https://engineering.wustl.edu/news/Pages/Dream-Chaser.aspx737Dream Chaser<p>​Lots of kids grow up dreaming of missions into space. Gazing upward at the night sky. Dressing up as astronauts. Building model rockets and counting down to launch, 3…2…1…<br/></p><img alt="" src="/news/PublishingImages/Liz%20with%20Dream%20Chaser.JPG?RenditionID=1" style="BORDER:0px solid;" /><div id="__publishingReusableFragmentIdSection"><a href="/ReusableContent/36_.000">a</a></div><p>Liz Antognoli made her dreams real. After earning her bachelor's degree in mechanical engineering at Washington University in St. Louis in 1997, her career lifted off at NASA's Johnson Space Center in Houston. Now, following a dozen years as a flight controller, she is helping develop a new generation of vehicles to deliver people and payloads into orbit.</p><p>Antognoli, 42, is a systems engineer for NASA contractor Sierra Nevada Corp. in Louisville, Colo. The company is building the Dream Chaser, a reusable, autonomous spacecraft capable of being launched into low-Earth orbit atop an Atlas V rocket. One version — Antognoli's — will deliver cargo to and from the International Space Station (ISS). The vehicle resembles a mini space shuttle and is about one quarter of the size of the venerable spacecraft retired by NASA in 2011.</p><p>Dream Chaser is scheduled to make at least six cargo service missions between 2019 and 2024. Antognoli is at the heart of that effort, responsible for the integration of NASA's diverse cargo needs with the design, processes and operations Sierra Nevada engineers are developing to meet them.</p><blockquote>"Since I was six years old I wanted to be part of the space program," she says, "and I still find it challenging and inspiring."</blockquote><p>Growing up outside Chicago in Wheeling, Ill., Antognoli was fascinated with science. Physics class captivated her during high school, and guidance counselors suggested she pursue engineering.</p><p>"My dad took me around the country visiting colleges, and I fell in love with the WashU campus," Antognoli says. "I wanted to have opportunities to be well rounded and found them. I learned a lot about myself while I was there. It was the best place to allow essential elements of my personality blossom and come together."</p><div style="width: 100%; font-size: 0.9em; font-style: italic; color: #555555; padding: 0px 10px 10px 0px;"><div style="text-align: center;"> <img src="/news/PublishingImages/Wash%20U%20Move%20in%20Liz%20Antognoli.jpg?RenditionID=1" alt=""/> </div><div style="text-align: center;">Liz Antognoli, 1993<br/></div></div><p>Upon graduation, Antognoli began her career with NASA contractor United Space Alliance at Johnson Space Center. She served as a mission planner and flight controller while also remotely earning a master of science degree in space operations from the University of Colorado at Colorado Springs. NASA later became her direct employer, but all the while Antognoli was responsible for essential elements of space shuttle missions and ISS assembly. Highlights included the integration of the station's robotic arm and various cargo transportation and retrieval missions.</p><p>"On those missions I spoke directly to (shuttle and ISS) crew members every day to discuss cargo transfers and answer questions," Antognoli says. "That was one of my favorite things I've done in my career."</p><p>Antognoli found her way to Sierra Nevada and Dream Chaser when the space shuttle program wound down. She also began a side venture called Mission Control Education LLC, developing manuals and lesson plans to assist teachers in recreating NASA mission control centers in their classrooms to inspire future engineers.</p><p>Antognoli's study of the physical world has coincided with a complementary exploration of her inner self. Early in her NASA career, she found herself feeling angry and judgmental about herself and others. </p><p>"I had checked a lot of boxes that are supposed to represent success and happiness, but my inner life was not as joyful," she says.<br/></p><blockquote>She began searching within herself, and credits Fr. Gary Braun, director of WashU's Catholic Student Center, with sowing seeds of introspection during her college days.</blockquote><p>"He helped me examine approaches to spirituality and the questioning of beliefs," Antognoli said. </p><p>That process led to an introduction to yoga and the study of eastern philosophy. Her practice became so life-changing that for the past 14 years she has complemented her space operations career by teaching yoga and leading Ayurvedic workshops.</p><p>At home, Antognoli and her wife, Jen, are also busy raising their one-year-old son, Luca, and chasing around their dog, Mowgli.</p><p>Antognoli encourages today's WashU students to try new things, even if that means following a nonlinear path. </p><p>"Trust your interests and the things that provide you with inspiration and passion," Antognoli says. "If something is working, keep going. If it's not, change it."<br/></p> <SPAN ID="__publishingReusableFragment"></SPAN> <p> <br/> </p><span> <div class="cstm-section"><h3>WashU Women & Engineering</h3><div> <strong></strong></div><div style="text-align: center;">Women & Engineering was established as an organization for engineering alumnae from Washington University in St. Louis to support each other; inspire and mentor our women students; and help shape the School of Engineering & Applied Science.</div><div style="text-align: center;"> <br/> </div><div style="text-align: center;"> <span style="font-size: 1em;"> <a href="/alumni/programs-events/Pages/women-engineering.aspx">>> Read more & get involved</a></span></div></div></span> Liz AntognoliChristopher Tritto2017-10-16T05:00:00ZNASA veteran Liz Antognoli, EN '97, is helping develop a new generation of spacecraft to deliver payloads into orbit.<p>​NASA veteran Liz Antognoli is helping develop a new generation of spacecraft to deliver payloads into orbit<br/></p>
https://engineering.wustl.edu/news/Pages/The-First-40-Tim-Tague.aspx735The First 40: Tim Tague recorded a second of video a day<p>Meet Tim Tague — Washington University in St. Louis Class of 2021.<br/></p><p>Back in August, we asked these first-year students to record one second of video every day for their first 40 or so days on campus. Here, learn more about these students and their first days in college. <br/> <br/></p><div class="div.youtube-wrap"><div class="iframe-container"> <iframe width="854" height="480" frameborder="0" src="https://www.youtube.com/embed/Ok-H6fFKums"></iframe> <br/></div></div><p></p> <br/><a href="https://source.wustl.edu/2017/10/first-40-three-first-year-students-record-second-video-day/">>> Watch all three</a><br/><img alt="Tim Tague" src="/news/PublishingImages/Tim%20Tague%20WashU%20engineering.jpg?RenditionID=1" style="BORDER:0px solid;" /><h3>​Tague on his First 40:</h3><p>“I’ve enjoyed the simple moments and the random moments. Sometimes I’ll pause, look around and take a video. It’s made me realize how lucky I am to be in this place. So much has happened in these past 40 days. I can only imagine what will happen in the next four years.”</p><h3>Why did you pick Washington University?<br/></h3><p>If you were to ask me my favorite sport, I would answer football in the fall and baseball in the spring. I couldn’t imagine giving either one up, and WashU gave me the opportunity to play both. And, of course, it’s a really good school. That combination of academic and athletic excellence drew me here.<br/></p><h3>What’s dorm life like?<br/></h3><p>I live in a six-person suite. We all play either football or baseball, and one guy plays both like me. We play a lot of “Rocket League,” and we eat together. Whenever someone gets hungry, they shout out “BD” and we all go together. Some of my friends from home talk about all of the free time they have in college, but it seems like I always have work to do or practice to go to. However, I am really enjoying all the time I spend doing this work and the hours spent at practice, so the days go by very quickly. It would be nice to sit on the bed for one day and take a nap, but I guess that’s what break is for.<br/></p><h3>Have you joined any clubs?</h3><p>I’ve joined the Bear Cubs Running Team, which is a running club for kids on the autism spectrum. Annie Marggraff (AB 2017), who started the program, lives one town over from me and started a chapter back home that my sister, Nicole, joined. My sister has a rare genetic condition and faces so many challenges, but when she runs — something a lot of us complain about — she always has the biggest smile on her face. She is so positive and happy. I wanted to meet kids in similar situations and learn from them the way I’ve learned from Nicole.<br/></p><p><br/>​</p> <span> <div class="cstm-section"><h3>Tim Tague<br/></h3><div> <strong></strong></div><div><strong>Hometown:</strong><span style="color: #3c3d3d; font-family: 'source sans pro', 'helvetica neue', helvetica, arial, sans-serif;"> Orinda, Calif.<br/></span><br style="box-sizing: inherit; color: #3c3d3d; font-family: 'source sans pro', 'helvetica neue', helvetica, arial, sans-serif;"/><strong>Major:</strong><span style="color: #3c3d3d; font-family: 'source sans pro', 'helvetica neue', helvetica, arial, sans-serif;"> Mechanical engineering </span></div></div></span>Tim Tague Diane Toroian Keaggyhttps://source.wustl.edu/2017/10/first-40-three-first-year-students-record-second-video-day/2017-10-12T05:00:00ZMeet Tim Tague — Washington University in St. Louis Class of 2021.
https://engineering.wustl.edu/news/Pages/Spartan-Makerspace-will-foster-innovation-and-entrepreneurship.aspx726Spartan Makerspace will foster innovation and entrepreneurship<p>​“I believe making things with your hands is essential to being a truly well-rounded engineer,” says Washington University Trustee Donald Jubel, BS ’73, chief executive officer of Spartan Light Metal Products. “You can learn the nuances of using different materials. You also learn to have respect for the people who actually make products. I have designed things that have turned out to be almost impossible to make. Learning from your mistakes is a great teacher.”<br/></p><img alt="" src="/news/PublishingImages/Spartan-Light-Metal-Products-Maker-SpaceFINAL-1aj0guj.jpg?RenditionID=1" style="BORDER:0px solid;" /><p>​To give Washington University students enhanced opportunities to learn by working with their hands, Spartan has pledged $1 million to create the Spartan Light Metal Products Maker Space. The cutting-edge facility will be centrally located on the ground floor of <a href="https://campusnext.wustl.edu/items/henry-a-and-elvira-h-jubel-hall/">Henry A. and Elvira H. Jubel Hall</a>, which was named in 2013 with a substantial commitment from the Jubel family through the Henry A. Jubel Foundation. Jubel Hall, part of the university’s east end transformation project, will be completed in 2019 and will house the Department of Mechanical Engineering & Materials Science in the School of Engineering & Applied Science.<br/></p><p>The Spartan Makerspace will transform the way students and faculty members interact with their subject matter in many areas of study. Its state-of-the-art resources will include 3D printers and scanners, plasma cutters, computer-controlled milling machines, and lathes for cutting metal. Such tools can be used to create everything from tech products and biomedical devices to sculptures and architectural mock-ups.</p><blockquote>“The makerspace will accelerate innovation and entrepreneurship across Washington University,” says<a href="/Profiles/Pages/Philip-Bayly.aspx"> Philip Bayly</a>, chair of mechanical engineering and the Lilyan and E. Lisle Hughes Professor. “It will provide a place where innovators can bring to life designs for addressing society’s challenges.</blockquote> <p>“For entrepreneurs, working prototypes are a huge help in demonstrating an idea in order to obtain patent protection, convince investors, and attract customers,” he adds. “The Spartan Makerspace will provide students and faculty with sophisticated fabrication capabilities that will allow them to have an even greater impact on our world.”</p><p>In 1961, Donald Jubel’s father, Henry Jubel, BS ’40, founded Spartan Light Metal Products, which has become an industry leader in the design and manufacture of aluminum and magnesium custom diecasting products and assemblies. He attributed his success to his Washington University education. Beginning with Henry, three generations of the Jubel family have earned degrees in mechanical engineering at the university, including Donald and his daughter Lindsey, BS ’09, MS ’09.</p><p>For decades, the Jubel family has provided extraordinary support and leadership for Washington University. The family and its foundation have directed significant gifts and annual support to scholarships and programs in the engineering school and to the Alvin J. Siteman Cancer Center. Among his many roles, Donald is a member of the engineering school’s national council and the university’s Alumni Board of Governors. His daughter Melissa Markwort, EMBA ’14, is a member of the LEAD Initiative committee for the engineering school and the Family Business Steering Committee for Olin Business School. She also serves as chair of the Fellows Committee for the William Greenleaf Eliot Society.</p><p>“The Jubels have championed both education and manufacturing in our region and beyond,” Professor Bayly says. “It means a great deal to the university for the maker space to bear the Spartan name.”<br/></p><br/><br/><br/> <span> <div class="cstm-section"><h3>Henry A. and Elvira H. Jubel Hall Details<br/></h3><div> <strong></strong></div><div><ul style="padding: 0px; margin: 0px 0px 1.33333em 1em; z-index: 0; color: #555555; font-family: "source sans pro", "helvetica neue", helvetica, arial, sans-serif; font-size: 18px;"><li style="line-height: 1.33333; left: 1em; margin-top: 0.44444em; margin-bottom: 0.44444em; margin-right: 1em;"><p>80,600 square ft. <br/></p></li><li><p>15,600 sq. ft. research lab space</p></li><li><p>7,850 sq. ft. faculty offices</p></li><li><p>3,350 sq. ft. makerspace <br/></p></li><li><p>Located south of Whitaker Hall, east of the Hub, and north of the new Ann and Andrew Tisch Park<br/></p></li><li style="line-height: 1.33333; left: 1em; margin-top: 0.44444em; margin-bottom: 0.44444em; margin-right: 1em;"><p>Two 65-seat pooled classrooms<br/></p></li><li style="line-height: 1.33333; left: 1em; margin-top: 0.44444em; margin-bottom: 0.44444em; margin-right: 1em;"><p><a href="https://campusnext.wustl.edu/items/henry-a-and-elvira-h-jubel-hall/">More details</a><br/></p></li></ul></div></div></span>“It (Spartan Light Metal Products Makerspace) is designed to pique interest,” Donald Jubel says. “Who knows, it may lead some students to change their major to engineering!”Kelly Marksburyhttp://together.wustl.edu/Pages/Jubel-Maker-Space.aspx2017-10-03T05:00:00ZThe new makerspace will include 3-D printers and scanners, plasma cutters, computer-controlled milling machines, and lathes for cutting metal.
https://engineering.wustl.edu/news/Pages/WashU-engineer-seeks-new-catalysts-from-2-D-materials.aspx717WashU engineer seeks new catalysts from 2-D materials<p>​Electrochemical systems, such as fuel cells, depend on catalysts to increase the rate of the chemical reactions. A team of engineers and materials scientists at Washington University in St. Louis and the University of Illinois at Chicago (UIC), plan to find new, highly efficient catalysts based on 2-D materials, which could have a revolutionary impact in energy-related systems, such as in the conversion of carbon dioxide, a greenhouse gas, into energy-rich fuels.<br/></p><img alt="" src="/Profiles/PublishingImages/Mishra_Rohan_03.jpg?RenditionID=1" style="BORDER:0px solid;" /><div id="__publishingReusableFragmentIdSection"><a href="/ReusableContent/36_.000">a</a></div><p><a href="/Profiles/Pages/Rohan-Mishra.aspx">Rohan Mishra</a>, assistant professor of mechanical engineering & materials science at WashU, received a four-year, $361,177 grant from the National Science Foundation to design these materials working in collaboration with Amin Salehi-Khojin, a mechanical engineer, and Robert Klie, a materials physicist, both at UIC. The grant is part of the Materials Genome Initiative launched by President Barack Obama in 2011 as a multi-agency initiative to create policy, resources and infrastructure that support U.S. institutions to discover, manufacture and deploy advanced materials efficiently and cost-effectively.<br/></p><p style="color: #000000; font-family: "times new roman"; font-size: medium;"></p><p>“Electrocatalysts are used in reducing carbon dioxide to carbon monoxide or into a hydrocarbon fuel, or to reduce oxygen for subsequent use in fuel cells or in lithium-air batteries,” said Mishra, a materials scientist in the School of Engineering & Applied Science. “We believe this will have applications in numerous areas.”</p><p style="color: #000000; font-family: "times new roman"; font-size: medium;"></p><p>Currently, precious materials including platinum and silver nanoparticles are used as catalysts but are too costly for widespread commercial use. In 2004, researchers discovered graphene, sparking discovery of a variety of new 2-D materials that Mishra said are simply a sheet of atoms.</p><p style="color: #000000; font-family: "times new roman"; font-size: medium;"></p><p>“My collaborators at UIC have recently discovered that when they take a particular class of 2-D materials called transition metal dichalcogenides and put them in ionic liquid, they get up to a 1,000-fold increase in catalytic activity,” Mishra said. “However, our goal is to understand within four years what makes certain 2-D materials such highly efficient catalysts and use this knowledge to design new 2-D materials and alloys that can lead to further improvement in catalytic activity. The eventual goal is to make them close to commercial catalysts with the hope that we won’t need platinum in cars working on fuel cells.”</p><p style="color: #000000; font-family: "times new roman"; font-size: medium;"></p><p>Mishra will rapidly screen available and hypothetical 2-D materials using quantum-mechanical electronic structure calculations run on the world’s 12th most powerful supercomputer, the Stampede2 at the Texas Advanced Computing Center, to determine which might be promising candidates. Then, Salehi-Khojin will synthesize the best candidates and measure their catalytic activity. Klie will then characterize the synthesized materials at the atomic scale using sophisticated electron microscopes. Mishra will then feed the atomic structure of the materials, their activity and their electronic structure back to the supercomputers to build a machine-learning model with the goal of accurately predicting catalysts.</p><p style="color: #000000; font-family: "times new roman"; font-size: medium;"></p><p>“We can’t synthesize and test each of the available 2-D materials and their alloys – that would take decades,” he said. “This is a closed-loop way of developing and discovering new materials using desirable properties from the atomic scale.”<br/></p><SPAN ID="__publishingReusableFragment"></SPAN><br/><br/>Rohan MishraBeth Miller2017-09-12T05:00:00ZRohan Mishra's new collaborative grant with the University of Illinois at Chicago is part of the Materials Genome Initiative launched by President Barack Obama in 2011.
https://engineering.wustl.edu/news/Pages/Measuring-with-and-against-the-grain.aspx714Measuring with and against the grain<p>​Learning more about how the brain responds to force could lead to better diagnosis and treatments for traumatic injuries. Engineers at Washington University in St. Louis are honing in on a new way to accurately assess the effects of forces during a traumatic brain injury, or TBI.<br/></p><img alt="" src="/news/PublishingImages/Phil%20Bayly%20Hong%20Chen%20WashU%20Engineering%20Brain%20Trauma.tif?RenditionID=1" style="BORDER:0px solid;" /><div id="__publishingReusableFragmentIdSection"><a href="/ReusableContent/36_.000">a</a></div><p>They’re focusing on measuring the brain’s anisotropy, or directional stiffness and strength. Much like a piece of wood, our brains have fibers which may impart extra strength along a specific direction, or grain. Researchers with the School of Engineering & Applied Science and the School of Medicine plan to use magnetic resonance imaging and focused ultrasound to better study the anisotropic behavior of brain tissue during trauma and mechanical stress.</p><p style="color: #000000; font-family: "times new roman"; font-size: medium;"></p><p>“What we eventually want to do in brain trauma prevention is develop computer simulations which can tell us how the injury occurs, what parts of the brain get injured and what preventative measures might make a difference,” said<a href="/Profiles/Pages/Philip-Bayly.aspx"> Phil Bayly, the Lilyan & E. Lisle Hughes Professor of Mechanical Engineering</a> at the School of Engineering & Applied Science. “To do that, you have to have a good mechanical model and to make that, you must have good measurements of a variety of factors, including anisotropy.”</p><p style="color: #000000; font-family: "times new roman"; font-size: medium;"></p><p>The National Science Foundation recently awarded Bayly and his collaborators a 3-year $467,000 grant to develop and validate the new measurement method.</p><p style="color: #000000; font-family: "times new roman"; font-size: medium;"></p><p>Working with <a href="/Profiles/Pages/Hong-Chen.aspx">Hong Chen, assistant professor of biomedical engineering and assistant professor of radiation oncology </a>at the School of Medicine, and <a href="https://www.mir.wustl.edu/research/research-laboratories/biomedical-magnetic-resonance-laboratory-bmrl/people/bio-garbow">Joel Garbow, professor of radiology at the School of Medicine</a>, Bayly plans to use focused ultrasound to remotely and non-invasively apply a force deep in the tissue, and then measure how the resulting acoustic waves travel. The researchers will repeat this in a variety of materials, including collagen and fibrin gels that have been magnetically aligned to mimic the anisotropy of natural tissues.</p><p style="color: #000000; font-family: "times new roman"; font-size: medium;"></p><p>“What we plan to do is use that focused ultrasound force to generate waves deep in the tissue, and then observe the effects” Bayly said. </p> <blockquote>“It’s like throwing a pebble in a pond and watching the waves move outward. In this case, the pebble is the focused ultrasound, and we’re watching how the waves move directionally.”</blockquote><p style="color: #000000; font-family: "times new roman"; font-size: medium;"></p><p>By better understanding how anisotropy influences the brain’s motion, scientists believe better computer models can be developed to predict and diagnose brain trauma. The work also lays the foundation for developing new, engineered biomaterials to replace or repair soft tissues.</p><p style="color: #000000; font-family: "times new roman"; font-size: medium;"></p><p>“We want to help modelers understand the mechanical behavior of tissue better than they do now,” said Bayly. “That’s the big picture goal.”<br/></p> <SPAN ID="__publishingReusableFragment"></SPAN> <p> <br/> </p>​ <div>​<br/>  <div><div class="cstm-section"><h3>​Collabo​rators​</h3><div style="text-align: center;"> <strong><a href="/Profiles/Pages/Philip-Bayly.aspx"><img src="/Profiles/PublishingImages/Bayly_Phil.jpg?RenditionID=3" alt="Philip Bayly" style="margin: 5px;"/></a><br/><a href="/Profiles/Pages/Philip-Bayly.aspx"><strong>Philip Bayly</strong></a><br/> </strong> </div><div style="text-align: center;"> <span style="font-size: 12px;">​​​Professor<br/>Mechanical Engineering & Materials Science</span> </div><div> <strong> <br/> </strong> </div><div style="text-align: center;"> <strong><a href="/Profiles/Pages/Hong-Chen.aspx"><img src="/Profiles/PublishingImages/Chen_Hong_7_15_06.jpg?RenditionID=3" alt="Hong Chen" style="margin: 5px; width: 120px; height: 120px;"/></a>​​</strong> </div><div style="text-align: center;"> <strong> <a href="/Profiles/Pages/Hong-Chen.aspx"> <strong>Hong Chen</strong></a></strong> </div><div style="text-align: center;"> <span style="font-size: 12px;">Assistant Professor</span></div><div style="text-align: center;"> <span style="font-size: 12px;">Biomedical Engineering</span><span style="font-size: 1em; line-height: 1.3;">​​​​</span></div><div style="text-align: center;"> <span style="font-size: 1em; line-height: 1.3;"> <br/></span></div><div style="text-align: center;"><div style="color: #343434; text-align: center;"> <strong> <a href="https://www.mir.wustl.edu/research/research-laboratories/biomedical-magnetic-resonance-laboratory-bmrl/people/bio-garbow"> <img src="/news/PublishingImages/Joel%20Garbow.jpg?RenditionID=3" alt="Hong Chen" style="margin: 5px;"/></a>​​</strong></div><div style="color: #343434; text-align: center;"> <strong> <a href="https://www.mir.wustl.edu/research/research-laboratories/biomedical-magnetic-resonance-laboratory-bmrl/people/bio-garbow"> <strong>Joel Garbow</strong></a></strong></div><div style="color: #343434; text-align: center;"><span style="font-size: 12px;">Professor of Radiology</span><span style="font-size: 1em; line-height: 1.3;">​​​​</span><br/></div> <span style="font-size: 1em; line-height: 1.3;"> <br/></span></div></div>  ​<br/></div></div> At left is a standard MRI image of the brain anatomy. The middle image shows a color-coded image of fiber direction in the brain, and at right is an MRI image of shear waves in the brain, induced to prove the properties of brain tissue. (Ruth Okamoto)Erika Ebsworth-Goold 2017-09-11T05:00:00ZEngineers at Washington University in St. Louis are honing in on a new way to accurately assess the effects of forces during a traumatic brain injury, or TBI.<p>​Engineers developing new way to analyze brain behavior during trauma<br/></p>

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