What question did this study set out to answer?

The aim is to demonstrate a pressure amplifier that enhances the performance of single-stage gas launchers.

April 17, 2026Open Access

Pressure amplification in single-stage gas launchers via Mach-stem formation

Key Points

The aim is to demonstrate a pressure amplifier that enhances the performance of single-stage gas launchers.
Designed using hydrodynamic simulations.
Utilized convergent shock geometry to amplify pressure.
Captured shock front evolution with ultrahigh speed x-ray phase-contrast imaging.
Measured velocity history of samples using photonic doppler velocimetry.
Achieved pressure amplification of up to 4.3 times compared to direct impact.
Observed maximum pressures of 40 GPa in copper and iron samples.
Documented phase-transition kinetics in iron with α–ϵ transitions.

Abstract

We present a pressure amplifier that integrates with single-stage gas launchers and enhances the accessible range of sample pressure states. The design of the amplifier was guided by hydrodynamic simulations. Using a convergent shock geometry, the amplifier generates pressures of up to 4.3 times greater than those achievable through direct impact. The evolution of the shock fronts through the amplifier was captured using ultrahigh speed x-ray phase-contrast imaging, and the velocity history of shocked samples was measured using photonic Doppler velocimetry to ascertain output pressures of the amplifier. Pressures of up to 40 GPa were observed in copper and iron samples as well as the observation of phase-transition kinetics in iron (α–ϵ transition). These results demonstrate the utility of the pressure amplifier in allowing a wider range of material phase space to be explored with single-stage guns.

Pressure amplification in single-stage gas launchers via Mach-stem formation

Key Points

Abstract

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