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Eötvös Quantum Utilities
v4.8.141
Providing the Horsepowers in the Quantum Realm
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adaptiveQ.m | A class providing adaptive distribution of the transverse momentum points |
antidot.m | A class to perform transport calculations on a graphene antidot (i.e., a hollow in a ribbon) |
automatic_test.m | Launches the automatic test procedure |
automatic_test_MEX.m | |
CalculateTransporSpecq.m | Function to calculate the DC transverse momentum resolved conductivity in the zero temperature limit |
CombineRibbons.m | |
CommonFunctions.m | A class containing common basic functionalities |
Coordinates.m | Structure containing the coordinates and other quantum number identifiers of the sites in the Hamiltonians |
CreateHamiltonians.m | A class to create and store Hamiltonian of the scattering region |
CreateLeadHamiltonians.m | Class to create and store Hamiltonian of the translational invariant leads |
createOutput.m | This function creates an output file containing the running parameters |
Custom_Hamiltonians.m | A class to import custom Hamiltonians provided by other codes or created manually |
Decimation.m | A class providing function handle to reduce the number of sites in the Hamiltonian via decimation procedure |
dgetPartialInv.c | Gateway routine to call the dgetPartialInv subroutine from the mkl_EQuUs package |
dgetPartialInv_test.m | |
dggev.c | Gateway routine to call the dggev function from LAPACKE package |
dggev_test.m | |
Differential_conductance.m | Example to calculate the differential conductance and the IV curve through a junction made of a square lattice |
documentationGuidelines.m | Documentation guidelines to extract documentation using Doxygen |
Download.m | |
EigenProblemLead.m | Class to solve the eigenproblem of a translational invariant leads and calculate the group velocities |
EQuUs_C.f90 | An EQuUs element prototype |
EQuUs_MATLAB.cpp | |
EQuUs_MATLAB.h | |
FAQ.m | |
FermiDirac.m | A class describing the Fermi Dirac distribution of fermionic particles |
Fox_sax_EQuUs.f90 | Deallocates the XML node |
gauge_field.m | Scalar gauge field connecting Landaux and Landauy gauges |
getPartialInv.F90 | Module to calculate the partial inverse of a real/complex sparse matrix via the PARDISO libraries |
Graphene_antidot_transport.m | Calculates the conductance through a graphene antidot in a homogeneous magnetic field |
Graphene_Conductivity.m | Example to calculate the conductivity through a wide (4 micron) graphene junction |
Graphene_QAD_eig.m | Example to calculate the eigenstates of quantum antidots |
Hex_Lead_Hamiltonians.m | A class to create the Hamiltonian of one unit cell in a translational invariant lead made of hexagonal lattice structure, including graphene and silicene |
hsx_EQuUs.f90 | Converts an array of XML subnodes into an EQstruct structure prototypes |
InterfaceRegion.m | A class describing the interface region between the scattering region and a lead |
IV.m | A class to calculate the I-V curve for a two terminal setup, based on the non-equilibrium Greens function technique of Eur |
JosephsonCurrent.m | Example to calculate DC Josephson current through a one-dimensional chain |
Landaux.m | Vector potential in the Landau gauge parallel to the x direction |
Landauy.m | Vector potential in the Landau gauge parallel to the y direction |
Lead.m | A class to calculate the Green functions and self energies of a translational invariant lead |
LoadFromFile.m | A class providing interface to load variables from a file |
magnetic_barrier.m | Example to calculate the conductivity through a magnetic barrier |
magnetic_ribbon.m | |
main.m | |
MatrixIO.F90 | |
Messages.m | A class containing methodes for displaying several standard messages |
MinimalConductivity.m | Calculates the minimal conductivity of the graphene sheet as a function of the aspect ratio |
NTerminal.m | A class describing an N-terminal geometry for equilibrium calculations mostly in the zero temperature limit |
Parallel.m | A class for controlling the parallel pool for paralell computations |
parseInput.m | This function parses the input file containing the input parameters |
Peierls.m | A class responsible for the Peierls and gauge transformations |
read_hsx.cpp | |
read_SiestaXML.cpp | |
Ribbon.m | A class for calculations on a ribbon of finite width for equilibrium calculations mostly in the zero temperature limit |
ScatterPotential.m | Function for island shaped hard-wall potential profile |
SNSJosephson.m | A class to calculate the DC Josephson current |
SpectralDensity.m | Example to calculates the spectral density function in a superconductor-graphene-superconductor junction |
Square_Lead_Hamiltonians.m | Class to create the Hamiltonian of one unit cell in a translational invariant lead made of square lattice structure, including the SSH model |
SSH_Josephson.m | |
SSH_transport.m | |
structures.m | |
Surface_Green_function.m | A class to calculate the Green functions and self energies of a translational invariant lead |
SVDregularizationLead.m | Class to regulerize the H1 problem of the leads by SVD decompozition |
Transport_Interface.m | A class to evaluate the Dyson equation and to calculate the scattering matrix for equilibrium processes |
UtilsBase.m | This class is a base class containing common properties and methods utilized in several other classes |
XML.f90 | Determines whether the XML node has subnodes or not |
XMLinput.m | |
XMLoutput.m | |
zgetPartialInv.c | Gateway routine to call the zgetpartialinv subroutine from the mkl_EQuUs package |
zgetPartialInv_test.m | |
zggev.c | Gateway routine to call the zggev function from LAPACKE package |
zggev_test.m |