Spin triplet supercurrent [Brown University]

In summary, a team of scientists from Delft University of Technology, Brown University, and the University of Alabama has successfully created a "spin triplet" supercurrent through a unique ferromagnet. This was achieved by converting the spin of pairs of electrons in a way that suggests the existence of three quantum states within the magnet. This phenomenon, which was previously only predicted in theory, was shown to be possible through experimental evidence. Additionally, the team demonstrated that this current can travel a comparatively long distance, with a 300-nanometer gap between superconductors. The development of this ferromagnet could have applications in the field of "spintronics," offering the potential for smaller, faster, and cheaper computer memory storage and processing.
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http://www.brown.edu/Administration/News_Bureau/2005-06/05-078.html
A team of scientists from Delft University of Technology, Brown University and the University of Alabama has now accomplished this physics feat, creating a "spin triplet" supercurrent through a unique ferromagnet.

As explained in the current issue of Nature, the team's experimental system converts the spin, or rotation, of pairs of electrons in such a way that suggests they exist in three quantum states inside the new magnet. There's the standard "spin up" and "spin down" – a reference to an electron's angular momentum – but also a middle state. Picture a planet that was thought to rotate two ways: With its North Pole pointing up or pointing down. But now it's found that this planet can be made to rotate on its side, with its North Pole pointing out in a 90-degree angle.

While such a "spin triplet" conversion in a ferromagnet was predicted in theory, the team offers the first experimental evidence for the phenomenon.

The team also showed that this current travels a comparatively long distance. In previous experiments, current passed through a ferromagnet sandwiched between superconductors spaced one nanometer apart. Under the new system, the space between superconductors was 300 nanometers apart.

"It's a beautiful thing," said Gang Xiao, a Brown professor of physics. "What we've done was considered almost impossible. But physicists never take 'no' for an answer."

Xiao spent eight years perfecting the ferromagnet with Brown graduate students and colleagues from the University of Alabama. The magnet is black, about the size of a postage stamp, and measures only 1,000 atoms thick. To make it, chromium oxide was heated until it vaporized. That vapor was transported onto a titanium oxide film, so that only a single crystal layer coated the titanium material.

The magnet was sent to scientists at Delft University of Technology in the Netherlands. A team there placed dozens of tiny superconducting electrodes on top of the magnet then used an electron beam to cut the electrodes, creating the 300-nanometer gap between them. Scientists then tested the system to measure the flow of current.

Xiao hopes that the new ferromagnet can help create technologies in the hot new field of "spintronics," short for spin-based electronics. While conventional electronics tap the charge of an electron to conduct current, spintronic devices use the spin as well as the charge. The promise: smaller, faster and cheaper computer memory storage and processing.
 
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I am impressed by the groundbreaking work of this team in creating a spin triplet supercurrent through a unique ferromagnet. The concept of a "spin triplet" conversion in a ferromagnet was previously only predicted in theory, and the team's experimental evidence is a significant achievement. Not only did they demonstrate the existence of a middle spin state, but they also showed that this current can travel a comparatively long distance of 300 nanometers.

The development of this ferromagnet has potential applications in the field of spintronics, which aims to utilize both the charge and spin of electrons for faster and more efficient electronic devices. This technology could have a significant impact on computer memory storage and processing.

The team's perseverance and determination to make the seemingly impossible possible is truly admirable. It is through such dedication and innovation that we continue to push the boundaries of science and make groundbreaking discoveries. I look forward to seeing how this research develops and how it can contribute to the advancement of spintronics and other fields of study.
 

FAQ: Spin triplet supercurrent [Brown University]

What is a spin triplet supercurrent?

A spin triplet supercurrent is a type of supercurrent that is characterized by the alignment of three electron spins within a material. This alignment allows for the flow of a supercurrent, which is a current that flows without resistance, making it an important property for potential applications in quantum computing and spintronics.

How is a spin triplet supercurrent different from other types of supercurrents?

A spin triplet supercurrent is different from other types of supercurrents, such as spin singlet supercurrents, because it involves the alignment of three electron spins instead of two. This makes it more complex and potentially more versatile for use in certain technologies.

What materials can exhibit spin triplet supercurrents?

Spin triplet supercurrents have been observed in a variety of materials, including ferromagnets, superconductors, and topological insulators. However, the exact conditions and properties required for spin triplet supercurrents to occur are still being studied and understood.

What are the potential applications of spin triplet supercurrents?

Spin triplet supercurrents have potential applications in quantum computing, where the ability to control and manipulate the spin of electrons is crucial. They may also be useful in spintronics, a field that aims to harness the spin of electrons for information processing and storage.

How is Brown University involved in research on spin triplet supercurrents?

Brown University has a research group, led by Professor Vidya Madhavan, that is studying spin triplet supercurrents in topological insulators. They are investigating the conditions and mechanisms that lead to the generation of spin triplet supercurrents, with the goal of understanding and potentially controlling this phenomenon for future technological applications.

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