The projects fall under four major categories: nanomaterials, earth-space interactions, medical physics and advanced computing. The teams will spend the next three years developing their projects, which could transform industries like automotive, space, health care and data science.<\/p>\n \u201cRanging from electromagnetic interference shielding nanomaterials, to in-beam time-of-flight positron emission tomography for proton radiation therapy, all the way to an ocean and climate change monitoring constellation based on radar altimeter data combined with gravity and ocean temperature and salinity measurements, the spread, number, and quality of the UT Austin Portugal joint strategic projects selected for funding within the recent competitive solicitation set forth by the Foundation for Science and Technology and National Innovation Agency are truly outstanding,\u201d said Manuel Heitor, Portugal\u2019s Minister of Science, Technology and Higher Education. \u201cI look forward to witnessing the results of such collaborative research between Portuguese and UT researchers.\u201d<\/p>\n The call for proposals included just three universities: The University of Texas at Austin, Carnegie Mellon University and the Massachusetts Institute of Technology. UT won the majority of the investment dollars, about 40% of the funding, and saw the most projects funded among the three engineering powerhouses.<\/p>\n \u201cWe had anticipated four to five projects would be selected for strategic grant awards and were astounded when we learned 11\u00a0had been selected by the evaluation panel in Portugal,\u201d said John Ekerdt, Cockrell School associate dean for research and principal investigator for UT Austin Portugal. \u201cThis is a testament to the outstanding faculty\u00a0and\u00a0quality projects they proposed with collaborators in Portugal and to the close ties that have been forged between UT researchers and faculty and counterparts in Portugal.\u201d<\/p>\n \u201cThe performance of the UT Austin Portugal program in the 2019 call for strategic projects has been remarkable,\u201d said Marco Bravo, executive director of the UT Austin Portugal program. \u201cEleven of 14 project proposals submitted by the UT Austin Portugal research consortia were approved for funding through an independent assessment process.\u00a0Overall, UT Austin Portugal saw 11 of its groundbreaking, industry-led proposals approved out of a total of 25 projects approved at this solicitation that included proposals from two other international partnerships, corresponding to nearly $24 million over three years. That\u2019s 40% of total funding to UT Austin Portugal projects, the largest share of research dollars available. UT Austin researchers are to be congratulated on this effort.\u201d<\/p>\n The UT Austin Portugal program dates back to 2007, and it is one of several partnerships between the Portuguese government and research institutions. The goal is to elevate science and technology in Portugal while fostering strong partnerships to help universities continue to innovate. The partnership with UT was extended in 2018, continuing the alliance until at least 2030.<\/p>\n \u201cOf the three international partnerships with American universities sponsored by the Portuguese Foundation for Science and Technology in Portugal, the partnership with UT Austin had the best performance in this call, which was designed and launched on the Portuguese side,\u201d said Jos\u00e9 Manuel Mendon\u00e7a, national director of the program. \u201cThe 11 approved projects represent a proposal success rate of almost 80% for the UT Austin Portugal Program. The approved projects will, undoubtedly, contribute to promoting and strengthening collaborations with UT Austin in high-level R&D matters with immediate transposition to various sectors of economic activity, several of which are critical to Portugal’s competitive position at an international level.\u201d<\/p>\n About a third of the funds for UT\u2019s projects come from the university, with the rest coming from a combination of public and private Portuguese entities. Each project team in Portugal is led by a Portuguese company. The UT side includes 21 faculty members and one from the MD Anderson Cancer Center.<\/p>\n Here is a look at the UT projects:<\/p>\n This project proposes to use the\u00a0\u201cwonder material\u201d<\/a>\u00a0graphene to improve on methods to combat electromagnetic interference, which can disrupt circuits and cause devices to fail. The team plans to create two composites with electromagnetic interference shielding capabilities and fabricate a solution to protect electric wires used in the automotive industry.<\/p>\n UT Austin Faculty:<\/strong>\u00a0Deji Akinwande, Cockrell School of Engineering, Department of Electrical and Computer Engineering; Brian Korgel, Cockrell School of Engineering, McKetta Department of Chemical Engineering<\/p>\n The use of\u00a0multiphoton microscopy<\/a>\u00a0to examine cell behavior in live tissue over time has become an important research tool for learning more about brains and tumors. This project aims to increase the speed and depth of this form of imaging and diagnostics through the development and application of ultrashort laser pulses.<\/p>\n UT Austin Faculty:<\/strong>\u00a0Andrew Dunn, Cockrell School of Engineering, Department of Biomedical Engineering; Adela Ben-Yakar, Cockrell School of Engineering, Walker Department of Mechanical Engineering<\/p>\n Researchers propose to develop a nano-satellite prototype for studying gravitational fields. The project will also develop a platform for future nano-satellite capabilities, including Earth observation, communications and exploration missions.<\/p>\n UT Austin Faculty:<\/strong>\u00a0Byron Tapley, Cockrell School of Engineering, Department of Aerospace Engineering and Engineering Mechanics, and the Center for Space Research; Brandon Jones, Cockrell School of Engineering, Department of Aerospace Engineering and Engineering Mechanics, and the Texas Spacecraft Laboratory<\/p>\n The advancement of technology has generated huge troves of data, which requires stronger computing power to process and analyze all that information. This project aims to create a software bundle to help companies pair their big data operations with\u00a0high-performance computing<\/a>, which includes tools for managing challenges such as computing and research storage.<\/p>\n UT Austin Faculty:<\/strong>\u00a0Vijay Chidambaram, College of Nature Sciences, Department of Computer Science; Todd Evans, Texas Advanced Computing Center<\/p>\n This project will develop a biosensor that can be injected into prostate cancer patients after surgery. The minimally invasive sensor would allow medical personnel to monitor high-risk patients remotely and look for the development of early tumors, with the potential to increase the predictive value of cancer screenings.<\/p>\n UT Austin Faculty:<\/strong>\u00a0Thomas Milner, Cockrell School of Engineering, Department of Biomedical Engineering; James Tunnell, Cockrell School of Engineering, Department of Biomedical Engineering<\/p>\n Researchers will develop a series of nano-sensors embedded into clothing that administer electrostimulation to people suffering from a lack of mobility and motor deficiency. The sensors could be monitored remotely by health professionals, creating a mobile rehabilitation option for people who have trouble getting to a doctor\u2019s office consistently or want greater freedom to complete treatment anywhere. The team envisions its project as a tool mostly for elderly people, but it has applications for training high-level athletes as well.<\/p>\n UT Austin Faculty:<\/strong>\u00a0George Biros, Cockrell School of Engineering, Walker Department of Mechanical Engineering, and the Oden Institute for Computational Engineering and Sciences; Michael Cullinan, Cockrell School of Engineering, Walker Department of Mechanical Engineering<\/p>\n Getting reliable data on manufacturing processes proves challenging due to issues with placing sensors in the right spots and retaining strong connectivity. Thin films loaded with small sensors that can be applied directly to the equipment represent a promising solution; however, installation has proved difficult. This project proposes a new set of software to make it easier to layer these films on top of equipment by providing necessary data to avoid mechanical problems during installation.<\/p>\n UT Austin Faculty:<\/strong>\u00a0Rui Huang, Cockrell School of Engineering, Department of Aerospace Engineering and Engineering Mechanics, Center for Mechanics of Solids, Structures and Materials; Kenneth M. Liechti, Cockrell School of Engineering, Department of Aerospace Engineering and Engineering Mechanics, Center for Mechanics of Solids, Structures and Materials<\/p>\n Proton radiation therapy<\/a>, the use of protons rather than X-rays to treat cancer patients, is on the rise, but measuring the distance protons travel proves problematic. Typically, it takes a ring of detectors surrounding the patient to get accurate measurements, but that poses geometric challenges. This project proposes to develop a new type of\u00a0Positron Emission Tomography<\/a>\u00a0scan, which shows how tissues and organs are functioning to better understand the range of protons and whether they are traveling to the right spots to attack the cancer.<\/p>\n UT Faculty:<\/strong>\u00a0Karol Lang, College of Natural Sciences, Department of Physics; Narayan Sahoo, University of Texas MD Anderson Cancer Center, Department of Radiation Physics<\/p>\n This project aims to develop the next generation of radar altimeter instruments \u2014 which measure the distance between an aircraft and the terrain below it \u2014 and a series of small satellites that can understand long-term variability in local, regional and global climate created by changes in sea levels due to water temperature. The project also includes a data processing and visualization system using advanced modeling, estimation techniques, statistical and scientific machine learning methods and error analysis.<\/p>\n UT Austin Faculty<\/strong>: Byron Tapley, Cockrell School of Engineering, Department of Aerospace Engineering and Engineering Mechanics Department, and the Center for Space Research; Patrick Heimbach, Jackson School of Geosciences, Department of Geological Sciences, and the Oden Institute for Computational Engineering and Sciences<\/p>\n Fabricating parts of cars and planes is hard on cutting tools and tends to ware them down. This project aims to develop coatings that better protect and extend the lifespan of these crucial pieces of equipment. The team also plans to develop simulation programs to improve cutting tools\u2019 performance.<\/p>\n UT Austin Faculty:\u00a0<\/strong>Gregory J. Rodin, Cockrell School of Engineering, Department of Aerospace Engineering and Engineering Mechanics, and the Oden Institute for Computational Engineering and Sciences; Filippo Mangolini, Cockrell School of Engineering, Walker Department of Mechanical Engineering<\/p>\n Traditional water treatment tech struggles to efficiently remove high amounts of pollutants from some types of surface and groundwater. This team is looking to use metallic nanoparticles to clean water by improving a process called catalytic hydrogenation, which involves adding hydrogen via a metallic catalyst.<\/p>\n UT Austin Faculty:<\/strong>\u00a0Charles J. Werth, Cockrell School of Engineering, Department of Civil, Architectural, and Environmental Engineering; Simon M. Humphrey, College of Natural Sciences, Department of Chemistry<\/p>\n![\"\"](\"https:\/\/www.csr.utexas.edu\/wordpress\/wp-content\/uploads\/2020\/06\/ut-portugal-projects-300x225.jpg\")
<\/a>Shielding electronic devices from electromagnetic interference<\/strong><\/h4>\n
New lasers for next-generation biomedical imaging<\/strong><\/h4>\n
Nano-satellites for gravitational field assessment<\/strong><\/h4>\n
Software to match big data with high-performance computing<\/strong><\/h4>\n
Sensors for monitoring cancer patients<\/strong><\/h4>\n
Wearable rehabilitation devices<\/strong><\/h4>\n
Software for gathering better data on manufacturing<\/strong><\/h4>\n
A new way to measure next-generation cancer therapy<\/strong><\/h4>\n
Satellite constellations for monitoring climate change<\/strong><\/h4>\n
Improving cutting tools for airline and automotive components<\/strong><\/h4>\n
An alternative to traditional water treatment options<\/strong><\/h4>\n