<?xml version="1.0" encoding="utf-8"?>
<rss version="2.0" xmlns:media="http://search.yahoo.com/mrss/">
    <channel>
                    <title>Phys.org - latest science and technology news stories</title>
            <link>https://phys.org/</link>
            <language>en-us</language>
            <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>

                            <item>
                    <title>Abundant catalyst converts methane into valuable liquid chemicals</title>
                    <description>Scientists at the U.S. Department of Energy&#039;s (DOE) Brookhaven National Laboratory and their collaborators have demonstrated a promising new approach for converting methane—the primary component of natural gas—into liquid chemicals that are precursors for many industrial chemicals and fuels. The research, described in a paper just published in Advanced Functional Materials, shows how molybdenum disulfide (MoS2), an earth-abundant industrial catalyst, can be used with minimal tweaking to selectively convert methane into methyl peroxide and other liquid oxygenate compounds at temperatures below 100°C (212°F). Methyl peroxide is a precursor for making methanol, an energy-dense liquid fuel that can be transported easily.</description>
                    <link>https://phys.org/news/2026-06-abundant-catalyst-methane-valuable-liquid.html</link>
                    <category>Analytical Chemistry</category>                    <pubDate>Tue, 30 Jun 2026 19:20:03 EDT</pubDate>
                    <guid isPermaLink="false">news702043741</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2026/abundant-catalyst-conv-1.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Reversible chirality switching in MoS₂ generates spin currents without magnets</title>
                    <description>A newly developed method allows researchers to dynamically switch chirality—a particular lack of mirror symmetry—to generate spin currents in semiconductors, researchers from Science Tokyo report. Their approach relies on the reversible insertion and removal of small chiral molecules from the interlayer gaps of a layered, nonchiral semiconductor material using electrochemistry.</description>
                    <link>https://phys.org/news/2026-06-reversible-chirality-mos-generates-currents.html</link>
                    <category>Condensed Matter</category>                    <pubDate>Wed, 17 Jun 2026 12:40:05 EDT</pubDate>
                    <guid isPermaLink="false">news700909861</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2026/reversible-switching-o.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Atomic-level simulations predict transistor scaling limits</title>
                    <description>As the global semiconductor industry enters the so-called 2-nanometer process era, the actual size of transistors—the core components of semiconductor chips—still remains above 10 nm. How much smaller, then, can transistors get? KAIST researchers have developed a technology to predict that limit through quantum mechanical, atom-level calculations.</description>
                    <link>https://phys.org/news/2026-06-atomic-simulations-transistor-scaling-limits.html</link>
                    <category>Nanophysics</category>                    <pubDate>Mon, 15 Jun 2026 10:00:05 EDT</pubDate>
                    <guid isPermaLink="false">news700734001</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2026/how-much-smaller-can-t.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Van der Waals forces can play unexpected role in thin film properties</title>
                    <description>Researchers have demonstrated the ability to use van der Waals forces to tune the physical and electronic properties of ferroelectric thin films. The work opens the door to new techniques for engineering materials for use in smaller, more energy efficient electronic devices.</description>
                    <link>https://phys.org/news/2026-06-van-der-waals-play-unexpected.html</link>
                    <category>Nanophysics</category>                    <pubDate>Mon, 08 Jun 2026 15:20:04 EDT</pubDate>
                    <guid isPermaLink="false">news700148551</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2026/van-der-waals-forces-c.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Ultrathin nanotubes reach 1 nanometer, opening path to smaller electronics</title>
                    <description>Researchers in Japan have created some of the world&#039;s smallest semiconducting nanotubes, structures 100,000 times thinner than a human hair. By growing molybdenum disulfide inside protective tubes of boron nitride, the researchers, including those from the University of Tokyo, produced highly uniform tubes just 1 nanometer wide, a scale at which it&#039;s difficult to make stable nanotube structures. The work confirms decades-old theoretical predictions about how these ultrafine materials behave and could also provide a new route toward miniaturized electronic devices.</description>
                    <link>https://phys.org/news/2026-06-ultrathin-nanotubes-nanometer-path-smaller.html</link>
                    <category>Nanomaterials</category>                    <pubDate>Thu, 04 Jun 2026 14:00:12 EDT</pubDate>
                    <guid isPermaLink="false">news699784622</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2026/nanometer-nanotubes-fo-2.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Mechanical method unlocks sunlight-driven wastewater cleanup</title>
                    <description>University of Birmingham researchers have demonstrated a new method to break down toxic pollutants in wastewater, using sunlight and molecular-thin catalysts created using an innovative &quot;mechanical&quot; approach. Non-degradable dyes originating from industries such as textiles, cosmetics, food, pharmaceuticals, and printing, are among the most prominent sources of industrial pollution. Left untreated, they disperse in both land and water, leading to contamination that poses serious risks to human health and the environment.</description>
                    <link>https://phys.org/news/2026-05-mechanical-method-sunlight-driven-wastewater.html</link>
                    <category>Analytical Chemistry</category>                    <pubDate>Thu, 07 May 2026 18:30:02 EDT</pubDate>
                    <guid isPermaLink="false">news697392421</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2026/researchers-show-a-new.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Designing better 2D electronics: Addressing anisotropic conductivity to cut contact resistance</title>
                    <description>The high-performance semiconductor devices powering smartphone displays, AI computing, EV batteries and more are increasingly incorporating 2D materials to overcome silicon&#039;s scaling limits. To optimize these technologies, a University of Michigan Engineering team developed a precise mathematical framework that accounts for anisotropic—or unevenly spreading—conductivity and device geometry.</description>
                    <link>https://phys.org/news/2026-03-2d-electronics-anisotropic-contact-resistance.html</link>
                    <category>Nanophysics</category>                    <pubDate>Fri, 20 Mar 2026 18:40:01 EDT</pubDate>
                    <guid isPermaLink="false">news693233901</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2026/model-incorporates-ani.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Reusable MoS₂ RF biosensor enables cost-effective liquid biopsies for early cancer detection</title>
                    <description>A research team affiliated with UNIST has unveiled an innovative, cost-effective biosensor capable of being washed and reused, paving the way for more accessible liquid biopsy diagnostics. This new platform aims to reduce the high costs and complexity associated with traditional cancer detection methods. The study was published in Sensors and Actuators B: Chemical.</description>
                    <link>https://phys.org/news/2026-02-reusable-mos-rf-biosensor-enables.html</link>
                    <category>Bio &amp; Medicine</category>                    <pubDate>Thu, 26 Feb 2026 11:50:01 EST</pubDate>
                    <guid isPermaLink="false">news691327561</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2026/revolutionary-reusable.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Capped VLS growth yields vanadium-doped MoS₂ films with superior CO₂-to-CO conversion</title>
                    <description>CO2 reduction to storable fuels or valuable chemical products provides a carbon-neutral cycle that can mitigate the rapid consumption of fossil fuels and increasing CO2 emissions. Although solar-driven CO2 reduction holds great promise for sustainable energy, the role and control of atomic-level active sites in governing intermediate formation and conversion pathways remains poorly understood.</description>
                    <link>https://phys.org/news/2026-01-capped-vls-growth-yields-vanadium.html</link>
                    <category>Nanomaterials</category>                    <pubDate>Tue, 20 Jan 2026 12:43:26 EST</pubDate>
                    <guid isPermaLink="false">news688135381</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2026/capped-vaporliquidsoli.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <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>
                    <guid isPermaLink="false">news687715883</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2026/molecule-deposition-on.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Atom-thin, content-addressable memory enables edge AI applications</title>
                    <description>Recent advances in the field of artificial intelligence (AI) have opened new exciting possibilities for the rapid analysis of data, the sourcing of information and the generation of use-specific content. To run AI models, current hardware needs to continuously move data from internal memory components to processors, which is energy-intensive and can increase the time required to tackle specific tasks.</description>
                    <link>https://phys.org/news/2026-01-atom-thin-content-memory-enables.html</link>
                    <category>Nanophysics</category>                    <pubDate>Mon, 12 Jan 2026 09:50:01 EST</pubDate>
                    <guid isPermaLink="false">news687433062</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2026/an-atom-thin-memory-fo.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Modifying chirality with electricity: Voltage-driven method enables reversible, tunable states</title>
                    <description>A way to electrically modify the chirality of organic–inorganic hybrid materials, in which chiral molecules adsorb onto inorganic surfaces, has been demonstrated by researchers at Science Tokyo. By using an electric double-layer transistor with a chiral electrolyte, specific chirality was imposed on an otherwise achiral molybdenum disulfide surface. This reversible method enables tunable chiral electronic states and opens new possibilities for advanced spintronic devices and the emerging field of &quot;chiral iontronics.&quot;</description>
                    <link>https://phys.org/news/2025-12-chirality-electricity-voltage-driven-method.html</link>
                    <category>Nanophysics</category>                    <pubDate>Sun, 21 Dec 2025 11:00:01 EST</pubDate>
                    <guid isPermaLink="false">news685367966</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/flipping-the-switch-on-2.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>High-precision analysis of 2D materials microstructures achieved using electron microscopy and machine learning</title>
                    <description>A research team led by NIMS has, for the first time, produced nanoscale images of two key features in an ultra-thin material: twist domains (areas where one atomic layer is slightly rotated relative to another) and polarities (differences in atomic orientation). The material, monolayer molybdenum disulfide (MoS₂), is regarded as a promising candidate for use in next-generation electronic devices.</description>
                    <link>https://phys.org/news/2025-11-high-precision-analysis-2d-materials.html</link>
                    <category>Nanomaterials</category>                    <pubDate>Thu, 13 Nov 2025 16:24:03 EST</pubDate>
                    <guid isPermaLink="false">news682273441</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/high-precision-analysi.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Pressure turns Ångström-thin semiconducting bismuth into a metal, expanding options for reconfigurable electronics</title>
                    <description>Two-dimensional (2D) materials, sparked by the isolation of Nobel-prize-winning graphene in 2004, has revolutionized modern materials science by showing that electrical, optical, and mechanical behaviors can be tuned simply by adjusting the thickness, strain, or stacking order of such 2D materials. From transistors and flexible display to neuromorphic chips, the future of electronics is expected to be significantly empowered by 2D materials.</description>
                    <link>https://phys.org/news/2025-10-pressure-ngstrm-thin-semiconducting-bismuth.html</link>
                    <category>Nanophysics</category>                    <pubDate>Fri, 24 Oct 2025 12:38:03 EDT</pubDate>
                    <guid isPermaLink="false">news680528281</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/pressure-turns-thin-se.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Stretchable light-emitting material holds promise for photon-based devices</title>
                    <description>A research team led by the California NanoSystems Institute at UCLA, or CNSI, demonstrated a new type of light-emitting material expected to be suitable for photonics—devices based on light in the same way that today&#039;s electronics are based on electrical signals.</description>
                    <link>https://phys.org/news/2025-09-stretchable-emitting-material-photon-based.html</link>
                    <category>Nanophysics</category>                    <pubDate>Fri, 26 Sep 2025 10:03:04 EDT</pubDate>
                    <guid isPermaLink="false">news678099781</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/new-stretchable-light.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Deep learning automates defect detection in 2D materials</title>
                    <description>A study published in Molecules and led by researchers from the Changchun Institute of Optics, Fine Mechanics and Physics (CIOMP) of the Chinese Academy of Sciences demonstrated how deep learning can streamline the identification of atomic-scale defects in molybdenum disulfide (MoS2), a promising two-dimensional (2D) material for next-generation electronics.</description>
                    <link>https://phys.org/news/2025-08-deep-automates-defect-2d-materials.html</link>
                    <category>Nanophysics</category>                    <pubDate>Thu, 21 Aug 2025 08:31:34 EDT</pubDate>
                    <guid isPermaLink="false">news674983868</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/deep-learning-automate.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>New imaging method reveals how light and heat generate electricity in nanomaterials</title>
                    <description>UC Riverside researchers have unveiled a powerful new imaging technique that exposes how cutting-edge materials used in solar panels and light sensors convert light into electricity—offering a path to better, faster, and more efficient devices.</description>
                    <link>https://phys.org/news/2025-07-imaging-method-reveals-generate-electricity.html</link>
                    <category>General Physics</category>                    <pubDate>Thu, 31 Jul 2025 06:24:48 EDT</pubDate>
                    <guid isPermaLink="false">news673161883</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/researchers-shed-light-3.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>From hydration layers to nanoarchitectures: Water&#039;s pivotal role in peptide organization on 2D nanomaterials</title>
                    <description>Researchers at the Nano Life Science Institute (WPI-NanoLSI), Kanazawa University, report in Small, on how short peptides self-assemble linearly on atomically-thick solid surfaces, such as graphite and MoS2.</description>
                    <link>https://phys.org/news/2025-06-hydration-layers-nanoarchitectures-pivotal-role.html</link>
                    <category>Nanomaterials</category>                    <pubDate>Thu, 26 Jun 2025 11:04:47 EDT</pubDate>
                    <guid isPermaLink="false">news670154683</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/from-hydration-layers.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Coupled electrons and phonons may flow like water in 2D semiconductors</title>
                    <description>A condition long considered to be unfavorable to electrical conduction in semiconductor materials may actually be beneficial in 2D semiconductors, according to new findings by UC Santa Barbara researchers published in the journal Physical Review Letters.</description>
                    <link>https://phys.org/news/2025-06-coupled-electrons-phonons-2d-semiconductors.html</link>
                    <category>Nanophysics</category>                    <pubDate>Mon, 23 Jun 2025 13:00:16 EDT</pubDate>
                    <guid isPermaLink="false">news669902402</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/coupled-electrons-and.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>New approach reversibly configures single and heteronuclear dual-atom catalysts on MoS₂ substrate</title>
                    <description>Single-atom catalysts (SACs) are materials consisting of individual metal atoms dispersed on a substrate (i.e., supporting surface). Recent studies have highlighted the promise of these catalysts for the efficient conversion and storage of energy, particularly when deployed in fuel cells and water electrolyzers.</description>
                    <link>https://phys.org/news/2025-06-approach-reversibly-configures-heteronuclear-dual.html</link>
                    <category>Nanomaterials</category>                    <pubDate>Fri, 13 Jun 2025 06:50:01 EDT</pubDate>
                    <guid isPermaLink="false">news668947073</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/an-approach-to-reversi-1.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>New study visualizes platinum doping on ultrathin 2D material with atomic precision</title>
                    <description>A popular 2D active material, molybdenum disulfide (MoS2), just got a platinum upgrade at an atomic level. A study led by researchers from the University of Vienna and Vienna University of Technology embedded individual platinum (Pt) atoms onto an ultrathin MoS2 monolayer and, for the first time, pinpointed their exact positions within the lattice with atomic precision.</description>
                    <link>https://phys.org/news/2025-06-visualizes-platinum-doping-ultrathin-2d.html</link>
                    <category>Nanomaterials</category>                    <pubDate>Wed, 11 Jun 2025 10:53:04 EDT</pubDate>
                    <guid isPermaLink="false">news668857968</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/new-study-visualizes-p.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Researchers realize direct methane to acetic acid conversion under mild conditions</title>
                    <description>The direct conversion of methane (CH4) into high-value-added multi-carbon (C2+) oxygenates, such as acetic acid (CH3COOH), under mild conditions offers a promising way to upgrade natural gas into transportable liquid chemicals. However, achieving this transformation efficiently remains a major challenge due to strong C-H bonds in methane, the difficulty of oxygen (O2) activation, and the low selectivity of C-C coupling reactions.</description>
                    <link>https://phys.org/news/2025-06-methane-acetic-acid-conversion-mild.html</link>
                    <category>Analytical Chemistry</category>                    <pubDate>Tue, 10 Jun 2025 11:31:56 EDT</pubDate>
                    <guid isPermaLink="false">news668773913</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/researchers-realize-di.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Revealing hidden transformations in 2D materials with atomic force microscopes</title>
                    <description>Researchers at the Institute of Physics in Zagreb, Croatia, in collaboration with international partners, have showcased new methods for visualizing atomic-scale changes in advanced materials.</description>
                    <link>https://phys.org/news/2025-06-revealing-hidden-2d-materials-atomic.html</link>
                    <category>Nanomaterials</category>                    <pubDate>Wed, 04 Jun 2025 10:58:03 EDT</pubDate>
                    <guid isPermaLink="false">news668253481</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/revealing-hidden-trans.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Torsion unipolar barrier heterojunction device simplifies optical imaging and sensing</title>
                    <description>Polarization, along with intensity, wavelength, and phase, is a fundamental property of light. It enhances contrast and resolution in imaging compared to traditional intensity-based methods. On-chip polarization devices rely on complex four-pixel arrays or external polarizers.</description>
                    <link>https://phys.org/news/2025-04-torsion-unipolar-barrier-heterojunction-device.html</link>
                    <category>Optics &amp; Photonics</category>                    <pubDate>Wed, 30 Apr 2025 16:30:03 EDT</pubDate>
                    <guid isPermaLink="false">news665249402</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/new-device-simplifies-1.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Scientists modulate 2D material properties via bending-induced interlayer sliding</title>
                    <description>A research group from the Ningbo Institute of Materials Technology and Engineering (NIMTE) of the Chinese Academy of Sciences has proposed a new strategy to precisely manipulate interlayer stacking orders and related properties in two-dimensional (2D) van der Waals layered materials via mechanical bending, enabling efficient electric polarization switching. The study is published in Physical Review Letters.</description>
                    <link>https://phys.org/news/2025-04-scientists-modulate-2d-material-properties.html</link>
                    <category>Nanophysics</category>                    <pubDate>Wed, 09 Apr 2025 13:04:03 EDT</pubDate>
                    <guid isPermaLink="false">news663422642</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/scientists-modulate-2d.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Defect removal technique paves the way for faster, low-power semiconductors</title>
                    <description>A research team, led by Professor Jimin Kwon from the Department of Electrical Engineering at UNIST, in collaboration with Professor Yong-Young Noh and his research team from the Department of Chemical Engineering at POSTECH, reports a new technology to eliminate defects in molybdenum disulfide (MoS2), a promising candidate for the next generation of semiconductor materials, at a temperature of 200°C.</description>
                    <link>https://phys.org/news/2025-03-defect-technique-paves-faster-power.html</link>
                    <category>Nanophysics</category>                    <pubDate>Mon, 31 Mar 2025 13:20:16 EDT</pubDate>
                    <guid isPermaLink="false">news662646014</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/defect-removal-techniq.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Transistor reshapes electronic properties of a 2D material</title>
                    <description>A RIKEN study shows that squeezing the right amount of potassium ions between the atomic layers of molybdenum disulfide can turn it from a semiconductor into a metal, superconductor or insulator. The same layered material can be made to behave as a superconductor, metal, semiconductor or insulator by using a transistor device developed by RIKEN physicists to tweak its electronic properties.</description>
                    <link>https://phys.org/news/2025-03-transistor-reshapes-electronic-properties-2d.html</link>
                    <category>Nanophysics</category>                    <pubDate>Thu, 27 Mar 2025 09:08:04 EDT</pubDate>
                    <guid isPermaLink="false">news662285282</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/transistor-reshapes-el.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Scientists achieve universal technique—called van der Waals squeezing—for atomic manufacturing of 2D metals</title>
                    <description>Since the groundbreaking discovery of graphene in 2004, the dizzying pace of progress in two-dimensional (2D) materials has ushered in a new era of fundamental research and technological innovation. Although nearly 2,000 2D materials have been theoretically predicted and hundreds have been created in laboratory settings, most of these 2D materials are limited to van der Waals (vdW) layered crystals.</description>
                    <link>https://phys.org/news/2025-03-scientists-universal-technique-van-der.html</link>
                    <category>Nanophysics</category>                    <pubDate>Wed, 12 Mar 2025 12:00:03 EDT</pubDate>
                    <guid isPermaLink="false">news660989068</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2023/graphene.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Mixing silicon with 2D materials for new energy-efficient semiconductor tech</title>
                    <description>Nanoelectronics deal with extremely small electronic components—transistors, sensors and circuits that can fit on the tip of a needle. This technology powers our everyday lives through devices such as computers, smartphones and medical tools.</description>
                    <link>https://phys.org/news/2025-01-silicon-2d-materials-energy-efficient.html</link>
                    <category>Nanophysics</category>                    <pubDate>Thu, 23 Jan 2025 14:28:13 EST</pubDate>
                    <guid isPermaLink="false">news656864886</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/ub-researchers-mix-sil.jpg" width="90" height="90" />
                                    </item>
                            <item>
                    <title>Next-gen fibers: Smart textile can sense light, pressure, smell and even taste</title>
                    <description>Researchers successfully developed a multifunctional sensor based on semiconductor fibers that emulates the five human senses. The technology developed in the study is expected to be utilized in a variety of state-of-the-art technology fields, such as wearables, Internet of Things (IoT), electronic devices, and soft robotics.</description>
                    <link>https://phys.org/news/2025-01-gen-fibers-smart-textile-pressure.html</link>
                    <category>Nanomaterials</category>                    <pubDate>Tue, 21 Jan 2025 12:56:02 EST</pubDate>
                    <guid isPermaLink="false">news656686561</guid>
                                            <media:thumbnail url="https://scx1.b-cdn.net/csz/news/tmb/2025/smart-textile-to-sense.jpg" width="90" height="90" />
                                    </item>
                        </channel>
</rss>