AI-powered radiation detector simulation through natural language.
A single-file Model Context Protocol (MCP) server that connects Allpix^2 and Geant4 Monte Carlo simulation with Claude AI. Design, configure, run, and analyze pixelated radiation detector simulations by talking to Claude — no manual config writing needed.
Built by Rad Detect AI for the radiation detection and medical imaging community.
You talk to Claude. Claude calls the MCP tools. Allpix^2 runs your simulation.
You: "Simulate a 2mm CdZnTe detector, 110µm pitch, 20µm gap, -800V, 60 keV gammas, 5000 events"
Claude: → calls geant4_generate_allpix2_config
→ writes main.conf + detector model + geometry
→ runs: allpix -c main.conf
→ returns ROOT output with 5M+ objects
| # | Tool | What it does |
|---|---|---|
| 1 | geant4_generate_macro |
Generate Geant4 macro files (.mac) with geometry, physics, scoring |
| 2 | geant4_generate_allpix2_config |
Create complete Allpix^2 configs for pixel detector simulation |
| 3 | geant4_run_simulation |
Execute Allpix^2 or Geant4 simulations |
| 4 | geant4_analyze_results |
Analyze output — energy spectra, spatial maps, charge sharing |
| 5 | geant4_material_lookup |
Detector material database (CdZnTe, CdTe, Si, Ge, CsI, BGO, LYSO, GaAs) |
| 6 | geant4_generate_xray_spectrum |
Polyenergetic X-ray spectrum generation (W, Mo, Rh anodes) |
| 7 | geant4_list_files |
Browse workspace files |
| 8 | geant4_physics_calculator |
Hecht equation, Fano resolution, charge sharing, attenuation |
| 9 | geant4_workspace_status |
Check environment and available simulators |
- Python 3.10+
- Allpix^2 (with Geant4)
- Claude Code or Claude Desktop
mkdir -p ~/geant4-mcp-server && cd ~/geant4-mcp-server
python3 -m venv .venv && source .venv/bin/activate
pip install "mcp[cli]" pydantic httpx numpy uproot matplotlib scipyCopy geant4_mcp_server.py into ~/geant4-mcp-server/.
Verify:
python3 -c "from geant4_mcp_server import mcp; print('✅ Server OK:', mcp.name)"claude mcp add geant4-simulation -- ~/geant4-mcp-server/.venv/bin/python3 ~/geant4-mcp-server/geant4_mcp_server.pyStart Claude Code and type /mcp — you should see 9 tools from geant4-simulation.
Create ~/.config/Claude/claude_desktop_config.json:
{
"mcpServers": {
"geant4-simulation": {
"command": "/home/YOUR_USER/geant4-mcp-server/.venv/bin/python3",
"args": ["/home/YOUR_USER/geant4-mcp-server/geant4_mcp_server.py"],
"env": {
"GEANT4_MCP_WORKSPACE": "/home/YOUR_USER/geant4_mcp_workspace",
"GEANT4_INSTALL_DIR": "/opt/geant4"
}
}
}
}Restart Claude Desktop.
Simulate a CdZnTe photon-counting detector:
Generate an Allpix^2 config for a 2mm thick CdZnTe detector with 110µm pixel pitch and 20µm interpixel gap, biased at -800V. Simulate 60 keV gammas, 5000 events.
Look up material properties:
Compare the µτ products and Fano factors of CdZnTe vs CdTe vs Silicon.
Calculate detector performance:
What's the Fano-limited energy resolution of CdZnTe at 140 keV with 80 electrons of electronic noise?
Generate an X-ray spectrum:
Generate a 120 kVp tungsten anode spectrum with 2.5mm Al filtration for CT simulation.
Built-in properties for 9 detector materials:
| Material | Type | Z_eff | Density (g/cm³) |
|---|---|---|---|
| CdZnTe | Semiconductor | 49.1 | 5.78 |
| CdTe | Semiconductor | 50.0 | 5.85 |
| Si | Semiconductor | 14 | 2.33 |
| Ge | Semiconductor | 32 | 5.32 |
| GaAs | Semiconductor | 32 | 5.32 |
| CsI:Tl | Scintillator | 54 | 4.51 |
| CsI:Na | Scintillator | 54 | 4.51 |
| BGO | Scintillator | 73 | 7.13 |
| LYSO | Scintillator | 65 | 7.10 |
Includes mobility, µτ products, Fano factors, bandgap, pair creation energy, light yield, and more.
- Hecht equation — Charge collection efficiency vs bias voltage and thickness
- Fano-limited energy resolution — Fundamental resolution with electronic noise
- Charge sharing estimation — Diffusion-based interpixel charge sharing fraction
- Attenuation length — Photon mean free path in detector material
- Ubuntu 22.04 / 24.04 LTS
- Allpix^2 v3.0.0
- Geant4 11.2.2
- Python 3.11
- Claude Code v2.1
- Allpix^2 config generation + execution
- Material database (9 materials)
- Physics calculators (Hecht, Fano, charge sharing)
- X-ray spectrum generator
- ROOT file analysis with uproot
- GATE integration for medical imaging
- GDML geometry import/export
- RadDetect AI Academy integration
- MTF / NPS / DQE calculation tools
Elmaddin Guliyev, Ph.D. Founder, Rad Detect AI
Expertise: CdZnTe/CdTe photon-counting detectors, charge transport simulation, X-ray imaging systems, Monte Carlo (Geant4, Allpix^2).
MIT License