{"id":26403,"date":"2025-05-27T11:59:14","date_gmt":"2025-05-27T06:14:14","guid":{"rendered":"https:\/\/www.revoscience.com\/en\/?p=26403"},"modified":"2025-05-27T12:01:00","modified_gmt":"2025-05-27T06:16:00","slug":"unlocking-a-new-way-to-boost-green-energy-materials-without-rare-elements","status":"publish","type":"post","link":"https:\/\/www.revoscience.com\/en\/unlocking-a-new-way-to-boost-green-energy-materials-without-rare-elements\/","title":{"rendered":"Unlocking a new way to boost green energy materials without rare elements"},"content":{"rendered":"\n<figure class=\"wp-block-image size-large\"><img loading=\"lazy\" decoding=\"async\" width=\"1024\" height=\"381\" sizes=\"auto, (max-width: 1024px) 100vw, 1024px\" src=\"https:\/\/www.revoscience.com\/en\/wp-content\/uploads\/2025\/05\/Phonon-dispersion-map-single-crystalline-1024x381.jpeg\" alt=\"Phonon dispersion map of single crystalline \u03b2-Zn\u2084Sb\u2083 at 300 K, measured in the longitudinal scan along [hh0].\" class=\"wp-image-26404\" title=\"\" srcset=\"https:\/\/www.revoscience.com\/en\/wp-content\/uploads\/2025\/05\/Phonon-dispersion-map-single-crystalline-1024x381.jpeg 1024w, https:\/\/www.revoscience.com\/en\/wp-content\/uploads\/2025\/05\/Phonon-dispersion-map-single-crystalline-675x251.jpeg 675w, https:\/\/www.revoscience.com\/en\/wp-content\/uploads\/2025\/05\/Phonon-dispersion-map-single-crystalline-768x285.jpeg 768w, https:\/\/www.revoscience.com\/en\/wp-content\/uploads\/2025\/05\/Phonon-dispersion-map-single-crystalline-150x56.jpeg 150w, https:\/\/www.revoscience.com\/en\/wp-content\/uploads\/2025\/05\/Phonon-dispersion-map-single-crystalline.jpeg 1098w\" \/><figcaption class=\"wp-element-caption\"><em><sup>Phonon dispersion map single crystalline \u03b2-Zn\u2084Sb\u2083 at 300 K, measured in the longitudinal scan along [hh0].<\/sup><\/em> <sup>IMAGE: NTU<\/sup><\/figcaption><\/figure>\n\n\n\n<p>A research team has discovered how to make a promising energy-harvesting material much more efficient without relying on rare or expensive elements. The material, called \u03b2-Zn\u2084Sb\u2083, is a tellurium-free thermoelectric compound that can convert waste heat into electricity. <\/p>\n\n\n\n<p>In their latest study, scientists used advanced neutron scattering techniques to peek inside the crystal and found something surprising: tiny heat vibrations (called phonons) were being disrupted by \u201crattling\u201d atoms inside the structure. This phenomenon, known as\u00a0<em>phonon avoided crossing<\/em>, dramatically slowed down how heat travels through the material.<\/p>\n\n\n\n<p>Thanks to this effect, the material\u2019s thermal conductivity dropped to extremely low levels\u2014great news for thermoelectric performance. Even better, the researchers found that the single-crystal version of this material also conducts electricity better than its polycrystalline counterpart, reaching a high power conversion efficiency of 1.4%. These results show that smart phonon control can lead to high-performance, eco-friendly materials for converting heat into power.<\/p>\n\n\n\n<p>In thermoelectric materials, avoided crossing refers to the interaction between propagating phonons and localized vibrational modes, where their energy dispersions repel each other rather than intersect. This phenomenon occurs under specific conditions, such as crystal symmetries or vibrational mode couplings.<\/p>\n\n\n\n<p>However, when researchers developed the single-crystal&nbsp;<em>\u03b2<\/em>-Zn\u2084Sb\u2083, they observed an unexpected, avoided crossing, revealing unique phonon behavior that deviated from conventional thermoelectric materials.<\/p>\n\n\n\n<p>The article explores the thermoelectric performance of single-crystalline \u03b2-Zn\u2084Sb\u2083, a tellurium-free material, by uncovering the microscopic mechanisms that lead to its ultralow lattice thermal conductivity (\u03ba<sub>L<\/sub>).<\/p>\n\n\n\n<p>Using inelastic neutron scattering (INS), the researchers provide the first experimental observation of avoided crossing between longitudinal acoustic phonons and low-energy rattling modes. This interaction causes a significant reduction in phonon group velocity\u2014from over 4000 m\/s to about 591 m\/s\u2014and shortens phonon lifetimes to under 1 picosecond, both of which contribute to strongly suppressed heat transport.<\/p>\n\n\n\n<p>The&nbsp;<em>\u03b2<\/em>-Zn\u2084Sb\u2083 single crystal achieves a \u03ba<sub>L<\/sub>&nbsp;of approximately 0.36 W\/m\u00b7K in the 300\u2013600 K range and a peak thermoelectric figure of merit (zT) of 1.0 at 623 K. Additionally, device-level testing shows a conversion efficiency (\u03b7) of 1.4% in a single-leg thermoelectric module\u2014one of the highest reported for undoped Zn\u2084Sb\u2083.<\/p>\n\n\n\n<p>Structural characterizations via TEM reveal a grain-boundary-free lattice with uniformly distributed moir\u00e9 fringes, attributed to Zn concentration variations. These nanoscale features further enhance phonon scattering without degrading electronic performance. Compared to polycrystalline samples, the single crystal exhibits significantly better electrical conductivity due to fewer defects and optimized carrier mobility.<\/p>\n\n\n\n<p>&#8220;This discovery shows how heat flow can be engineered to design more efficient and sustainable energy technologies\u2014without depending on scarce resources,\u201d says Prof. Hsin-Jay Wu.<\/p>\n","protected":false},"excerpt":{"rendered":"<p>A research team has discovered how to make a promising energy-harvesting material much more efficient without relying on rare or expensive elements. 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