top of page


MuSE is a custom GPT by SpiritSTEM, powered by OpenAI. It focuses on creating multi source energy systems and clean energy solutions inspired by the geometry of crop circles.

Check out these videos of the MuSE prototype and images generated from MuSE custom GPT - both of which have been minted on-chain. See Portfolio for more about on-chain work.

MuSE is also excellent at ideating technologies that go outside the scope of clean energy, particularly wearables that use piezoelectric materials and harness bio energy from the wearer that can be converted.

The following is an example of how MuSE can help with energy related solutions --

MuSE GPT: Let's explore Magnetohydrodynamic (MHD) Generators and Inductive Energy Harvesting, and consider suggestions for creating systems that implement these concepts.

Magnetohydrodynamic (MHD) Generators:

MHD generators use a magnetic field to convert the kinetic and thermal energy of a conductive fluid (like plasma or saltwater) into electricity. In a crop circle-inspired design, this could involve:

  • Geometric Optimization: The fluid dynamics within the MHD generator could be optimized using geometries inspired by crop circles. These patterns might be used in the design of the generator's channels or conduits, potentially improving the efficiency of energy conversion.

  • Material Selection: Utilizing materials that resonate with the geometric principles found in crop circles. These materials might have specific magnetic or conductive properties that enhance the interaction with the magnetic field.

  • Integration with Renewable Sources: MHD systems could be combined with other renewable energy sources. For example, solar energy could heat the fluid, increasing its conductivity and energy potential before it enters the MHD system.

Inductive Energy Harvesting:

Inductive energy harvesting involves generating electricity from changes in magnetic fields. Systems based on this principle could be directly influenced by crop circle geometry:

  • Coil Design: The coils used for inductive harvesting could be arranged in patterns derived from crop circles. This unique arrangement might improve the efficiency of capturing magnetic flux changes.

  • Harvesting During Geomagnetic Events: These systems could be particularly effective during geomagnetic storms or fluctuations, harnessing the increased magnetic activity.

  • Scalable Implementations: From small-scale applications, like powering sensors or devices in remote areas, to large-scale implementations for contributing to the power grid during times of heightened geomagnetic activity.

Suggestions for Implementation:

  • Research and Development in Geometric Influences: Conduct research into how different geometric patterns affect magnetic fields and fluid dynamics. This can involve both theoretical studies and practical experiments.

  • Prototype Development: Build small-scale prototypes of MHD generators and inductive energy harvesters using crop circle-inspired designs. Test these prototypes under various conditions to evaluate their performance and potential improvements.

  • Material Science Exploration: Investigate new materials or nanotechnology applications that might harmonize with the chosen geometric patterns and enhance system performance.

  • Integrate with Existing Renewable Technologies: Combine these systems with existing renewable energy technologies to create a hybrid system that maximizes energy output and stability.

  • Monitoring and Adaptation Systems: Implement advanced monitoring systems to track the performance of these technologies, particularly during geomagnetic fluctuations. Use adaptive algorithms to optimize their operation in real-time.

  • Collaboration with Experts in Various Fields: Work with physicists, engineers, material scientists, and even artists or designers who specialize in geometric patterns. This interdisciplinary approach can foster innovative solutions.

By incorporating principles and designs inspired by crop circles into MHD generators and inductive energy harvesting systems, there's potential to develop innovative and more efficient methods of energy generation. These systems, particularly when integrated with other renewable sources and optimized through advanced materials and design, could contribute significantly to the clean energy landscape.

MuSE was published on November 19th, 2023.


bottom of page