Calculators Created by Abhijit gharphalia

Electronic Structure in Clusters and Nanoparticles (8)

Created Coulomb Energy of Charged Particle using Radius of Cluster

Created Coulomb Energy of Charged Particle using Wigner Seitz radius

Created Energy Deficiency of Curvature containing Cluster Surface

Created Energy Deficiency of Plane Surface using Binding Energy Deficiency

Created Energy Deficiency of Plane Surface using Surface Tension

Created Energy of Liquid Drop in Neutral System

Created Energy per Unit Volume of Cluster

Created Radius of Cluster using Wigner Seitz Radius

Förster resonance energy transfer (11)

Created Donor Lifetime using Rates of Transitions

Created Donor Lifetime with FRET using Rate of Energy and Transitions

Created Efficiency of Energy Transfer using Distances

Created Efficiency of Energy Transfer using Donor Lifetime

Created Efficiency of Energy Transfer using Fluorescence Intensity of Donor

Created Efficiency of Energy Transfer using Photobleaching Decay Time Constant

Created Efficiency of Energy Transfer using Rate of Energy Transfer

Created Efficiency of Energy Transfer using Rate of Energy Transfer and Donor Lifetime

Created Fluorescence Quantum Yield in FRET

Created Forster Critical Distance

Created Rate of Energy Transfer using Distances and Donor Lifetime

Magnetism in Nanomaterials (5)

Created Anisotropy Field using Spontaneous Magnetization

Created Average Anisotropy using Anisotropy Constant

Created Average Anisotropy using Diameter and Thickness

Created Energy of Propagation using Specific Surface Energy

Created Uniaxial Anisotropy Energy per Unit Volume using Anisotropy Constant

Mechanical and Nanomechanical Properties (8)

Created Depth during Indentation using Displacement of Surface and Depth of Contact

Created Depth of Contact using Depth during Indentation and Displacement of Surface

Created Depth of Contact using Maximum Depth and Displacement of Surface

Created Displacement of Surface using Depth during Indentation and Depth of Contact

Created Displacement of Surface using Final Depth and Maximum Depth

Created Displacement of Surface using Maximum Depth and Depth of Contact

Created Maximum Depth using Depth of Contact and Displacement of Surface

Created Maximum Depth using Final Depth and Displacement of Surface

Nanocomposites The End of Compromise (4)

Created Diffusion Coefficient of Solute in Composite given Volume Fraction

Created Diffusion Coefficient of Solute in Polymer Matrix given Volume Fraction

Created Tortuosity Coefficient using Diffusion Coefficient of Solute

Created Tortuosity Coefficient using Thickness and Diameter of Disks

Optical Properties of Metallic Nanoparticles (23)

Created Average Electron Density using Electron Density and Electron diameter

Created Average Electron Density using Nanoparticle Density and Spill-out Amplitude

Created Dipole moment of Sphere using Polarization due to Sphere

Created Electron Density using Average Electron Density and Electron diameter

Created Electron Density using Average Electron Density and Spill-out Amplitude

Created Electron Diameter using Nanoparticle Diameter and Spill-out Amplitude

Created Incident Field using Local Field and Polarization

Created Intrinsic Electron Collision Frequency using Total Collision Rate

Created Local field using Incident Field and Polarization

Created Nanoparticle Diameter using Electron Diameter and Spill-out Amplitude

Created Number of Nanoparticles using Volume Fraction and Volume of Nanoparticle

Created Polarization Due to Metallic Particle using Dielectric Constants and Incident Field

Created Polarization Due to Metallic Particle using Total Polarization and Polarization Due to Sphere

Created Polarization due to Sphere using Dipole moment of Sphere

Created Polarization due to Sphere using Local field and Incident Field

Created Polarization Due to Sphere using Polarization Due to Metallic Particle and Total Polarization

Created Spill-out Amplitude using Nanoparticle Diameter and Electron Diameter

Created Total Collision Rate using Intrinsic Electron Collision Frequency

Created Total Polarization of Composite Material using Dielectric Constants and Incident Field

Created Total Polarization of Composite Material using Polarization due to Metallic Particle and Sphere

Created Volume Fraction using Polarization and Dipole Moment of Sphere

Created Volume Fraction using Volume of Nanoparticles

Created Volume of Nanoparticles using Volume Fraction

Organometallic chemistry (6)

Created Number of Metal-Metal bond

Created Per Metal Number of Metal-Metal Bond

Created Polyhedral Electron Pair Count

Created Turn over Number given Turn over Frequency

Created Turnoover Number using Yield

Created Turnover Frequency from Turnover Number

Size Effects on Structure and Morphology of Free or Supported Nanoparticles (6)

Created Excess Pressure using Surface Energy and Radius

Created Generalized Free Energy using Surface Energy and Volume

Created Pressure Inside Grain

Created Specific Surface Energy using Pressure, Volume Change and Area

Created Specific Surface Energy using Work for Nanoparticles

Created Surface Stress using Work

List of Calculators by Abhijit gharphalia