supramolecular Chemistry
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Catalysis
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Metal-ligand coordination
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Theory and Computations
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Ab initio and classical computational approaches
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Electronic structure & excited state methods
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Molecular modelling & docking
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Reaction mechanisms
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Prof. Ron Naaman
research areas
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Chemical Physics
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Molecular electronics
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Quantum science and technologies
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Spin physics
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Organic Chemistry
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Electrochemistry
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Supramolecular Chemistry
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Molecular-based devices
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Prof. Ronny Neumann
research areas
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Energy and Sustainability
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Catalysis
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Chemistry and the environment
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Storage & conversion
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Synthesis
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Organic Chemistry
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Catalysis
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Green chemistry & energy
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Materials & nanochemistry
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Metal-ligand coordination
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Supramolecular chemistry
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Supramolecular Chemistry
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Catalysis
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Materials
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Metal-ligand coordination
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Prof. Boris Rybtchinski
research areas
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Biological Physics
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Protein dynamics
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Chemical Physics
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Molecular dynamics
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Quantum science and technologies
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Spectroscopy & microscopy
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Surface science
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Energy and Sustainability
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Chemistry and the environment
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Energy storage & conversion devices
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Storage & conversion
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Sustainable materials
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Materials and Nanoscience
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Advanced spectroscopy & microscopy
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Mechanical properties
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Nano-synthesis & fabrication
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Optical and electronic properties
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Self-assembly
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Soft matter
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Organic Chemistry
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Green chemistry & energy
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Materials & nanochemistry
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Sensors & biosensors
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Supramolecular chemistry
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Synthesis
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X-ray crystallography
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Supramolecular Chemistry
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Biomolecular assemblies
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Materials
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Molecular-based devices
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Synthesis
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Prof. Samuel Safran
research areas
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Biological Physics
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Bio-materials
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Cell Mechanics & mechanobiology
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Interfaces
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Macromolecules & membranes
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Soft and living matter
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Materials and Nanoscience
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Interfaces
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Mechanical properties
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Self-assembly
-
Soft matter
-
-
Structural and Molecular Biology
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Proteins & macromolecular assemblies
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-
Supramolecular Chemistry
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Biomolecular assemblies
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Materials
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Theory and Computations
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Active matter systems
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Biopolymers
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Materials science
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Nonlinear dynamics & pattern formation
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Soft condensed matter
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Theoretical biological physics
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Theory of living matter
Dr. Sergey Semenov
research areas
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Chemical Biology
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Molecular sensors and probes
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Energy and Sustainability
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Catalysis
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Synthesis
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Materials and Nanoscience
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Self-assembly
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Soft matter
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Organic Chemistry
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Catalysis
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Electrochemistry
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Green chemistry & energy
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Metal-ligand coordination
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Supramolecular chemistry
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Synthesis
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Systems chemistry
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X-ray crystallography
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Supramolecular Chemistry
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Biomimicry
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Biomolecular assemblies
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Catalysis
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Materials
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Metal-ligand coordination
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Molecular-based devices
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Synthesis
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Systems chemistry
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Theory and Computations
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Nonlinear dynamics & pattern formation
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Reaction mechanisms
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Systems far from equilibrium
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Prof. Mordechai Sheves
research areas
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Biological Physics
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Bio-materials
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Macromolecules & membranes
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Chemical Biology
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Bio-organic chemistry
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Materials and Nanoscience
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Optical and electronic properties
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Organic Chemistry
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Chemical biology & medicinal chemistry
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Materials & nanochemistry
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Synthesis
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Supramolecular Chemistry
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Synthesis
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Dr. Ulyana Shimanovich
research areas
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Biological Physics
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Bio-materials
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Soft and living matter
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Materials and Nanoscience
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Mechanical properties
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Nano-synthesis & fabrication
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Optical and electronic properties
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Self-assembly
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Soft matter
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Organic Chemistry
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Materials & nanochemistry
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Supramolecular chemistry
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Structural and Molecular Biology
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Proteins & macromolecular assemblies
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Supramolecular Chemistry
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Biomimicry
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Biomolecular assemblies
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Molecular-based devices
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Theory and Computations
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Complex solids and fluids
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Prof. Joel Sussman
research areas
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Biological Physics
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Protein dynamics
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Chemical Biology
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Drug discovery & translational research
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Molecular modeling
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Chemical Physics
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Molecular dynamics
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Organic Chemistry
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X-ray crystallography
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-
Structural and Molecular Biology
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Electron microscopy
-
Evolution & allostery
-
Molecular dynamics & computational approaches
-
Nucleic acids
-
Proteins & macromolecular assemblies
-
X-ray crystallography
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-
Supramolecular Chemistry
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Biomolecular assemblies
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-
Theory and Computations
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Disordered systems
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Molecular modelling & docking
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Prof. Daniel Hanoch Wagner
research areas
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Biological Physics
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Bio-materials
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Cell Mechanics & mechanobiology
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Interfaces
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Energy and Sustainability
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Sustainable materials
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Materials and Nanoscience
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Advanced spectroscopy & microscopy
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Interfaces
-
Mechanical properties
-
Soft matter
-
-
Organic Chemistry
-
X-ray crystallography
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Structural and Molecular Biology
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Biomineralization
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Electron microscopy
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Supramolecular Chemistry
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Biomimicry
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Materials
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Dr. Omer Yaffe
research areas
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Chemical Physics
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Light & matter
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Molecular dynamics
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Spectroscopy & microscopy
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Energy and Sustainability
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Storage & conversion
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Sustainable materials
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Materials and Nanoscience
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Mechanical properties
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Optical and electronic properties
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Surface science
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Supramolecular Chemistry
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Materials
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Prof. Milko van der Boom
research areas
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Chemical Physics
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Molecular electronics
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Spectroscopy & microscopy
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Surface science
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Energy and Sustainability
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Energy storage & conversion devices
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Molecular electronics
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Storage & conversion
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Sustainable materials
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Synthesis
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Materials and Nanoscience
-
Advanced spectroscopy & microscopy
-
Interfaces
-
Mechanical properties
-
Nano-synthesis & fabrication
-
Optical and electronic properties
-
Self-assembly
-
Soft matter
-
Surface science
-
-
Organic Chemistry
-
Catalysis
-
Electrochemistry
-
Electron microscopy
-
Green chemistry & energy
-
Materials & nanochemistry
-
Metal-ligand coordination
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Sensors & biosensors
-
Supramolecular chemistry
-
Synthesis
-
Systems chemistry
-
X-ray crystallography
-
-
Supramolecular Chemistry
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Catalysis
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Host–guest chemistry & sensors
-
Materials
-
Metal-ligand coordination
-
Molecular-based devices
-
Synthesis
-
Systems chemistry
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