# Microstructural and Mechanical Characterization of Ultra-Pure Aluminum for Low-Amplitude-Vibration Cryogenic Applications

**Authors:** Mirko Pigato, Filippo Agresti, Alberto Benato, Carlo Bucci, Irene Calliari, Daniele Cortis, Serena D’Eramo, Shihong Fu, Cristina Giancarli, Luca Pezzato, Andrea Zambon, Antonio D’Addabbo

PMC · DOI: 10.3390/ma19061195 · 2026-03-18

## TL;DR

This paper studies ultra-pure aluminum's mechanical and microstructural properties for use in cryogenic systems that require minimal vibration.

## Contribution

The study provides new insights into the cryogenic mechanical behavior and microstructure of ultra-high-purity aluminum grades.

## Key findings

- Mechanical properties of UHP-Al grades were evaluated from room temperature to -150°C.
- Microstructural analysis showed a strong correlation between material structure and elastic behavior.
- Results offer guidelines for using UHP-Al in cryogenic systems requiring vibration control.

## Abstract

In fundamental physics, sensors operating below liquid helium temperatures are highly vulnerable to vibrations, which can affect the sensitivity, for example, of high-performance particle detectors. Pulse-tube refrigerators, while generating vibrations lower than those of conventional systems, may still introduce several disturbances. Hence, flexible thermal connections are a commonly used mechanical solution to mitigate these undesirable effects. Among the materials that can be used, ultra-high-purity aluminum (UHP-Al) has attracted the attention for low-amplitude-vibration cryogenic applications, including gravitational wave interferometry, quantum information systems, precision space instrumentation, and cryogenic resonators. Thus, the aim of the paper is the characterization of the mechanical and microstructure properties of three UHP-Als (i.e., 5N—99.999 wt%, 5N5—99.9995 wt% and 6N—99.9999 wt%) intended for the production of thermal flexible connections with low stiffness, specifically designed to reduce vibration transmission in cryogenic environments. Mechanical properties were evaluated through standard tensile tests from room (+25 °C) to low temperature (i.e., −150 °C), providing insights into yield strength, ultimate tensile strength, elongation and elastic modulus. In addition, the dynamic elastic modulus of material loads, at cryogenic conditions (i.e., about −180 °C), was determined by measuring the natural resonance frequency, thereby assessing the material’s response to vibrational. Moreover, an extensive microstructural analysis was conducted using electron backscatter diffraction and x-ray diffraction. The correlation between the observed microstructure and the elastic properties was systematically examined. The results underscore the pivotal role of microstructural characteristics in dictating the elastic behavior of UHP Als. Eventually, the analysis provides valuable guidelines for the materials employment inside cryogenic systems, where severe vibration control is critical to maintain high operational performance.

## Full-text entities

- **Chemicals:** 5N5 (-), 5N (MESH:C005072), aluminum (MESH:D000535)

## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/PMC13027578/full.md

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Source: https://tomesphere.com/paper/PMC13027578