Approximate resolution convolution function for fitting a dispersion gap measured on a triple-axis spectrometer
Abstract
We present an analytic convoluted-gap function, eq. 11 in the manuscript, for fitting dispersion gaps measured on triple-axis spectrometers (TAS). At the gap, the instrumental resolution skews the signal, producing a high-energy tail that complicates fitting. Our function assumes an instrumental -resolution with two equal wide and one narrow direction (typical of focused TAS instruments), and a parabolic dispersion at the gap, which is exact for quadratic and accurate for linear dispersions if the resolution is moderate. We demonstrate, that our function outperforms previous methods of fitting a gap, by giving a better fit and more accurate gap determination, seen in figure 4. Here, the anti-ferromagnetically gapped material; MnF is simulated in a double-focusing TAS instrument. We also tested our function on experimental data on MnF from a TAS-like instrument, where we reproduce the gap size from previous accurate experimentally determined measurements. The function is simple to implement, converges reliably, and we recommend its use for future gap fitting on TAS data.
Cite
@article{arxiv.2511.19144,
title = {Approximate resolution convolution function for fitting a dispersion gap measured on a triple-axis spectrometer},
author = {Emma Y. Lenander and Silas B. Schack and Kim Lefmann and Henrik M. Rønnow},
journal= {arXiv preprint arXiv:2511.19144},
year = {2025}
}