Electrohydrodynamics for Hall Effect Thrusters

Model Card

Model Overview

Model Name: mistral-7b-hall-thruster-fluid-dynamics
Model Type: Transformer-based language model
Languages: English
License: Apache License 2.0

This model is based on the Mistral-Large-Instruct-2411 foundation model and is being fine-tuned on the Taylor658/Electrohydrodynamics dataset. It is designed to assist with understanding electrohydrodynamics, plasma-fluid interactions, and related fluid dynamic phenomena in Hall Effect Thrusters (HETs).

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Model Details

• Developers: A Taylor
• Model Architecture: Transformer-based with enhancements for code generation and multimodal processing
• Parameters: 7 Billion
• Native Function Calling: Supported
• Multimodal Capabilities: Text-based domain discussions

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Intended Use

• Primary Applications: - Assist aerospace engineers and researchers in analyzing plasma and fluid flows in HET channels - Provide support for understanding electrohydrodynamics in propulsion systems - Facilitate research by offering computational assistance in modeling plasma-fluid interactions

• Usage Scenarios:
  • Discussing the influence of magnetic fields on electron mobility
  • Explaining ionization dynamics in the thruster discharge channel
  • Interpreting simulation data and theoretical results for efficiency and plume characteristics

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Training Data

• Dataset Name: Taylor658/Electrohydrodynamics
• Description: A dataset containing textual explanations, theoretical derivations, and computational concepts related to fluid dynamics and plasma interactions in Hall Effect Thrusters.
• Data Modalities:
  • Text: Technical documentation, research summaries, and theoretical analyses
  • Code:

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Training Procedure

The model will be fine tuned to enhance its capabilities in handling advanced fluid dynamics and plasma physics scenarios relevant to Hall Effect Thrusters. Key enhancements include:

1. Domain-Specific Fine-Tuning: Adjusting the model's parameters using the Taylor658/Electrohydrodynamics dataset to improve performance in electrohydrodynamics.
2. Validation and Testing: Ensuring the model’s outputs are accurate and reliable by comparing them against established literature and computational benchmarks.
3. Iterative Refinement: Continuously refining responses based on domain expert feedback and real-world problem sets.

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How to Use

• Input Format:
  • Natural language queries or prompts about electrohydrodynamics, fluid flow, or plasma phenomena in Hall Effect Thrusters.
• Examples:
  • "Explain how the Hall parameter affects electron mobility in a Hall Effect Thruster."
  • "What are the primary factors influencing ionization efficiency in the thruster channel?"

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Limitations

• Work in Progress: The model is currently being fine-tuned; performance may improve over time.
• Domain Specificity: Optimized for Hall Effect Thruster fluid dynamics, may not generalize well outside this domain.
• Computational Resources: Requires adequate computational power for optimal performance due to model size.

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Ethical Considerations

• Accuracy: Intended as a research and educational aid; not a substitute for expert judgment.

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Acknowledgements

• Mistral AI: For providing the Mistral-Large-Instruct-2411 foundation model.
• Dataset Contributors: A Taylor
• Open-Source Community: Gratitude for tools and libraries that supported the fine-tuning process.

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License

• Model License: Apache License 2.0
• Dataset License: Apache License 2.0

Future Work

• Next Version: May incorporate advanced magnetohydrodynamic modeling, improved handling of variable mass flow rates, and refined treatments of plasma-wall interactions.

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Contact Information

• Author: A Taylor @ hf.co/taylor658
• Email
• Repository:

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