Which thing has more speed than light?

Faster Than a Speeding Photon (in Water): The Story of Cherenkov Radiation

The phrase “faster than light” evokes images of warp drives and science fiction fantasies. Einstein’s theory of special relativity tells us that nothing can exceed the speed of light in a vacuum. This speed, a constant denoted by ‘c’, is the ultimate speed limit in the universe. However, there’s a fascinating nuance to this rule, and it manifests as a beautiful, ethereal blue glow emanating from spent nuclear fuel submerged in water: Cherenkov radiation.

This captivating glow isn’t the result of some exotic nuclear reaction, but rather a consequence of charged particles exceeding the speed of light within the water. It’s crucial to understand this distinction. Light slows down when traveling through a medium like water or glass. Its speed in a vacuum is approximately 300,000 kilometers per second, but in water, it drops to around 225,000 kilometers per second.

Spent nuclear fuel emits high-energy charged particles, such as electrons. These particles, propelled by radioactive decay, can achieve velocities greater than light’s speed in water, although they remain slower than ‘c’. Imagine a supersonic jet breaking the sound barrier; it creates a sonic boom. Similarly, when these charged particles surpass the speed of light in water, they generate a visual equivalent: a shockwave of light known as Cherenkov radiation.

This “optical boom” appears as a continuous blue glow. The blue hue is a consequence of the specific frequency of light emitted during this process. Similar to how a sonic boom carries the sound of the supersonic jet, Cherenkov radiation carries the “light” of these speeding particles. The intensity of the glow is proportional to the particle’s velocity – the faster the particle, the brighter the glow.

Cherenkov radiation isn’t limited to nuclear reactors. It also occurs in other environments involving high-energy particles, like particle accelerators and even the Earth’s atmosphere when impacted by cosmic rays. Furthermore, it’s a valuable tool for scientists. By detecting and analyzing Cherenkov radiation, researchers can identify and study the properties of these high-energy particles, providing insights into fundamental physics and astrophysical phenomena.

So, while nothing can surpass the speed of light in a vacuum, the mesmerizing blue glow of Cherenkov radiation serves as a beautiful reminder that the interaction of light and matter can create some truly remarkable phenomena. It’s a testament to the complex and often counterintuitive nature of physics, where even the seemingly unbreakable rules can reveal surprising exceptions under specific circumstances.