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Publication Year: 2021

291 to 300 of 369 Results

Unitary Transform between Radial and Cartesian Representation of the Spherical Harmonic Oscillator Basis May 4, 2021 - Quantum Mechanics Baumeister, Paul F., 2021, "Unitary Transform between Radial and Cartesian Representation of the Spherical Harmonic Oscillator Basis", https://doi.org/10.26165/JUELICH-DATA/MWHIW5, Jülich DATA, V1 The spherical harmonic oscillator is one of the most basic quantum mechanical problems with known analytical solutions in two representations: Radial and Cartesian. This data file provides the coefficient of the unitary transformation connecting the two representations.
sho_unitary.dat May 4, 2021 - Unitary Transform between Radial and Cartesian Representation of the Spherical Harmonic Oscillator Basis Fixed Field Text Data - 53.0 KB - SHA-256: 7790979cf69bcb4f2244044b59e80ef1c66f2c62960f44f208de4908a55e8adf integer coefficients for non-zero matrix elements up to \nu = 9
sho_unitary.F90 May 4, 2021 - Unitary Transform between Radial and Cartesian Representation of the Spherical Harmonic Oscillator Basis Unknown - 39.1 KB - SHA-256: a8266960a3590f57ce52ecb8e89c7b1dc5a6dfeb024bcb6e5aafae7e3d7bd1d0 generator code (Fortran 90)
sho_unitary.pdf May 4, 2021 - Unitary Transform between Radial and Cartesian Representation of the Spherical Harmonic Oscillator Basis Adobe PDF - 152.0 KB - SHA-256: 44fe93409e3a7c7f25629d88633bbebe220e1dca39002125f65d77f1259a144a Theory document
sho_unitary.tex May 4, 2021 - Unitary Transform between Radial and Cartesian Representation of the Spherical Harmonic Oscillator Basis LaTeX - 9.0 KB - SHA-256: 85755e92b24ab920dded995617f9faf5dd30ab2b4e44aceb17d5e908e49ff43d Theory document source
Model output from CAABA/MECCA obtained during the development of JAMOC Apr 23, 2021 - Institute of Climate and Energy Systems – Troposphere (ICE-3) Rosanka, Simon; Sander, Rolf; Wahner, Andreas; Taraborrelli, Domenico, 2021, "Model output from CAABA/MECCA obtained during the development of JAMOC", https://doi.org/10.26165/JUELICH-DATA/SD9F6B, Jülich DATA, V1 This dataset contains the model output from the box-model Chemistry As A Boxmodel Application (CAABA) using the Module Efficiently Calculating the Chemistry of the Atmosphere (MECCA) obtained during the development of the Jülich Aqueous-phase Mechanism of Organic Chemistry (JAMOC...
JAMOC_caaba_jval.nc Apr 23, 2021 - Model output from CAABA/MECCA obtained during the development of JAMOC Network Common Data Form - 224.3 KB - SHA-256: 029fae4e20e6b01d589f7748b76acd2378a59560ba8be0a4a2e9b6f4b71b4e35 Photolysis rates from the simulation using the Jülich Aqueous-phase Mechanism of Organic Chemistry (JAMOC).
JAMOC_caaba_mecca_aero.nc Apr 23, 2021 - Model output from CAABA/MECCA obtained during the development of JAMOC Network Common Data Form - 5.0 KB - SHA-256: 2dbe0b068fdc104b8cb7d5f3c78cc72e276c6de045bc9f9c1e992ba68e5dd70e Box-model physical properties (liquid water content) from the simulation using the Jülich Aqueous-phase Mechanism of Organic Chemistry (JAMOC).
JAMOC_caaba_mecca.nc Apr 23, 2021 - Model output from CAABA/MECCA obtained during the development of JAMOC Network Common Data Form - 1.7 MB - SHA-256: 90b866d23f994989ca5cf29b36f20a854563f4b2fff572bdd390fe9114ff8f41 Tracer mixing ratios from the simulation using the Jülich Aqueous-phase Mechanism of Organic Chemistry (JAMOC).
JAMOC_caaba_messy.nc Apr 23, 2021 - Model output from CAABA/MECCA obtained during the development of JAMOC Network Common Data Form - 8.2 KB - SHA-256: 637357ff81bbb761bee13453762a9a7a36c5645833d78799cb414e6e5c637373 Box-model physical properties (pressure, temperature, and solar zenith angle) from the simulation using the Jülich Aqueous-phase Mechanism of Organic Chemistry (JAMOC).

Unitary Transform between Radial and Cartesian Representation of the Spherical Harmonic Oscillator Basis

May 4, 2021 - Quantum Mechanics

Baumeister, Paul F., 2021, "Unitary Transform between Radial and Cartesian Representation of the Spherical Harmonic Oscillator Basis", https://doi.org/10.26165/JUELICH-DATA/MWHIW5, Jülich DATA, V1

The spherical harmonic oscillator is one of the most basic quantum mechanical problems with known analytical solutions in two representations: Radial and Cartesian. This data file provides the coefficient of the unitary transformation connecting the two representations.

sho_unitary.dat

May 4, 2021 - Unitary Transform between Radial and Cartesian Representation of the Spherical Harmonic Oscillator Basis

Fixed Field Text Data - 53.0 KB - SHA-256: 7790979cf69bcb4f2244044b59e80ef1c66f2c62960f44f208de4908a55e8adf

integer coefficients for non-zero matrix elements up to \nu = 9

sho_unitary.F90

May 4, 2021 - Unitary Transform between Radial and Cartesian Representation of the Spherical Harmonic Oscillator Basis

Unknown - 39.1 KB - SHA-256: a8266960a3590f57ce52ecb8e89c7b1dc5a6dfeb024bcb6e5aafae7e3d7bd1d0

generator code (Fortran 90)

sho_unitary.pdf

May 4, 2021 - Unitary Transform between Radial and Cartesian Representation of the Spherical Harmonic Oscillator Basis

Adobe PDF - 152.0 KB - SHA-256: 44fe93409e3a7c7f25629d88633bbebe220e1dca39002125f65d77f1259a144a

Theory document

sho_unitary.tex

May 4, 2021 - Unitary Transform between Radial and Cartesian Representation of the Spherical Harmonic Oscillator Basis

LaTeX - 9.0 KB - SHA-256: 85755e92b24ab920dded995617f9faf5dd30ab2b4e44aceb17d5e908e49ff43d

Theory document source

Model output from CAABA/MECCA obtained during the development of JAMOC

Apr 23, 2021 - Institute of Climate and Energy Systems – Troposphere (ICE-3)

Rosanka, Simon; Sander, Rolf; Wahner, Andreas; Taraborrelli, Domenico, 2021, "Model output from CAABA/MECCA obtained during the development of JAMOC", https://doi.org/10.26165/JUELICH-DATA/SD9F6B, Jülich DATA, V1

This dataset contains the model output from the box-model Chemistry As A Boxmodel Application (CAABA) using the Module Efficiently Calculating the Chemistry of the Atmosphere (MECCA) obtained during the development of the Jülich Aqueous-phase Mechanism of Organic Chemistry (JAMOC...

JAMOC_caaba_jval.nc

Apr 23, 2021 - Model output from CAABA/MECCA obtained during the development of JAMOC

Network Common Data Form - 224.3 KB - SHA-256: 029fae4e20e6b01d589f7748b76acd2378a59560ba8be0a4a2e9b6f4b71b4e35

Photolysis rates from the simulation using the Jülich Aqueous-phase Mechanism of Organic Chemistry (JAMOC).

JAMOC_caaba_mecca_aero.nc

Apr 23, 2021 - Model output from CAABA/MECCA obtained during the development of JAMOC

Network Common Data Form - 5.0 KB - SHA-256: 2dbe0b068fdc104b8cb7d5f3c78cc72e276c6de045bc9f9c1e992ba68e5dd70e

Box-model physical properties (liquid water content) from the simulation using the Jülich Aqueous-phase Mechanism of Organic Chemistry (JAMOC).

JAMOC_caaba_mecca.nc

Apr 23, 2021 - Model output from CAABA/MECCA obtained during the development of JAMOC

Network Common Data Form - 1.7 MB - SHA-256: 90b866d23f994989ca5cf29b36f20a854563f4b2fff572bdd390fe9114ff8f41

Tracer mixing ratios from the simulation using the Jülich Aqueous-phase Mechanism of Organic Chemistry (JAMOC).

JAMOC_caaba_messy.nc

Apr 23, 2021 - Model output from CAABA/MECCA obtained during the development of JAMOC

Network Common Data Form - 8.2 KB - SHA-256: 637357ff81bbb761bee13453762a9a7a36c5645833d78799cb414e6e5c637373

Box-model physical properties (pressure, temperature, and solar zenith angle) from the simulation using the Jülich Aqueous-phase Mechanism of Organic Chemistry (JAMOC).

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