An initial value algorithm examines the time-dependent evolution of electromagnetic fields from oblique scattering of bounded pulses from an infinite planar dielectric interface. The qubit lattice algorithm (QLA) is utilized, which is almost fully unitary, leading to excellent conservation of electromagnetic energy. The dataset was created by Min Soe, George Vahala, Linda Vahala, Efstratios Koukoutsis, Abhay K. Ram, and Kyriakos Hizanidis and was last updated on June 23, 2026.
Use Cases
- Simulating electromagnetic energy conservation based on the almost fully unitary qubit lattice algorithm (QLA).
- Analyzing transmitted pulse shapes based on the combination of Gaussian envelopes and Huygen-like wavefronts described.
- Studying the effect of incident pulse width on wavefront strength as mentioned in the description.
- Modeling oblique scattering of Gaussian envelope pulses below the total internal reflection angle.
Strengths
- Excellent conservation of electromagnetic energy due to the almost fully unitary qubit lattice algorithm (QLA).
- Examines various Gaussian envelope pulses in specific scattering regimes.
- Authored by a team of six researchers from the Plasma Science and Fusion Center Dataverse.
Limitations
- Column-level documentation is absent; field semantics must be inferred after download.
- Row count is unknown, which may limit suitability assessment.
- Description metadata is limited; actual data quality requires manual inspection after download.
Provenance
- Source
- Plasma Science and Fusion Center Dataverse
- Collection Method
- Simulation using an initial value algorithm and the qubit lattice algorithm (QLA).
- Freshness
- Last updated 2026-06-23 16:59:14; freshness should be verified.