Results 151 to 160 of about 1,063,085 (285)
Investigation of Oxygen‐Free Wetting Behavior of Aluminum on Copper via Molecular Dynamics Simulations and Experiments
Advanced Engineering Materials, EarlyView.The wettability of aluminum droplets (Al) on different copper substrates (Cu), where liquid Al spreads on solid Cu surfaces to form a liquid–solid interface, is studied numerically and experimentally. The experimental and numerical results show good agreement in the fast‐spreading regime.Shan Lyu, Timon Steinhoff, Finn‐Lennard Janthur, Sarah Seffer, Jörg Hermsdorf, Christian Klose, Ludger Overmeyer, Hans‐Jürgen Maier, Nina Merkert +8 morewiley +1 more sourceDevelopment of Sustainable MgO–C Refractories Using MgO–C Recyclates and a Novel Eco‐Friendly Fructose–Tannin Binder Crosslinked With Citric Acid
Advanced Engineering Materials, EarlyView.This study develops sustainable MgO–C refractories using recycled materials and eco‐friendly fructose–tannin binders. The enhanced performance of citric acid as a cross‐linker and functional additives on mechanical and thermomechanical properties was examined. Characterization included strength tests, immersion trials, and microstructural and inclusion Dinesh K. Gunasekar, Jana Hubálková, Steffen Dudczig, Gert Schmidt, Florian Kerber, Thomas Schemmel, Patrick Gehre, Christos G. Aneziris +7 morewiley +1 more sourceDeterministic Detection of Single Ion Implantation
Advanced Engineering Materials, EarlyView.Focused ion beam implantation with high detection efficiencies will enable the rapid and scalable fabrication of advanced spin‐based technologies such as qubits. This work presents the detection efficiencies of a wide range of ions implanted into solid‐state hosts, with efficiencies of >90% recorded for ion species and substrate combinations of ...Mason Adshead, Lok Kan Wan, Maddison Coke, Janet Jacobs, Nicholas F. L. Collins, Mark C. Rosamond, Richard J. Curry +6 morewiley +1 more sourceHigher order terms for the quantum evolution of a Wick observable within the Hepp method</a> </p><span class="r_subtitle"><img src="/img/openaccess.ico" alt="open access: yes" title="open access: yes" width="16" height="16"><i>Cubo</i>, 2012 </span><br><span class="r_content">El metodo de Hepp describe en terminos de estados coherentes la dinamica en campo medio de bosones o la propagación semiclasica. Un punto clave es la evolución asintótica de observables de Wick bajo la evolucion dada por un Hamiltoniano cuadratico ...</span><br><span class="r_sub"><i>Sébastien Breteaux</i></span><br><small><a href="https://doaj.org/article/4b1de5db30a347e9a4f66db355c6c5b6" target="_blank" rel="nofollow" title="doaj.org/article/4b1de5db30a347e9a4f66db355c6c5b6">doaj</a> </small> <br></div><div class="r"><p class="r_title"><a href="https://doi.org/10.1002/adem.202502943" target="_blank" rel="nofollow">Unraveling the Effect of Tramp Elements on Phase Transformations in Steels by Combining CALPHAD Modeling and Experiments</a> </p><span class="r_subtitle"><img src="/img/openaccess.ico" alt="open access: yes" title="open access: yes" width="16" height="16"><i>Advanced Engineering Materials, EarlyView.</i></span><br><span class="r_content">This study investigates how tramp elements from increased scrap usage influence phase transformations in low‐alloyed steel. Combining dilatometry and microscopy reveal that tramp elements delay transformations, reduce critical cooling rates and increase hardenability.</span><br><span class="r_sub"><i>Lukas Hatzenbichler<span id="ma_8" style="display:none">, Daniel Marian Ogris, Phillip Haslberger, Matthew Galler, Oleksandr Glushko, Ronald Schnitzer</span> <small><a href="#" style="color:#808080;" onClick="return toggle_div(this, 'ma_8')">+5 more</a></small></i></span><br><small><a href="https://onlinelibrary.wiley.com/doi/10.1002/adem.202502943?mi=2or9o2m&af=R&AllField=coherent states&ConceptID=15941&content=articlesChapters&target=default" target="_blank" rel="nofollow" title="wiley.com/doi/10.1002/adem.202502943?mi=2or9o2m&af=R&AllField=coherent states&ConceptID=15941&content=articlesChapters&target=default">wiley</a> </small> <div id="more_8" style="display:none"><a href="/sci_redir.php?doi=10.1002%2Fadem.202502943" target="_blank" rel="nofollow">openaccessbutton.org (pdf)</a><br><a href="javascript:navigator.clipboard.writeText('10.1002/adem.202502943'); alert('Copied the doi');">copy doi</a> <small>(10.1002/adem.202502943)</small><br></div><small><a href="#" onClick="return toggle_div(this, 'more_8')">+1 more source</a></small><br></div><div class="r"><p class="r_title"><a href="https://doi.org/10.1002/adem.202503030" target="_blank" rel="nofollow">Rafting of Ni‐Based Superalloys Under Multiaxial Load as Understood by Phase‐Field Simulations and Critical Experiments</a> </p><span class="r_subtitle"><img src="/img/openaccess.ico" alt="open access: yes" title="open access: yes" width="16" height="16"><i>Advanced Engineering Materials, EarlyView.</i></span><br><span class="r_content">Phase‐field simulations coupled with dislocation‐density‐based crystal plasticity modeling reproduce γ′ rafting behavior in single‐crystal Ni‐based superalloys under varied loading conditions. The model captures both macroscopic creep and microscopic morphology evolution, with results matching high‐temperature creep experiments.</span><br><span class="r_sub"><i>Micheal Younan<span id="ma_9" style="display:none">, David Bürger, Gunther Eggeler, Oleg Shchyglo, Ingo Steinbach, Muhammad Adil Ali</span> <small><a href="#" style="color:#808080;" onClick="return toggle_div(this, 'ma_9')">+5 more</a></small></i></span><br><small><a href="https://onlinelibrary.wiley.com/doi/10.1002/adem.202503030?mi=2or9o2m&af=R&AllField=coherent states&ConceptID=15941&content=articlesChapters&target=default" target="_blank" rel="nofollow" title="wiley.com/doi/10.1002/adem.202503030?mi=2or9o2m&af=R&AllField=coherent states&ConceptID=15941&content=articlesChapters&target=default">wiley</a> </small> <div id="more_9" style="display:none"><a href="/sci_redir.php?doi=10.1002%2Fadem.202503030" target="_blank" rel="nofollow">openaccessbutton.org (pdf)</a><br><a href="javascript:navigator.clipboard.writeText('10.1002/adem.202503030'); alert('Copied the doi');">copy doi</a> <small>(10.1002/adem.202503030)</small><br></div><small><a href="#" onClick="return toggle_div(this, 'more_9')">+1 more source</a></small><br></div><div class="r"><p class="r_title"><a href="https://doi.org/10.2478/s11534-009-0039-3" target="_blank" rel="nofollow">Coherent states for Smorodinsky-Winternitz potentials</a> </p><span class="r_subtitle"><img src="/img/openaccess.ico" alt="open access: yes" title="open access: yes" width="16" height="16"><i>Open Physics</i>, 2009 </span><br><span class="r_sub"><i>Ünal Nuri</i></span><br><small><a href="https://doaj.org/article/1afee7c14fcb4623a0118339d6b5222c" target="_blank" rel="nofollow" title="doaj.org/article/1afee7c14fcb4623a0118339d6b5222c">doaj</a> </small> <div id="more_10" style="display:none"><a href="/sci_redir.php?doi=10.2478%2Fs11534-009-0039-3" target="_blank" rel="nofollow">openaccessbutton.org (pdf)</a><br><a href="javascript:navigator.clipboard.writeText('10.2478/s11534-009-0039-3'); alert('Copied the doi');">copy doi</a> <small>(10.2478/s11534-009-0039-3)</small><br></div><small><a href="#" onClick="return toggle_div(this, 'more_10')">+1 more source</a></small><br></div><div class="r"><div style="margin-bottom:2px;overflow:hidden"><div style="display: inline-block; float: left; font-size: small; padding-right: 16px; margin-top: -1px; padding-bottom: 1px;"><a href="/q-fos%3A_physical_sciences/" class="suggestion"onclick="show_loader();"><b>fos: physical sciences</b></a><br/><a href="/q-physics/" class="suggestion"onclick="show_loader();"><b>physics</b></a><br/><a href="/q-quantum_physics_quant-ph/" class="suggestion"onclick="show_loader();"><b>quantum physics quant-ph</b></a><br/></div><div style="display: inline-block; float: left; font-size: small; padding-right: 16px; margin-top: -1px; padding-bottom: 1px;"><a href="/q-quantum_physics/" class="suggestion"onclick="show_loader();"><b>quantum physics</b></a><br/><a href="/q-mathematical_physics/" class="suggestion"onclick="show_loader();"><b>mathematical physics</b></a><br/><a href="/q-coherent_state/" class="suggestion"onclick="show_loader();"><b>coherent state</b></a><br/></div><div style="display: inline-block; float: left; font-size: small; padding-right: 16px; margin-top: -1px; padding-bottom: 1px;"><a href="/q-mathematical_physics_math-ph/" class="suggestion"onclick="show_loader();"><b>mathematical physics math-ph</b></a><br/><a href="/q-squeezed_states/" class="suggestion"onclick="show_loader();"><b>squeezed states</b></a><br/><a href="/q-entanglement/" class="suggestion"onclick="show_loader();"><b>entanglement</b></a><br/></div></div></div><div class="pagenav"><a href="/q-coherent_states/p-15/" rel="nofollow"><b>previous</b></a> <a href="/q-coherent_states/p-14/" rel="nofollow">14</a> <a href="/q-coherent_states/p-15/" rel="nofollow">15</a> <b>16</b> <a href="/q-coherent_states/p-17/" rel="nofollow">17</a> <a href="/q-coherent_states/p-18/" rel="nofollow">18</a> <a href="/q-coherent_states/p-17/" id="next" rel="nofollow"><b>next</b></a> </div><br></div>
</div>
<script>document.getElementById('loadingGif').style.display='none';</script><div style="width: 100%; height: 40px; bottom: 0px; background-color: #f5f5f5;"><div style="padding-left: 15px; padding-top: 10px">
<a href="/" rel="nofollow">Home</a> - <a href="/page-about/" rel="nofollow">About</a> - <a href="/page-disclaimer/" rel="nofollow">Disclaimer</a> - <a href="/page-privacy/" rel="nofollow">Privacy</a>
</div></div>
<link rel="stylesheet" href="//ajax.googleapis.com/ajax/libs/jqueryui/1.11.4/themes/smoothness/jquery-ui.min.css"/>
</body>
</html>
