Quantum regimes in long-range electron transport in an assembly of ZnO nanocrystals. A.L. Roest*, E.A. Meulenkamp†, J.J. Kelly* and D. Vanmaekelbergh* *Physics and Chemistry of Condensed Matter, Debye Institute, Univer

Source URL: www.quantsol.org

• Quantum electronics
• Quantum chemistry
• Nanomaterials
• Emerging technologies
• Charge carriers
• Quantum dot
• Electron
• Zinc oxide
• Atomic orbital
• Physics
• Chemistry
• Condensed matter physics

Quantsol workshop MarchA quantum-dot antenna layer coupled to a thin-film solar cell. R. Koole, P. Liljeroth, S. Wuister, A. Meijerink and D. Vanmaekelbergh Chemistry of Condensed Matter, Debye Institute, Universi

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• Spintronics
• Nanomaterials
• Emerging technologies
• Quantum electrodynamics
• Quantum dot
• Exciton
• Solar cell
• Cadmium telluride
• Electron
• Physics
• Condensed matter physics
• Quantum electronics

Probing the single-particle orbital energy spectrum of insulating nanocrystals with Scanning Tunneling Spectroscopy E. Bakkers and D. Vanmaekelbergh, Debye Institute, University of Utrecht Current techniques in colloid c

Source URL: www.quantsol.org

• Quantum chemistry
• Spectroscopy
• Atomic physics
• Quantum electronics
• Electron
• Quantum dot
• Scanning tunneling spectroscopy
• Atomic orbital
• Energy level
• Chemistry
• Physics
• Nanomaterials

Binary quantum-dot superlattices: the beauty and the science D. Vanmaekelbergh, D. Grodzinska, W. Evers, H. Friedrich, B. de Nijs, K. Overgaag, and P. Liljeroth Debye Institute for NanoMaterials Science, University of Ut

Source URL: www.quantsol.org

• Nanotechnology
• Physics
• Emerging technologies
• Selenides
• Cadmium compounds
• Quantum dot
• Multiple exciton generation
• Superlattice
• Nanocrystal
• Nanomaterials
• Chemistry
• Quantum electronics

Supplementary Table S1. Calculated powder diffraction pattern of vapnikite (CuK1+2 = , geometry: Debye-Scherrer, no anomalous dispersion; condition: I > 2.00) h 0 –1 1

Source URL: www.minersoc.org

• Science
• Powder diffraction
• Dispersion
• Condensed matter physics
• Physics
• Diffraction
• Optics

PDF Document

Source URL: cml.harvard.edu

• Colloidal chemistry
• Emerging technologies
• Electrochemistry
• Analytical chemistry
• Nanoelectronics
• Debye length
• Nanowire
• Graphene
• Biosensor
• Chemistry
• Physics
• Electromagnetism

Journal of Computational Physics[removed]–597 www.elsevier.com/locate/jcp Modeling ion extraction from a free-plasma surface with a flexible conformal mesh Stanley Humphries Jr

Source URL: www.fieldp.com

• Ion source
• Plasma
• Debye sheath
• Electric current
• Ion gun
• Duoplasmatron
• Plasma physics
• Physics
• Chemistry

PHYSICAL REVIEW E 70, Saturation of conductance in single ion channels: The blocking effect of the near reaction field Boaz Nadler,1,* Zeev Schuss,2,† Uwe Hollerbach,3,‡ and R. S. Eisenberg3,§ 1

Source URL: www.wisdom.weizmann.ac.il

• Electrophysiology
• Cell communication
• Integral membrane proteins
• Cellular neuroscience
• Membrane potential
• Debye–Hückel theory
• Debye length
• Potassium channel
• Implicit solvation
• Biology
• Chemistry
• Electrochemistry

Debye-Hückel Theory 1. assume complete dissociation of strong electrolytes 2. ionic atmosphere decreases chemical potential (have to do more work to pull ion out of solution)

Source URL: www.colby.edu

Poisson-Boltzmann Equation Electrolyte Solutions ρi(r) = qi p(r) = charge density = charge per unit volume (r) ∇·[ε(r)∇·φi(r)] = εr = 1

Source URL: www.colby.edu

• Science
• Physics
• Poisson–Boltzmann equation
• Polarization density
• Maxwell–Boltzmann distribution
• Debye–Hückel theory
• Chemistry
• Colloidal chemistry
• Physical chemistry