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Anything-goes “anyons” may be at the root of surprising quantum experiments
Researchers establish new basis for quantum sensing and communication
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MIT News | Massachusetts Institute of Technology · MIT physics, Research Laboratory of Electronics, Senthil Todadri, electron fractions, fractional quantum anomalous Hall effect, anyons, bosons, Fermions, superconductivity, Magnetism, quantum computing, stable qubits
MIT News | Massachusetts Institute of Technology · Moe Win, MIT AeroAstro, MIT LIDS, MIT IDSS, Quantum neXus Laboratory, quantum sensing, photon-varied Gaussian states (PVGSs), quantum communications, quantum information, non-Gaussian quantum states
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'''Article preview.'''<br>
'''Article preview.'''<br>
MIT theoretical physicists may have an explanation for the surprising observation that<br>
Researchers have established a new basis for quantum sensing and communication. Their<br>
superconductivity and magnetism can co-exist in some materials. They propose that<br>
theoretical approach for generating quantum states could be crucial for many areas,<br>
under certain conditions, a magnetic material’s electrons could splinter into<br>
ranging from fingerprinting the magnetic field of the Earth to enhancing astrophysical<br>
quasiparticles known as “anyons,” some of which could flow together without friction —<br>
research.<br>
an entirely new form of superconductivity.<br>
The article is featured here because it connects current quantum research with a<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
technical discussion to the original source.<br>
Topic area: MIT physics, Research Laboratory of Electronics, Senthil Todadri, electron<br>
Topic area: Moe Win, MIT AeroAstro, MIT LIDS, MIT IDSS, Quantum neXus Laboratory,<br>
fractions, fractional quantum anomalous Hall effect, anyons, bosons, Fermions,<br>
quantum sensing, photon-varied Gaussian states (PVGSs), quantum communications,<br>
superconductivity, Magnetism, quantum computing, stable qubits.<br>
quantum information, non-Gaussian quantum states.<br>
The selected source is MIT News | Massachusetts Institute of Technology; the full<br>
The selected source is MIT News | Massachusetts Institute of Technology; the full<br>
article link appears below this preview.
article link appears below this preview.
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[https://news.mit.edu/2025/anything-goes-anyons-may-be-root-surprising-quantum-experiments-1222 Read the full article at MIT News | Massachusetts Institute of Technology ->]
[https://news.mit.edu/2025/researchers-establish-new-basis-quantum-sensing-communication-0313 Read the full article at MIT News | Massachusetts Institute of Technology ->]
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Revision as of 23:10, 20 May 2026

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Featured external quantum article

Researchers establish new basis for quantum sensing and communication

MIT News | Massachusetts Institute of Technology · Moe Win, MIT AeroAstro, MIT LIDS, MIT IDSS, Quantum neXus Laboratory, quantum sensing, photon-varied Gaussian states (PVGSs), quantum communications, quantum information, non-Gaussian quantum states

Article preview.
Researchers have established a new basis for quantum sensing and communication. Their
theoretical approach for generating quantum states could be crucial for many areas,
ranging from fingerprinting the magnetic field of the Earth to enhancing astrophysical
research.
The article is featured here because it connects current quantum research with a
broader scientific or technological problem.
The preview highlights the main idea while leaving the detailed evidence, figures and
technical discussion to the original source.
Topic area: Moe Win, MIT AeroAstro, MIT LIDS, MIT IDSS, Quantum neXus Laboratory,
quantum sensing, photon-varied Gaussian states (PVGSs), quantum communications,
quantum information, non-Gaussian quantum states.
The selected source is MIT News | Massachusetts Institute of Technology; the full
article link appears below this preview.

External source: MIT News | Massachusetts Institute of Technology. Selected external quantum article.

Credits: MIT News | Massachusetts Institute of Technology

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