General Fusion Exceeds Core Technology Performance Targets with Plasma and Compression Prototypes

Date
12/12/2022

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The company achieves performance milestones that demonstrate it is on track to meet its Fusion Demonstration Program goals at power plant relevant scale

General Fusion’s plasma injector exceeds requirements with 10-millisecond self-sustaining energy confinement time without requiring active magnetic stabilization, auxiliary heating, or a conventional divertor.

­General Fusion has demonstrated plasma energy confinement times, plasma temperatures, and compression system performance that support meeting its goal of 10 keV (100 million degrees Celsius) in the company’s integrated Magnetized Target Fusion (MTF) demonstration, being built to 70 percent scale of a commercial machine at the UK Atomic Energy Authority’s Culham Campus.

The results come as the company celebrates its 20th anniversary. In that time, it has completed over 200,000 plasma shots, achieved 150 patents and patents pending, and grown to a team of more than 200 employees. Using large-scale prototypes, General Fusion has proven its core technology approach. Today, it announces additional advancements in its plasma and compression technologies.

“In 2002, I founded General Fusion with the vision of creating a technology that would combat climate change and end the world’s reliance on fossil fuels for power. To be successful, I knew I needed a practical method that overcame longstanding barriers to commercializing fusion. That’s why I chose Magnetized Target Fusion,” said Dr. Michel Laberge, Founder and Chief Science Officer, General Fusion. “After 20 years – to see our core technologies proven out and ready to be put together in the fusion demonstration – it’s an incredible feeling.”

Creating fusion energy with MTF starts with a hydrogen plasma injected into a vessel lined with liquid metal. Next, high-powered pistons compress the liquid metal around the plasma, squeezing and building pressure until the plasma reaches more than 100 million degrees Celsius – and fusion occurs. The technology depends on three core factors to be successful: hot plasmas that hold their energy long enough to be compressed, a synched compression system, and a stable fusion process that will increase neutron yields and temperatures when plasmas are compressed.

Plasma injector exceeds requirements with 10-millisecond self-sustaining energy confinement time: 

General Fusion’s plasma injector PI3 is the world's largest and most powerful of its kind. It generates plasma targets with confinement times exceeding predictions from accepted scaling laws and consistently achieves the conditions required for the company’s fusion demonstration. Today, General Fusion is creating the plasmas it needs, achieving 10 millisecond energy confinement time without requiring active magnetic stabilization, auxiliary heating, or a conventional divertor. The plasmas reach a temperature of 250 eV, almost 3 million degrees Celsius, the starting plasma temperature required for the company to compress the plasma to fusion conditions. Combined with known scaling laws, these results and modelling provide confidence that the company’s fusion demonstration is on track to meet its target temperature of 10 keV. 

Compression system prototype validates five millisecond compression time for fusion demonstration:

General Fusion takes a pulsed approach to create fusion energy. This means, unlike a tokamak, its plasmas do not need to be sustained for long periods. Instead, the company uses mechanical compression to achieve fusion conditions. This is done with high-speed drivers that are timed to rapidly create a precisely shaped, symmetrical collapse of a liquid metal cavity, which envelopes the plasma. General Fusion’s primary compression prototype has completed over 1,000 shots, consistently achieving its compression performance targets. In addition, researchers and engineers have used test results across a range of compression parameters to validate and refine their fluid dynamic models to a high degree of fidelity. These models show that the fusion demonstration can achieve a shaped collapse in a liquid metal cavity within approximately five milliseconds. This is sufficient for the thermal confinement times already achieved within General Fusion’s existing plasma prototypes. 

These two recent milestone announcements build on the significant technological advances previously achieved by General Fusion’s team since the founding of the company in 2002.

  • 2005: Fusion reaction in the company’s first MTF prototype
  • 2010: First at-scale plasma injector with magnetically confined plasma
  • 2011: First demonstration of compressive heating of magnetized plasma
  • 2012: Liquid metal compression tests validate engineering of liquid metal approach and synchronization of at-scale pistons
  • 2013: Plasma achieves performance to enable compression heating
  • 2017: Stable compression of plasma
  • 2018: Heating and increased neutron yield during plasma compression
  • 2019: Plasma lifetime maintained within a liquid metal cavity
  • 2019-2021: Plasma performance sufficient to achieve fusion conditions at scale
  • 2021: Compressed liquid cavity into a controlled, symmetrical shape sufficient to achieve fusion conditions when scaled in the company’s fusion demonstration
  • 2022: Plasma energy confinement time of 10 milliseconds and validated compression time of 5 milliseconds support achieving 10 keV at power plant scale

“Commercializing fusion energy is within reach, and General Fusion is ready to deliver it to the grid by the 2030s,” said Greg Twinney, CEO, General Fusion. “We have the right team, the right technology, and the right strategy to get us there.”

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