Application of recoil-imaging time projection chambers to directional neutron background measurements in the SuperKEKB accelerator tunnel

TL;DR

This study demonstrates the use of advanced gaseous TPCs for directional neutron background measurements in the SuperKEKB tunnel, validating simulation models and identifying neutron hotspots with high angular resolution.

Contribution

First application of recoil-imaging TPCs for directional neutron background measurement in an accelerator environment, with validation against simulations and new insights into neutron hotspots.

Findings

High recoil purity achieved at low energies

Good agreement between measured and simulated spectra in most detectors

First experimental evidence of localized neutron hotspots

Abstract

Gaseous time projection chambers (TPCs) with high readout segmentation are capable of reconstructing detailed 3D ionization distributions of nuclear recoils resulting from elastic neutron scattering. Using a system of six compact TPCs with pixel ASIC readout, filled with a 70:30 mixture of He:CO$_2$ gas, we analyze the first directional measurements of beam-induced neutron backgrounds in the tunnel regions surrounding the Belle II detector at the SuperKEKB $e^+e^-$ collider. With the use of 3D recoil tracking, we show that these TPCs are capable of maintaining nearly $100\%$ nuclear recoil purity to reconstructed ionization energies ($E_\text{reco}$) as low as 5 $\mathrm{keV_\text{ee}}$. Using a large sample of simulated $^4$He, $^{12}$C, and $^{16}$O recoil tracks, we find consistency between predicted and measured recoil energy spectra in five of the six TPCs, providing useful validation of the neutron production mechanisms modeled in simulation. Restricting this sample to $^4$He recoil tracks with $E_\text{reco}>40$ $\mathrm{keV_\text{ee}}$, we demonstrate axial angular resolutions within $8^{\circ}$ and we introduce a procedure that under suitable conditions, correctly assigns the vector direction to $91\%$ of simulated $^4$He recoils. Applying this procedure to assign vector directions to measured $^4$He recoil tracks, we observe consistency between the angular distributions of observed and simulated recoils, providing first experimental evidence of localized neutron "hotspots" in the accelerator tunnel. Observed rates of nuclear recoils in these TPCs suggest that simulation overestimates the neutron flux from these hotspots.