Differentiable RHEED simulations and Reconstruction in JAX
Project description
Rheedium
High-Performance RHEED Pattern Simulation for Crystal Surface Analysis
A JAX-accelerated Python package for realistic Reflection High-Energy Electron Diffraction (RHEED) pattern simulation using kinematic theory and atomic form factors.
Documentation • Installation • Quick Start • Examples • Contributing
Overview
Rheedium is a modern computational framework for simulating RHEED patterns with scientific rigor and computational efficiency. Built on JAX for automatic differentiation and GPU acceleration, it provides researchers with tools to:
- Simulate realistic RHEED patterns using Ewald sphere construction and kinematic diffraction theory
- Analyze crystal surface structures with atomic-resolution precision
- Handle complex reconstructions including domains, supercells, and surface modifications
- Leverage high-performance computing with JAX's JIT compilation and GPU support
Key Features
- JAX-Accelerated: GPU-ready computations with automatic differentiation
- Physically Accurate: Kirkland atomic potentials and kinematic scattering theory
- Comprehensive Analysis: Support for CIF files, surface reconstructions, and domains
- Visualization Tools: Phosphor screen colormap and interpolation for realistic display
- Research-Ready: Designed for thin-film growth, MBE, and surface science studies
Installation
Prerequisites
- Python 3.8 or higher
- CUDA-compatible GPU (optional, for acceleration)
Install from PyPI
pip install rheedium
Install for Development
git clone https://github.com/your-username/rheedium.git
cd rheedium
pip install -e ".[dev]"
Dependencies
- JAX (with GPU support if available)
- NumPy
- Matplotlib
- SciPy
- Pandas
- Beartype (for runtime type checking)
Quick Start
Basic RHEED Simulation
import rheedium as rh
import jax.numpy as jnp
# Load crystal structure from CIF file
crystal = rh.inout.parse_cif("data/SrTiO3.cif")
# Simulate RHEED pattern
pattern = rh.simul.simulate_rheed_pattern(
crystal=crystal,
voltage_kV=10.0, # Beam energy
theta_deg=2.0, # Grazing angle
detector_distance=1000.0 # Screen distance (mm)
)
# Visualize results
rh.plots.plot_rheed(pattern, interp_type="cubic")
Working with Surface Reconstructions
# Filter atoms within penetration depth
filtered_crystal = rh.ucell.atom_scraper(
crystal=crystal,
zone_axis=jnp.array([0, 0, 1]), # Surface normal
penetration_depth=5.0 # Angstroms
)
# Simulate pattern for surface layer
surface_pattern = rh.simul.simulate_rheed_pattern(
crystal=filtered_crystal,
voltage_kV=15.0,
theta_deg=1.5
)
Advanced Analysis
# Generate reciprocal lattice points
reciprocal_points = rh.ucell.generate_reciprocal_points(
crystal=crystal,
hmax=5, kmax=5, lmax=2
)
# Calculate kinematic intensities
intensities = rh.simul.compute_kinematic_intensities(
positions=crystal.cart_positions[:, :3],
G_allowed=reciprocal_points
)
Examples
1. Single Crystal Analysis
import rheedium as rh
# Load SrTiO3 structure
crystal = rh.inout.parse_cif("examples/SrTiO3.cif")
# High-resolution simulation
pattern = rh.simul.simulate_rheed_pattern(
crystal=crystal,
voltage_kV=30.0,
theta_deg=1.0,
hmax=6, kmax=6, lmax=2,
tolerance=0.01
)
# Create publication-quality plot
rh.plots.plot_rheed(
pattern,
grid_size=400,
interp_type="cubic",
cmap_name="phosphor"
)
2. Surface Reconstruction Study
# Analyze (√13×√13)-R33.7° reconstruction
reconstructed_crystal = rh.ucell.parse_cif_and_scrape(
cif_path="data/SrTiO3.cif",
zone_axis=jnp.array([0, 0, 1]),
thickness_xyz=jnp.array([0, 0, 3.9]) # Single unit cell
)
# Compare patterns at different azimuths
azimuths = [0, 15, 30, 45]
patterns = []
for azimuth in azimuths:
# Rotate crystal
rotation_matrix = rh.ucell.build_rotation_matrix(azimuth)
rotated_crystal = rh.ucell.rotate_crystal(reconstructed_crystal, rotation_matrix)
# Simulate pattern
pattern = rh.simul.simulate_rheed_pattern(rotated_crystal, theta_deg=2.6)
patterns.append(pattern)
3. Domain Analysis
# Multi-domain simulation
domains = []
for rotation_angle in [33.7, -33.7]: # Twin domains
rotated_crystal = rh.ucell.rotate_crystal(crystal, rotation_angle)
domain_pattern = rh.simul.simulate_rheed_pattern(rotated_crystal)
domains.append(domain_pattern)
# Combine domain contributions
combined_pattern = rh.types.combine_rheed_patterns(domains)
Supported File Formats
- CIF files: Crystallographic Information Format with symmetry operations
- CSV data: Kirkland atomic potential parameters
- Image formats: PNG, TIFF, SVG for visualization output
Configuration
Performance Optimization
import jax
# Enable 64-bit precision
jax.config.update("jax_enable_x64", True)
# Use GPU if available
jax.config.update("jax_platform_name", "gpu")
# JIT compilation for speed
@jax.jit
def fast_simulation(crystal, voltage):
return rh.simul.simulate_rheed_pattern(crystal, voltage_kV=voltage)
Custom Atomic Potentials
# Use custom Kirkland parameters
custom_potential = rh.simul.atomic_potential(
atom_no=38, # Strontium
pixel_size=0.05,
sampling=32,
potential_extent=6.0,
datafile="custom_potentials.csv"
)
Applications
Rheedium is designed for researchers working in:
- Molecular Beam Epitaxy (MBE): Real-time growth monitoring and optimization
- Pulsed Laser Deposition (PLD): Surface quality assessment and phase identification
- Surface Science: Reconstruction analysis and domain characterization
- Materials Engineering: Thin film quality control and defect analysis
- Method Development: New RHEED analysis technique validation
Documentation
Full documentation is available at rheedium.readthedocs.io, including:
- API Reference: Complete function and class documentation
- Tutorials: Step-by-step guides for common workflows
- Theory Guide: Mathematical background and implementation details
- Examples Gallery: Real-world usage scenarios with code
Contributing
We welcome contributions from the community! Please see our Contributing Guide for details on:
- Code style and standards
- Testing requirements
- Documentation guidelines
- Pull request process
Development Setup
git clone https://github.com/your-username/rheedium.git
cd rheedium
pip install -e ".[dev,test,docs]"
pre-commit install
Running Tests
pytest tests/
pytest --cov=rheedium tests/ # With coverage
License
This project is licensed under the MIT License - see the LICENSE file for details.
Citation
If you use Rheedium in your research, please cite:
@software{rheedium2024,
title={Rheedium: High-Performance RHEED Pattern Simulation},
author={Mukherjee, Debangshu},
year={2025},
url={https://github.com/debangshu-mukherjee/rheedium},
version={2025.6.16},
doi={10.5281/zenodo.14757400},
}
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