Dams, D.
, Kosik, M.
, Muller, M.
, Ghosh, A.
, Babaze, A.
, Szczuczko, J.
, Bryant, G.
, Ayuela, A.
, Rockstuhl, C.
, Pelc, M.
and Slowik, K.
(2025),
GRANAD - Simulating GRAphene nanoflakes with ADatoms, Computer Physics Communications, [online], https://doi.org/10.1016/j.cpc.2025.109818, https://tsapps.nist.gov/publication/get_pdf.cfm?pub_id=957737
(Accessed September 30, 2025)
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GRANAD - Simulating GRAphene nanoflakes with ADatoms
Published
Author(s)
David Dams, Miriam Kosik, Marvin Muller, Abhishek Ghosh, Antton Babaze, Julia Szczuczko, , Andres Ayuela, Carsten Rockstuhl, Marta Pelc, Karolina Slowik
Abstract
GRANAD is a new program based on the tight-binding approximation to simulate optoelectronic properties of graphene nanoflakes and Su–Schrieffer–Heeger (SSH) chains with possible adatom defects under electromagnetic illumination. Its core feature is the numerical solution of a time-domain master equation for the spin-traced one-particle reduced density matrix. It offers direct time-resolved insights into the evolution of charge distribution, access to induced field dynamics, and characteristics of the plasmonic response. Other computable quantities include energy profiles, electron distribution in real space, and absorption spectra. GRANAD is written in Python and relies on the JAX library for high-performance array computing, just-in-time compilation, and differentiability. It is intended to be lightweight, portable, and easy to set up, offering a transparent and efficient way to access the properties of low-dimensional carbon structures from the nanoscale to the mesoscopic regime. GRANAD is open source, with the full code and documentation available at https://github.com/GRANADlauncher/granad.git.Citation
Computer Physics Communications
Volume
317
Pub Type
Journals
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Keywords
Simulations, graphene, Su-Schrieffer-Heeger model, time-domain master equation
Citation
Issues
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Created August 26, 2025, Updated September 23, 2025