Renewable Energy /chbe/ en Weimer Group identifies material and scheme that may enable efficient solar-driven production of H2 and CO /chbe/2022/01/25/weimer-group-identifies-material-and-scheme-may-enable-efficient-solar-driven-production <span>Weimer Group identifies material and scheme that may enable efficient solar-driven production of H2 and CO </span> <span><span>Anonymous (not verified)</span></span> <span><time datetime="2022-01-25T13:39:24-07:00" title="Tuesday, January 25, 2022 - 13:39">Tue, 01/25/2022 - 13:39</time> </span> <div> <div class="imageMediaStyle focal_image_wide"> <img loading="lazy" src="/chbe/sites/default/files/styles/focal_image_wide/public/article-thumbnail/weimer_group_2.jpg?h=904df13e&amp;itok=zCshUFv-" width="1200" height="800" alt="Justin Tran and Kent Warren pose in front of lab equipment"> </div> </div> <div role="contentinfo" class="container ucb-article-categories" itemprop="about"> <span class="visually-hidden">Categories:</span> <div class="ucb-article-category-icon" aria-hidden="true"> <i class="fa-solid fa-folder-open"></i> </div> <a href="/chbe/taxonomy/term/78"> News </a> </div> <div role="contentinfo" class="container ucb-article-tags" itemprop="keywords"> <span class="visually-hidden">Tags:</span> <div class="ucb-article-tag-icon" aria-hidden="true"> <i class="fa-solid fa-tags"></i> </div> <a href="/chbe/taxonomy/term/4" hreflang="en">News</a> <a href="/chbe/taxonomy/term/385" hreflang="en">Renewable Energy</a> <a href="/chbe/taxonomy/term/383" hreflang="en">Tran</a> <a href="/chbe/taxonomy/term/381" hreflang="en">Warren</a> <a href="/chbe/taxonomy/term/379" hreflang="en">Weimer</a> </div> <span>Jonathan Raab</span> <div class="ucb-article-content ucb-striped-content"> <div class="container"> <div class="paragraph paragraph--type--article-content paragraph--view-mode--default"> <div class="ucb-article-content-media ucb-article-content-media-above"> <div> <div class="paragraph paragraph--type--media paragraph--view-mode--default"> <div> <div class="imageMediaStyle large_image_style"> <img loading="lazy" src="/chbe/sites/default/files/styles/large_image_style/public/article-image/weimer_group_2.jpg?itok=SyTOSuYW" width="1500" height="1125" alt="Justin Tran and Kent Warren pose in front of lab equipment"> </div> </div> </div> </div> </div> <div class="ucb-article-text d-flex align-items-center" itemprop="articleBody"> <div><div class="OutlineElement Ltr BCX2 SCXW247237663"> <p> </p><div class="ucb-box ucb-box-title-hidden ucb-box-alignment-right ucb-box-style-fill ucb-box-theme-white"> <div class="ucb-box-inner"> <div class="ucb-box-title"></div> <div class="ucb-box-content"><br> Tran and Warren in the Weimer lab. Photo courtesy the researchers.</div> </div> </div> <p><span lang="EN"><span>Hydrogen has long been seen as a </span><span>possible </span><span>renewable fuel source, held out of reach for full-scale adoption </span><span>by production costs</span><span> and inefficiencies</span><span>.</span><span> Researchers in the <a href="/lab/weimer/" rel="nofollow">Weimer Group</a> </span><span>are</span><span> working to address this by</span><span> using solar </span><span>thermal processing </span><span>to </span><span>drive</span><span> </span><span>high-temperature chemical reactions</span><span> </span><span>that</span><span> </span><span>produce</span><span> </span><span>hydrogen</span><span> and carbon monoxide, which can be used to synthesize liquid hydrocarbon</span><span> fuels</span><span>.</span></span> </p><p><span lang="EN"><span>Postdoc</span><span>toral </span><span>r</span><span>esearch </span><span>a</span><span>ssociate</span><span> </span></span><a href="/lab/weimer/kent-warren" rel="nofollow" target="_blank"><span lang="EN"><span>Kent Warren</span></span></a><span lang="EN"><span> and </span><span>graduate student </span></span><a href="/lab/weimer/justin-tran" rel="nofollow" target="_blank"><span lang="EN"><span>Justin Tran</span></span></a><span lang="EN"><span> of the Weimer Group are co-authors with </span><span>Melvin E. and Virginia M. Clark Professor </span></span><a href="/chbe/alan-w-weimer" rel="nofollow" target="_blank"><span lang="EN"><span>Alan Weimer</span></span></a><span lang="EN"><span> </span><span>on </span><span>“A thermochemical study of iron aluminate-based materials: a preferred class for isothermal water splitting” published in </span></span><a href="https://pubs.rsc.org/en/content/articlelanding/2022/EE/D1EE02679H" rel="nofollow" target="_blank"><span lang="EN"><span>Energy</span><span> </span><span>&amp;</span><span> </span><span>Environmental Science</span></span></a><span lang="EN"><span> earlier this month.</span></span><span> </span></p> </div> <div class="OutlineElement Ltr BCX2 SCXW247237663"> <blockquote> <p><span lang="EN"><span>“This will result in a seismic shift in research directions for solar thermal water splitting,” </span><span>Weimer said.</span></span><span> </span> </p></blockquote> </div> <div class="OutlineElement Ltr BCX2 SCXW247237663"> <p><span lang="EN"><span>Warren, Tran</span><span> and Weimer believe that low-cost iron aluminate-based oxides may improve performance over current </span><span>methods</span><span> of thermochemical </span><span>H</span><span>2</span><span> production</span><span>, as they remain effective </span><span>under </span><span>less favorable</span><span> </span><span>conditions expected </span><span>in</span><span> </span><span>large-scale production systems</span><span> </span><span>where</span><span> </span><span>implementing </span><span>wide </span><span>temperature changes </span><span>and</span><span> using</span><span> </span><span>excess steam </span><span>is avoided to </span><span>improve the process’ efficiency.</span></span><span> </span> </p></div> <div class="OutlineElement Ltr BCX2 SCXW247237663"> <p><span lang="EN"><span>“There is a prevailing consensus in the solar thermochemistry community that, in order to produce an appreciable hydrogen yield under an isothermal operating configuration, prohibitive amounts of steam are required,” Warren said. “We conclusively demonstrated that, for the first time, this concern can be mitigated with proper active material selection. My hope is that this work not only helps rewrite this narrative, but also encourages other research labs and institutions to consider </span><span>thermochemical water-splitting as </span><span>a </span><span>more viable alternative to </span><span>other green </span><span>hydrogen </span><span>technologies</span><span> </span><span>such as </span><span>water electrolysis.”</span></span><span> </span> </p></div> <div class="OutlineElement Ltr BCX2 SCXW247237663"> <p><span lang="EN"><span>The researchers came to this conclusion by establishing </span><span>the </span><span>thermodynamic equilibrium behavior</span><span> of iron aluminate-based oxides, then compared their findings to other materials </span><span>subjected to</span><span> </span><span>similar </span><span>methods</span><span> </span><span>by other researchers.</span></span><span> </span> </p></div> <div class="OutlineElement Ltr BCX2 SCXW247237663"> <blockquote> <p><span lang="EN"><span>“W</span><span>e demonstrate that iron aluminate-based oxides can isothermally outperform other candidates, even when said candidates are exposed to more favorable temperature-swing conditions</span><span>,” Warren said.</span></span><span> </span> </p></blockquote> </div> <div class="OutlineElement Ltr BCX2 SCXW247237663"> <p><span lang="EN"><span>Warren cited his ten-year fascination with solar thermochemistry as inspiration for his work on this project, going back to his time as an undergraduate at Valparaiso University and later as a graduate research assistant at the University of Florida under Associate Professor Jonathan Scheffe, who is a former graduate student of Weimer’s.</span></span><span> </span> </p></div> <div class="OutlineElement Ltr BCX2 SCXW247237663"> <p><span lang="EN"><span>“I</span><span>n 2019</span><span>,</span><span> I was offered a postdoctoral position to work with </span><span>Professor Weimer </span><span>on </span><span>‘</span><span>breaking the world record</span><span> of</span><span> solar-to-hydrogen conversion efficiency,</span><span>’ which</span><span> I eagerly accepted</span><span>,” Warren said.</span><span> </span><span>“</span><span>Before I undertook that challenge, however, I needed to ensure that we were operating with the ideal material composition under conditions most favorable for practical applications.</span><span>”</span></span><span> </span> </p></div> <div class="OutlineElement Ltr BCX2 SCXW247237663"> <p><span lang="EN"><span>Prior to Warren’s arrival at CU Boulder, Weimer had </span><span>performed some preliminary work on iron aluminate-based oxides</span><span>.</span></span><span> </span> </p></div> <div class="OutlineElement Ltr BCX2 SCXW247237663"> <p><span lang="EN"><span>“T</span><span>hat was the natural starting point</span><span>,” Warren said.</span><span> </span><span>“</span><span>I did not expect to learn that this class of materials exhibits such favorable thermodynamic properties under such adverse operating conditions.</span><span>”</span></span><span> </span> </p></div> <div class="OutlineElement Ltr BCX2 SCXW247237663"> <p><span lang="EN"><span>Graduate research assistant </span><span>Justin Tran was responsible for gaining insight into the workings and mechanism of the iron </span><span>aluminate</span><span>-based materials during th</span><span>e </span><span>characterization process. He developed phase diagrams and ran Rietveld </span><span>r</span><span>efinement to help the group thermochemically characterize them.</span><span>&nbsp; </span></span> </p></div> <div class="OutlineElement Ltr BCX2 SCXW247237663"> <p><span lang="EN"><span>“I'm inspired to work in this topic because of the potential to efficiently produce clean fuel, having a higher theoretical efficiency than competing processes,” Tran said. “This field still has a lot of room to grow and I'm excited to be part of </span><span>that.”</span></span><span> </span> </p></div> <div class="OutlineElement Ltr BCX2 SCXW247237663"> <p><span lang="EN"><span>Warren believes their research serves as the </span><span>foundation</span><span> for the development of a prototype-scale reactor that will be evaluated with CU Boulder’s high-flux solar simulator facility</span><span>.</span></span><span> </span> </p></div> <div class="OutlineElement Ltr BCX2 SCXW247237663"> <p><span lang="EN"><span>“T</span><span>he goal is to establish a world record solar-to-hydrogen conversion efficiency – the key metric for benchmarking our technology against other pathways to green hydrogen</span><span>,” Warren said.</span></span><span> </span> </p></div> <div class="OutlineElement Ltr BCX2 SCXW247237663"> <p><span lang="EN"><span>Tran expressed hope that their work will bring renewed interest to thermochemical fuel production, particularly isothermal operation.</span></span><span> </span> </p></div> <div class="OutlineElement Ltr BCX2 SCXW247237663"> <blockquote> <p><span lang="EN"><span>“</span><span>This work shows that with the proper material choice, we can efficiently produce clean, sustainable fuels</span><span>,” Tran said.</span></span><span> </span> </p></blockquote> </div> <div class="OutlineElement Ltr BCX2 SCXW247237663"> <p><span lang="EN"><span>Tran’s </span><span>position with the Weimer Group is funded by a National Science Foundation Graduate Research Fellowship Program. Parts of this research project </span><span>a</span><span>re </span><span>included in</span><span> a CHEN 4530 senior capstone design project. It </span><span>i</span><span>s </span><span>sponsored by OMC Hydrogen</span><span>, a startup interested in developing commercial green hydrogen processing, and </span><span>i</span><span>s </span><span>supported by the </span></span><a href="/engineering/bold" rel="nofollow" target="_blank"><span lang="EN"><span>BOLD Center</span></span></a><span lang="EN"><span>.</span></span> </p></div></div> </div> </div> </div> </div> <div>Hydrogen has long been seen as a possible renewable fuel source, held out of reach for full-scale adoption by production costs and inefficiencies. Researchers in the Weimer Group are working to address this by using solar thermal processing to drive high-temperature chemical reactions that produce hydrogen and carbon monoxide, which can be used to synthesize liquid hydrocarbon fuels.</div> <h2> <div class="paragraph paragraph--type--ucb-related-articles-block paragraph--view-mode--default"> <div>Off</div> </div> </h2> <div>Traditional</div> <div>0</div> <div>On</div> <div>White</div> Tue, 25 Jan 2022 20:39:24 +0000 Anonymous 3109 at /chbe