We are independent & ad-supported. We may earn a commission for purchases made through our links.
Advertiser Disclosure
Our website is an independent, advertising-supported platform. We provide our content free of charge to our readers, and to keep it that way, we rely on revenue generated through advertisements and affiliate partnerships. This means that when you click on certain links on our site and make a purchase, we may earn a commission. Learn more.
How We Make Money
We sustain our operations through affiliate commissions and advertising. If you click on an affiliate link and make a purchase, we may receive a commission from the merchant at no additional cost to you. We also display advertisements on our website, which help generate revenue to support our work and keep our content free for readers. Our editorial team operates independently of our advertising and affiliate partnerships to ensure that our content remains unbiased and focused on providing you with the best information and recommendations based on thorough research and honest evaluations. To remain transparent, we’ve provided a list of our current affiliate partners here.
Physics

Our Promise to you

Founded in 2002, our company has been a trusted resource for readers seeking informative and engaging content. Our dedication to quality remains unwavering—and will never change. We follow a strict editorial policy, ensuring that our content is authored by highly qualified professionals and edited by subject matter experts. This guarantees that everything we publish is objective, accurate, and trustworthy.

Over the years, we've refined our approach to cover a wide range of topics, providing readers with reliable and practical advice to enhance their knowledge and skills. That's why millions of readers turn to us each year. Join us in celebrating the joy of learning, guided by standards you can trust.

What is the Casimir Effect?

Michael Anissimov
By
Updated: May 21, 2024
Views: 9,607
Share

The Casimir effect refers to the tiny attractive force that appears between two uncharged plates in a vacuum. This Casimir force is only measurable when the plates are extremely close together (several atomic diameters). This force was predicted in 1948 by Hendrik Casimir, a Dutch theoretical physicist. It was experimentally verified in 1958 by Marcus Spaarnay, again at Philips in Eindhoven while he was studying the properties of colloidal solutions. The recognized cause of the Casimir effect is the quantum vacuum fluctuations (zero-point fluctuations) of the electromagnetic field between the plates.

The attractive force occurs because, as quantum theory indicates, even a so-called vacuum contains a multitude of virtual electromagnetic particles and anti-particles in a continuous state of fluctuation. This is known as the vacuum energy. Because the gap between the plates constrains the possible wavelengths of the virtual particle pairs, there are fewer virtual particles within the space between the plates relative to the space outside them. This means the energy density between the plates is less than that of the energy density of the surrounding space, creating a negative pressure which pulls the plates together ever so slightly.

The closer the plates become, the smaller the vacuum energy density. It was not until 1997 that the precise magnitude of the Casimir force was measured by Steve K. Lamoreaux of the Los Alamos National Laboratory along with Umar Mohideen and Anushree Roy from UC Riverside. Because using two parallel plates would require impractically high standards for precise alignment, a plate and a nearly perfect sphere were used. Within a margin of error of 5%, the intensity was found to be just that predicted by quantum theory; defined as the zero-point energy of the Fourier modes of the electromagnetic field between the plates.

With certain materials and in certain configurations, it has been shown that the Casimir effect can be repulsive as well as attractive. It seems that the Casimir force is too small to be applied usefully to any of our present-day technology, though knowledge of its existence may be essential for those designing micromechanical or nanomechanical robotic devices in the present and in the decades to come. One day it may be possible to exploit the Casimir effect for the generation of energy, though this day is very far off and it is likely that more efficient energy sources will be discovered before this even becomes possible.

Share
All The Science is dedicated to providing accurate and trustworthy information. We carefully select reputable sources and employ a rigorous fact-checking process to maintain the highest standards. To learn more about our commitment to accuracy, read our editorial process.
Michael Anissimov
By Michael Anissimov
Michael Anissimov is a dedicated All The Science contributor and brings his expertise in paleontology, physics, biology, astronomy, chemistry, and futurism to his articles. An avid blogger, Michael is deeply passionate about stem cell research, regenerative medicine, and life extension therapies. His professional experience includes work with the Methuselah Foundation, Singularity Institute for Artificial Intelligence, and Lifeboat Foundation, further showcasing his commitment to scientific advancement.
Discussion Comments
Michael Anissimov
Michael Anissimov
Michael Anissimov is a dedicated All The Science contributor and brings his expertise in paleontology, physics, biology...
Learn more
Share
https://www.allthescience.org/what-is-the-casmir-effect.htm
Copy this link
All The Science, in your inbox

Our latest articles, guides, and more, delivered daily.

All The Science, in your inbox

Our latest articles, guides, and more, delivered daily.