# Ionoacoustic detection of swift heavy ions

**Authors:** Sebastian Lehrack, Walter Assmann, Markus Bender, Daniel Severin,, Christina Trautmann, J\"org Schreiber, Katia Parodi

arXiv: 1903.12170 · 2020-01-08

## TL;DR

This paper demonstrates the use of ionoacoustic detection to accurately measure the range of heavy ions in water, showing potential for precise particle monitoring in high-energy accelerator applications.

## Contribution

It introduces a novel ionoacoustic method for heavy ion range measurement at GeV energies, validated by experiments and simulations, suitable for future high-intensity beam monitoring.

## Key findings

- Range measurements agree with simulations within 1%
- Effective detection of acoustic signals from heavy ions
- Potential application in high-energy accelerator facilities

## Abstract

The maximum energy loss (Bragg peak) located near the end of range is a characteristic feature of ion stopping in matter, which generates an acoustic pulse, if ions are deposited into a medium in adequately short bunches. This so-called ionoacoustic effect has been studied for decades, mainly for astrophysical applications, and it has recently found renewed interest in proton therapy for precise range measurements in tissue. After detailed preparatory studies with 20 MeV protons at the MLL tandem accelerator, ionoacoustic range measurements were performed in water at the upgraded SIS18 synchrotron of GSI with 238U and 124Xe ion beams of energy about 300 MeV/u, and 12C ions of energy about 200 MeV/u using fast beam extraction to get 1 microsecond pulse lengths. Acoustic signals were recorded in axial geometry by standard piezo-based transducers at a 500 kHz mean frequency and evaluated in both the time and frequency domains. The resulting ranges for the different ions and energies were found to agree with Geant4 simulations as well as previous measurements to better than 1%. Given the high accuracy provided by ionoacoustic range measurements in water and their relative simplicity, we propose this new method for stopping power measurements for heavy ions at GeV energies and above. Our experimental results clearly demonstrate the potential of an ionoacoustic particle monitor especially for very intense heavy ion beams foreseen at future accelerator facilities.

---
Source: https://tomesphere.com/paper/1903.12170