{"version":"1.0","provider_name":"Silicon Saxony","provider_url":"https:\/\/silicon-saxony.de\/en\/","author_name":"publizer2silisax","author_url":"https:\/\/silicon-saxony.de\/en\/author\/publizer2silisax\/","title":"HZDR: On the trail of unconventional superconductivity - Silicon Saxony","type":"rich","width":600,"height":338,"html":"<blockquote class=\"wp-embedded-content\" data-secret=\"2Cm9PsNLZw\"><a href=\"https:\/\/silicon-saxony.de\/en\/hzdr-on-the-trail-of-unconventional-superconductivity\/\">HZDR: On the trail of unconventional superconductivity<\/a><\/blockquote><iframe sandbox=\"allow-scripts\" security=\"restricted\" src=\"https:\/\/silicon-saxony.de\/en\/hzdr-on-the-trail-of-unconventional-superconductivity\/embed\/#?secret=2Cm9PsNLZw\" width=\"600\" height=\"338\" title=\"&#8220;HZDR: On the trail of unconventional superconductivity&#8221; &#8212; Silicon Saxony\" data-secret=\"2Cm9PsNLZw\" frameborder=\"0\" marginwidth=\"0\" marginheight=\"0\" scrolling=\"no\" class=\"wp-embedded-content\"><\/iframe><script>\n\/*! This file is auto-generated *\/\n!function(d,l){\"use strict\";l.querySelector&&d.addEventListener&&\"undefined\"!=typeof URL&&(d.wp=d.wp||{},d.wp.receiveEmbedMessage||(d.wp.receiveEmbedMessage=function(e){var t=e.data;if((t||t.secret||t.message||t.value)&&!\/[^a-zA-Z0-9]\/.test(t.secret)){for(var s,r,n,a=l.querySelectorAll('iframe[data-secret=\"'+t.secret+'\"]'),o=l.querySelectorAll('blockquote[data-secret=\"'+t.secret+'\"]'),c=new RegExp(\"^https?:$\",\"i\"),i=0;i<o.length;i++)o[i].style.display=\"none\";for(i=0;i<a.length;i++)s=a[i],e.source===s.contentWindow&&(s.removeAttribute(\"style\"),\"height\"===t.message?(1e3<(r=parseInt(t.value,10))?r=1e3:~~r<200&&(r=200),s.height=r):\"link\"===t.message&&(r=new URL(s.getAttribute(\"src\")),n=new URL(t.value),c.test(n.protocol))&&n.host===r.host&&l.activeElement===s&&(d.top.location.href=t.value))}},d.addEventListener(\"message\",d.wp.receiveEmbedMessage,!1),l.addEventListener(\"DOMContentLoaded\",function(){for(var e,t,s=l.querySelectorAll(\"iframe.wp-embedded-content\"),r=0;r<s.length;r++)(t=(e=s[r]).getAttribute(\"data-secret\"))||(t=Math.random().toString(36).substring(2,12),e.src+=\"#?secret=\"+t,e.setAttribute(\"data-secret\",t)),e.contentWindow.postMessage({message:\"ready\",secret:t},\"*\")},!1)))}(window,document);\n<\/script>\n","description":"January 31, 2024. If certain metals are cooled low enough, their electrical resistance disappears and they conduct electricity without loss. This effect of superconductivity has been known for more than a hundred years and is now well understood for so-called conventional superconductors. Unconventional superconductors, on the other hand, are more recent and it is not yet clear how they work. A team from the Helmholtz-Zentrum Dresden-Rossendorf (HZDR), together with colleagues from the French research institute CEA (Commissariat \u00e0 l'\u00e9nergie atomique et aux \u00e9nergies alternatives), the Japanese University of T\u014dhoku and the Max Planck Institute for Chemical Physics of Solids in Dresden, has now gained new insights, as the researchers report in the journal Nature Communications (DOI: 10.1038\/s41467-023-44183-1). The findings could explain why a new type of material remains superconducting even in extremely high magnetic fields - a property that conventional superconductors lack and which could enable previously unthinkable technological applications.","thumbnail_url":"https:\/\/cdn.pblzr.de\/dacbb27c-1270-4041-b681-e2b95f06f8a1\/2024\/02\/hzdr-logo-400x300_TEXT.jpg"}