Finite‐Difference Time‐Domain Simulation of Strong‐Field Ionization: A Perfectly Matched Layer Approach

Høgni C. Kamban; Sigurd S. Christensen; Thomas Søndergaard; Thomas G. Pedersen

doi:10.1002/pssb.201900467

Finite‐Difference Time‐Domain Simulation of Strong‐Field Ionization: A Perfectly Matched Layer Approach

Høgni C. Kamban, Sigurd S. Christensen, Thomas Søndergaard, Thomas G. Pedersen

Náttúruvísindadeildin - Faculty of Science and Technology

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

A finite-difference time-domain (FDTD) scheme with perfectly matched layers (PMLs) is considered for solving the time-dependent Schrödinger equation and simulating the laser-induced ionization of two systems: 1) an electron initially bound to a 1D δ potential and 2) excitons in carbon nanotubes (CNTs). The performance of PMLs based on different absorption functions is compared, where slowly growing functions are found to be preferable. PMLs are shown to be able to reduce the computational domain, and thus the required numerical resources, by several orders of magnitude. This is demonstrated by testing the proposed method against an FDTD approach without PMLs and a very large computational domain. It is shown that PMLs outperform the well-known exterior complex scaling (ECS) technique for short-range potentials when implemented in FDTD. For long-range potentials such as in CNTs, however, ECS performs better than PMLs when propagating over many periods.

Original language	English
Article number	1900467
Number of pages	11
Journal	physica status solidi (b)
Volume	257
Issue number	5
DOIs	https://doi.org/10.1002/pssb.201900467
Publication status	Published - 25 May 2020

Keywords

ionization

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10.1002/pssb.201900467

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title = "Finite‐Difference Time‐Domain Simulation of Strong‐Field Ionization: A Perfectly Matched Layer Approach",

abstract = "A finite-difference time-domain (FDTD) scheme with perfectly matched layers (PMLs) is considered for solving the time-dependent Schr{\"o}dinger equation and simulating the laser-induced ionization of two systems: 1) an electron initially bound to a 1D δ potential and 2) excitons in carbon nanotubes (CNTs). The performance of PMLs based on different absorption functions is compared, where slowly growing functions are found to be preferable. PMLs are shown to be able to reduce the computational domain, and thus the required numerical resources, by several orders of magnitude. This is demonstrated by testing the proposed method against an FDTD approach without PMLs and a very large computational domain. It is shown that PMLs outperform the well-known exterior complex scaling (ECS) technique for short-range potentials when implemented in FDTD. For long-range potentials such as in CNTs, however, ECS performs better than PMLs when propagating over many periods.",

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author = "Kamban, {H{\o}gni C.} and Christensen, {Sigurd S.} and Thomas S{\o}ndergaard and Pedersen, {Thomas G.}",

year = "2020",

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doi = "10.1002/pssb.201900467",

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T1 - Finite‐Difference Time‐Domain Simulation of Strong‐Field Ionization

T2 - A Perfectly Matched Layer Approach

AU - Kamban, Høgni C.

AU - Christensen, Sigurd S.

AU - Søndergaard, Thomas

AU - Pedersen , Thomas G.

PY - 2020/5/25

Y1 - 2020/5/25

N2 - A finite-difference time-domain (FDTD) scheme with perfectly matched layers (PMLs) is considered for solving the time-dependent Schrödinger equation and simulating the laser-induced ionization of two systems: 1) an electron initially bound to a 1D δ potential and 2) excitons in carbon nanotubes (CNTs). The performance of PMLs based on different absorption functions is compared, where slowly growing functions are found to be preferable. PMLs are shown to be able to reduce the computational domain, and thus the required numerical resources, by several orders of magnitude. This is demonstrated by testing the proposed method against an FDTD approach without PMLs and a very large computational domain. It is shown that PMLs outperform the well-known exterior complex scaling (ECS) technique for short-range potentials when implemented in FDTD. For long-range potentials such as in CNTs, however, ECS performs better than PMLs when propagating over many periods.

AB - A finite-difference time-domain (FDTD) scheme with perfectly matched layers (PMLs) is considered for solving the time-dependent Schrödinger equation and simulating the laser-induced ionization of two systems: 1) an electron initially bound to a 1D δ potential and 2) excitons in carbon nanotubes (CNTs). The performance of PMLs based on different absorption functions is compared, where slowly growing functions are found to be preferable. PMLs are shown to be able to reduce the computational domain, and thus the required numerical resources, by several orders of magnitude. This is demonstrated by testing the proposed method against an FDTD approach without PMLs and a very large computational domain. It is shown that PMLs outperform the well-known exterior complex scaling (ECS) technique for short-range potentials when implemented in FDTD. For long-range potentials such as in CNTs, however, ECS performs better than PMLs when propagating over many periods.

KW - ionization

UR - https://doi.org/10.1002/pssb.201900467

U2 - 10.1002/pssb.201900467

DO - 10.1002/pssb.201900467

M3 - Article

SN - 1521-3951

VL - 257

JO - physica status solidi (b)

JF - physica status solidi (b)

IS - 5

M1 - 1900467

ER -

Finite‐Difference Time‐Domain Simulation of Strong‐Field Ionization: A Perfectly Matched Layer Approach

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Keywords

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