Stanford researchers are developing a tiny electron accelerator that could have applications in physics, medicine, and industry. The accelerator is based on “accelerator-on-a-chip” technology. 

The accelerator is shoebox-sized and uses a microchip that contains a vacuum tube made up of thousands of pillars. Miniature laser beams are directed at the pillars to accelerate electrons. This is different from traditional particle accelerator technology. 

The accelerator can steer electrons and increase their energy at rates similar to larger accelerators. This could lead to particle accelerators becoming more widely available in science, medicine, and industry

Stanford researchers are getting closer to building a tiny electron accelerator based on “accelerator-on-a-chip” technology with broad potential applications in studying physics as well as medical and industrial uses

The Nanophotonic Electron Accelerator (NEA) is a particle accelerator that’s about the size of a coin. It’s made up of a microchip that contains a vacuum tube with thousands of pillars. Researchers use miniature laser beams to accelerate electrons by firing them at the pillars

The NEA accelerates charged particles, like protons and electrons, to high energies and speeds. The accelerated particles can be used for a variety of purposes, including: 

• Fundamental research in particle physics 
• Medical treatments 
• Industrial applications Electron accelerators are often used in X-ray cancer therapy. When an electron beam collides with a metal material and loses kinetic energy rapidly, an X-ray is generated

Stanford researchers are developing a tiny electron accelerator that could have applications in physics, medicine, and industry. The accelerator is based on “accelerator-on-a-chip” technology

The Stanford team, led by Payton Broaddus, aims to develop a tiny linear accelerator that could rival the capabilities of larger machines at a fraction of the cost. This miniaturized accelerator could have revolutionary applications in medicine, enabling precise electron beam targeting for tumor treatment. 

Other potential applications for the accelerator include:

• Quantum computing Using the devices to create special states of light that could be useful for quantum computing. 
• Materials research For example, for making images of thin materials with ultrahigh time resolution. 

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