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                    <title>Phys.org - latest science and technology news stories</title>
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            <description>Phys.org internet news portal provides the latest news on science including: Physics, Nanotechnology, Life Sciences, Space Science, Earth Science, Environment, Health and Medicine.</description>

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                    <title>&#039;Solar-blind&#039; 2D heterostructure delivers 422-fold responsivity gain for UV sensing</title>
                    <description>Photodetectors remain a critical component in the development of advanced electronics and photonics, particularly in the role of signal readout through the conversion of photons into electrons. These digital imaging components are ubiquitous in sensors, cameras, adaptive displays, telecommunications, LiDAR systems, health monitoring wearables, and oximeters.</description>
                    <link>https://phys.org/news/2026-05-solar-2d-heterostructure-responsivity-gain.html</link>
                    <category>Nanophysics</category>                    <pubDate>Tue, 05 May 2026 16:40:05 EDT</pubDate>
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                    <title>Silicon nanospheres boost WS₂ second-harmonic generation 40-fold while preserving polarization</title>
                    <description>A research team has demonstrated that silicon nanospheres can strongly enhance second-harmonic generation (SHG) from an atomically thin semiconductor while preserving the circular polarization information tied to its valley degree of freedom. The study, published in Nano Letters, provides design guidelines for efficient, polarization-preserving nonlinear light sources at the nanoscale.</description>
                    <link>https://phys.org/news/2026-03-silicon-nanospheres-boost-ws-harmonic.html</link>
                    <category>Nanophysics</category>                    <pubDate>Wed, 25 Mar 2026 19:40:04 EDT</pubDate>
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                    <title>Catching light in air: Programmable Mie voids boost light matter interaction</title>
                    <description>Atomically thin semiconductors such as tungsten disulfide (WS2) are promising materials for future photonic technologies. Despite being only a single layer of atoms thick, they host tightly bound excitons—pairs of electrons and holes that interact strongly with light—and can efficiently generate new colors of light through nonlinear optical processes such as second-harmonic generation.</description>
                    <link>https://phys.org/news/2026-03-air-programmable-mie-voids-boost.html</link>
                    <category>Nanophysics</category>                    <pubDate>Mon, 02 Mar 2026 16:30:01 EST</pubDate>
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                    <title>Ultrafast light switches use atomically thin semiconductors for rapid optical control</title>
                    <description>A nanostructure made of silver and an atomically thin semiconductor layer can be turned into an ultrafast switching mirror device that may function as an optical transistor—with a switching speed around 10,000 times faster than an electronic transistor.</description>
                    <link>https://phys.org/news/2026-01-ultrafast-atomically-thin-semiconductors-rapid.html</link>
                    <category>Nanophysics</category>                    <pubDate>Wed, 21 Jan 2026 14:35:57 EST</pubDate>
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                    <title>Molecule deposition on 2D materials promotes defect healing and quality restoration</title>
                    <description>Researchers from the Institute of Physics in Zagreb have shown that depositing a thin layer of organic molecules on two-dimensional (2D) semiconductors can improve their optical properties and even repair defects. Their work, published in Surfaces and Interfaces, could help improve the performance of 2D materials in (opto)electronics and photonics.</description>
                    <link>https://phys.org/news/2026-01-molecule-deposition-2d-materials-defect.html</link>
                    <category>Nanomaterials</category>                    <pubDate>Sat, 17 Jan 2026 07:20:01 EST</pubDate>
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                    <title>Quantum phenomenon enables a nanoscale mirror that can be switched on and off</title>
                    <description>Controlling light is an important technological challenge—not just at the large scale of optics in microscopes and telescopes, but also at the nanometer scale. Recently, physicists at the University of Amsterdam published a clever quantum trick that allows them to make a nanoscale mirror that can be turned on and off at will.</description>
                    <link>https://phys.org/news/2026-01-quantum-phenomenon-enables-nanoscale-mirror.html</link>
                    <category>Optics &amp; Photonics</category>                    <pubDate>Thu, 08 Jan 2026 14:42:38 EST</pubDate>
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                    <title>Controlling exciton flow in moiré superlattices: New method leverages correlated electrons</title>
                    <description>Excitons are pairs of bound negatively charged electrons and positively charged holes that form in semiconductors, enabling the transport of energy in electronic devices. These pairs of charge carriers also emerge in transition metal dichalcogenides, thin semiconducting materials comprised of a transition metal and two chalcogen atoms.</description>
                    <link>https://phys.org/news/2025-12-exciton-moir-superlattices-method-leverages.html</link>
                    <category>Condensed Matter</category>                    <pubDate>Sun, 21 Dec 2025 14:10:02 EST</pubDate>
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                    <title>Expanding the search for quantum-ready 2D materials</title>
                    <description>Quantum technologies from ultrasensitive sensors to next-generation information processors depend on the ability of quantum bits, or qubits, to maintain their delicate quantum states for a sufficiently long time to be useful.</description>
                    <link>https://phys.org/news/2025-12-quantum-ready-2d-materials.html</link>
                    <category>Condensed Matter</category>                    <pubDate>Mon, 08 Dec 2025 17:12:21 EST</pubDate>
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                    <title>Shining a light on dark valleytronics: First direct observation of dark excitons in atomically thin materials</title>
                    <description>In a world-first, researchers from the Femtosecond Spectroscopy Unit at the Okinawa Institute of Science and Technology (OIST) have directly observed the evolution of the elusive dark excitons in atomically thin materials, laying the foundation for new breakthroughs in both classical and quantum information technologies.</description>
                    <link>https://phys.org/news/2025-09-dark-valleytronics-excitons-atomically-thin.html</link>
                    <category>Condensed Matter</category>                    <pubDate>Thu, 25 Sep 2025 09:21:31 EDT</pubDate>
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                    <title>Two-step method enables controllable WS&amp;#8322; epitaxy growth</title>
                    <description>In a study published in Journal of the American Chemical Society, a team led by Prof. Song Li from the University of Science and Technology of China (USTC) of the Chinese Academy of Sciences synthesized monolayer WS2 lateral homojunctions via in situ domain engineering, and enabled controllable direct chemical vapor deposition (CVD) growth of these structures.</description>
                    <link>https://phys.org/news/2025-09-method-enables-ws8322-epitaxy-growth.html</link>
                    <category>Nanomaterials</category>                    <pubDate>Tue, 23 Sep 2025 14:44:02 EDT</pubDate>
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                    <title>Trilayer moiré superlattices unlock tunable control of exciton configurations</title>
                    <description>Moiré superlattices are periodic patterns formed when two or more thin semiconducting layers are stacked with a small twist angle or lattice mismatch. When 2D materials form these patterns, their electronic, mechanical, and optical properties can change significantly.</description>
                    <link>https://phys.org/news/2025-09-trilayer-moir-superlattices-tunable-exciton.html</link>
                    <category>Condensed Matter</category>                    <pubDate>Fri, 12 Sep 2025 07:20:02 EDT</pubDate>
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                    <title>Ultrathin resonators set new standard for efficient light manipulation</title>
                    <description>In the nanometer range (billionth of a meter), interactions occur between light and matter that do not happen on larger scales. As such, so-called nanophotonic materials have unique optical properties that open up a whole range of technical possibilities.</description>
                    <link>https://phys.org/news/2025-05-ultrathin-resonators-standard-efficient.html</link>
                    <category>Nanophysics</category>                    <pubDate>Thu, 29 May 2025 12:09:11 EDT</pubDate>
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                    <title>Moiré than meets the eye: Phasons enable interlayer excitons to move at low temperatures for quantum stability</title>
                    <description>A moiré pattern appears when you stack and rotate two copies of an image with regularly repeating shapes, turning simple patterns of squares or triangles into a groovy wave pattern that moves across the combined image in an optical delight.</description>
                    <link>https://phys.org/news/2025-03-moir-eye-phasons-enable-interlayer.html</link>
                    <category>Nanophysics</category>                    <pubDate>Mon, 24 Mar 2025 13:03:04 EDT</pubDate>
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                    <title>The first observation of amplified spontaneous emission from electron-hole plasma in 2D semiconductors</title>
                    <description>Amplified spontaneous emission is a physical phenomenon that entails the amplification of the light spontaneously emitted by excited particles, due to photons of the same frequency triggering further emissions. This phenomenon is central to the functioning of various optoelectronic technologies, including lasers and optical amplifiers (i.e., devices designed to boost the intensity of light).</description>
                    <link>https://phys.org/news/2025-03-amplified-spontaneous-emission-electron-hole.html</link>
                    <category>Condensed Matter</category>                    <pubDate>Mon, 17 Mar 2025 09:00:02 EDT</pubDate>
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                    <title>Researchers achieve near-unity quantum efficiency in 2D photon emitters</title>
                    <description>Leveraging the principles of quantum mechanics, quantum computers can perform calculations at lightning-fast speeds, enabling them to solve complex problems faster than conventional computers. In quantum technology applications such as quantum computing, light plays a central role in encoding and transmitting information.</description>
                    <link>https://phys.org/news/2024-12-unity-quantum-efficiency-2d-photon.html</link>
                    <category>Optics &amp; Photonics</category>                    <pubDate>Tue, 17 Dec 2024 16:05:05 EST</pubDate>
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                    <title>Scientists capture images of a new quantum phase in electron molecular crystals</title>
                    <description>Electrons typically travel at high speeds, zipping through matter unbound. In the 1930s, physicist Eugene Wigner predicted that electrons could be coaxed into stillness at low densities and cold temperatures, forming an electron ice that would later be called the Wigner crystal.</description>
                    <link>https://phys.org/news/2024-11-scientists-capture-images-quantum-phase.html</link>
                    <category>Condensed Matter</category>                    <pubDate>Thu, 07 Nov 2024 12:05:03 EST</pubDate>
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                    <title>A new paradigm for control of quantum emitters—modulating and encoding quantum photonic info on a single light stream</title>
                    <description>A U.S. Naval Research Laboratory (NRL) multi-disciplinary team developed a new paradigm for the control of quantum emitters, providing a new method for modulating and encoding quantum photonic information on a single photon light stream.</description>
                    <link>https://phys.org/news/2024-10-paradigm-quantum-emitters-modulating-encoding.html</link>
                    <category>Optics &amp; Photonics</category>                    <pubDate>Thu, 31 Oct 2024 14:15:38 EDT</pubDate>
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                    <title>Theoretical physicist uncovers how twisting layers of a material can generate mysterious electron-path-deflecting effect</title>
                    <description>In 2018, a discovery in materials science sent shock waves throughout the community. A team showed that stacking two layers of graphene—a honeycomb-like layer of carbon extracted from graphite—at a precise &quot;magic angle&quot; turned it into a superconductor, says Ritesh Agarwal of the University of Pennsylvania.</description>
                    <link>https://phys.org/news/2024-10-theoretical-physicist-uncovers-layers-material.html</link>
                    <category>Nanophysics</category>                    <pubDate>Fri, 04 Oct 2024 09:10:18 EDT</pubDate>
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                    <title>Low-energy ion implantation enables 2D lateral p-n junction construction</title>
                    <description>The feature size of silicon-based transistors is approaching the theoretical limit, which puts forward higher requirements for the atomic level manufacturing of semiconductors. The basic idea of atomic level manufacturing is to process and manipulate matters with atomic level precision, which will greatly reduce the power consumption of the chip and achieve a huge increase in the chip&#039;s arithmetic power.</description>
                    <link>https://phys.org/news/2024-09-energy-ion-implantation-enables-2d.html</link>
                    <category>Nanophysics</category>                    <pubDate>Mon, 02 Sep 2024 13:33:04 EDT</pubDate>
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                    <title>Scientists create ultracompact polarization-entangled photon sources for miniaturized quantum devices</title>
                    <description>Scientists have created an ultra-thin light source that emits pairs of polarization-entangled photons. These specially correlated photons hold promise for future quantum technologies, including ultra-secure communication, powerful computation, and high-precision measurements. This light source is particularly small, pure, efficient, and versatile.</description>
                    <link>https://phys.org/news/2024-08-scientists-ultracompact-polarization-entangled-photon.html</link>
                    <category>Optics &amp; Photonics</category>                    <pubDate>Tue, 27 Aug 2024 13:36:03 EDT</pubDate>
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                    <title>A new approach to accelerate the discovery of quantum materials</title>
                    <description>Researchers at the Department of Energy&#039;s Lawrence Berkeley National Laboratory (Berkeley Lab) and several collaborating institutions have successfully demonstrated an innovative approach to find breakthrough materials for quantum applications. The study is published in the journal Nature Communications.</description>
                    <link>https://phys.org/news/2024-07-approach-discovery-quantum-materials.html</link>
                    <category>Condensed Matter</category>                    <pubDate>Wed, 17 Jul 2024 12:09:05 EDT</pubDate>
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                    <title>New synthesis method enhances MoS₂ optoelectronic performance</title>
                    <description>An international research team led by Professor My Ali El Khakani of the Institut national de la recherche scientifique (INRS) has made a surprising discovery about the properties of molybdenum disulfide, also known as MoS2. The material is highly sought after in optoelectronics.</description>
                    <link>https://phys.org/news/2024-07-synthesis-method-mos-optoelectronic.html</link>
                    <category>Nanophysics</category>                    <pubDate>Thu, 11 Jul 2024 12:36:24 EDT</pubDate>
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                    <title>Super-resolution machining of single crystalline sapphire by femtosecond laser-induced, plasma-assisted ablation</title>
                    <description>A new study in Opto-Electronic Advances discusses super-resolution machining of single crystalline sapphire by GHz burst mode femtosecond laser-induced plasma assisted ablation.</description>
                    <link>https://phys.org/news/2024-07-super-resolution-machining-crystalline-sapphire.html</link>
                    <category>Optics &amp; Photonics</category>                    <pubDate>Mon, 08 Jul 2024 17:27:03 EDT</pubDate>
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                    <title>Boosting UV light absorption in 2D semiconductor with quantum dot hybrids for enhanced light emission</title>
                    <description>A new publication in Opto-Electronic Science discusses boosting UV light absorption in a 2D semiconductor with quantum dot hybrids for enhanced light emission.</description>
                    <link>https://phys.org/news/2024-07-boosting-uv-absorption-2d-semiconductor.html</link>
                    <category>Optics &amp; Photonics</category>                    <pubDate>Mon, 08 Jul 2024 15:55:02 EDT</pubDate>
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                    <title>Strong coupling and catenary field enhancement in the hybrid plasmonic metamaterial cavity and TMDC monolayers</title>
                    <description>Researchers in the field of nanophotonics have spent significant time in recent years investigating fascinating concepts known as polaritons and/or plexcitons. These ideas revolve around the strong coupling of light photons and/or plasmons to excitons in semiconductor materials.</description>
                    <link>https://phys.org/news/2024-06-strong-coupling-catenary-field-hybrid.html</link>
                    <category>Nanophysics</category>                    <pubDate>Fri, 14 Jun 2024 12:48:21 EDT</pubDate>
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                    <title>Scientists create the thinnest lens on Earth, enabled by excitons</title>
                    <description>Lenses are used to bend and focus light. Normal lenses rely on their curved shape to achieve this effect, but physicists from the University of Amsterdam and Stanford University have made a flat lens of only three atoms thick that relies on quantum effects. This type of lens could be used in future augmented reality glasses.</description>
                    <link>https://phys.org/news/2024-05-scientists-thinnest-lens-earth-enabled.html</link>
                    <category>Nanophysics</category>                    <pubDate>Thu, 30 May 2024 11:06:03 EDT</pubDate>
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                    <title>Twist-angle in moiré lattice controls valley polarization switching in heterostructures</title>
                    <description>In a study published in Science Advances, Prof. Wang Can from the Institute of Physics of the Chinese Academy of Sciences and Prof. Xu Xiulai of Peking University have demonstrated for the first time the dependence of valley polarization switching and polarization degree on the moiré period by twist engineering in electrically controlled transition metal dichalcogenide heterobilayers (hBLs).</description>
                    <link>https://phys.org/news/2024-05-angle-moir-lattice-valley-polarization.html</link>
                    <category>Condensed Matter</category>                    <pubDate>Wed, 22 May 2024 09:48:03 EDT</pubDate>
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                    <title>Advancing transistor technology with triply-degenerate semimetal PtBi₂</title>
                    <description>Despite its promising characteristics in condensed matter physics, the triply-degenerate semimetal PtBi2 has been largely unexplored in practical applications, particularly in semiconductor technology. The main difficulties include a lack of empirical data on the integration of PtBi2 with existing semiconductor components and the need for innovative approaches to leverage its unique properties, such as high stability and mobility, within the constraints of current electronic manufacturing processes.</description>
                    <link>https://phys.org/news/2024-05-advancing-transistor-technology-triply-degenerate.html</link>
                    <category>Condensed Matter</category>                    <pubDate>Tue, 14 May 2024 15:52:40 EDT</pubDate>
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                    <title>Physicists create five-lane superhighway for electrons</title>
                    <description>MIT physicists and colleagues have created a five-lane superhighway for electrons that could allow ultra-efficient electronics and more. The work, reported in the May 9 issue of Science, is one of several important discoveries by the same team over the last year involving a material that is essentially a unique form of pencil lead.</description>
                    <link>https://phys.org/news/2024-05-physicists-lane-superhighway-electrons.html</link>
                    <category>Condensed Matter</category>                    <pubDate>Mon, 13 May 2024 16:46:28 EDT</pubDate>
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                    <title>Defect removal of 2D semiconductor crystals: Trapping oxygen molecules offers greater control</title>
                    <description> A study of oxygen molecules interacting with atomically thin layers of materials being developed as new generations of semiconductors could significantly improve control over the fabrication and applications of these two-dimensional (2D) materials.</description>
                    <link>https://phys.org/news/2024-04-defect-2d-semiconductor-crystals-oxygen.html</link>
                    <category>Nanomaterials</category>                    <pubDate>Thu, 11 Apr 2024 13:21:54 EDT</pubDate>
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