ASAP is a powerful tool for investigating how materials behave under the extreme conditions found in high-energy physics, nuclear engineering, and aerospace. By automating atomistic workflows, ASAP helps researchers predict material durability and functionality in environments where experimental testing is often dangerous or prohibitively expensive.
Applications in High-Energy Research:
- Radiation Effects: Use ASAP to execute quantum-accurate “collision experiments” on individual atoms.
- Detector Design: Optimize the electronic and optical properties of materials to improve the energy resolution and light yield of sensors used in medical imaging and particle detection.
- Predictive Maintenance: Evaluate how high-energy environments impact the long-term structural integrity of components to predict operational lifespans.
Here are a few examples of how ASAP can be applied to solve challenges in high-energy environments:
- High-Energy Sensing: Scintillators
Learn how ASAP can be used to accelerate the discovery and performance characterisation of scintillator materials for high-energy physics. - Migration and Clustering in High-Energy Environments
See how atomistic simulations with ASAP reveal the mechanisms behind defect migration and material degradation. - Predicting Component Lifetime in High-Energy Environments
Discover how ASAP helps predict the durability of materials subjected to the extreme conditions of nuclear and high-energy applications.
Request your 30-day ASAP trial or Consult our experts about your electronic material challenges.