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TMI's core faculty lead cutting-edge research by running their grants through the institute, fostering collaboration and resource sharing.
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Our Materials Science and Engineering program is one of the best in the nation, and our graduates go on to be leaders in their fields.
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Research
TMI supports interdisciplinary research at UT Austin, with over 100 faculty focusing on clean energy, nanotechnology, and advanced materials using our state-of-the-art facilities.
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Jean Anne Incorvia named 2023 APL Rising Star
Applied Physics Letters has introduced the APL Rising Stars Collection and APL Rising Star Award to spotlight early career principal investigators making strides in applied physics. Dr. Jean Anne Incorvia has been unveiled as the first recipient, recognizing her impactful contributions to the field.
Delia Milliron receives 2023 NSEF Forum Award
In recognition for her outstanding contributions to the advancement of nanoscale science and engineering in the field of chemical engineering, Delia Milliron has received the Nanoscale Science and Engineering 2023 NSEF Forum Award.
Clarivate Highly Cited Researchers 2023
Congratulations to the 10 faculty affiliated with the Texas Materials Institute that were acknowledge by Clarivate as Highly Cited Researchers for 2023.
Delia Milliron receives 2023 Materials Research Society (MRS) Medal Award
Delia Milliron, the Ernest Cockrell, Sr. Chair #1 in engineering and department chair in chemical engineering, has received the Materials Research Society’s 2023 MRS Medal, which recognizes an exceptional achievement in materials research, or a specific outstanding recent discovery or advancement, that is expected to have a major impact on the progress of a materials‐related field.
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Texas Materials Seminar Series
The Texas Materials Seminar Series features MSE 397 Seminars, TMI Distinguished Lectureships, and TMI Special Seminars, where leading faculty and professionals from around the world share cutting-edge innovations and advancements in materials engineering with our students.
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News
Dr. Deji Akinwande's Group Publishes in ACS Nano
Dr. Deji Akinwande’s research group has just published new research in ACS Nano. The team developed a novel method using UV-Ozone to create precisely engineered defects in graphene membranes. This breakthrough solves a major challenge in ultrathin hydrogen fuel cell membranes, improving their performance without affecting the material’s strength or stability.
A Path to Safer, High-Energy Electric Vehicle Batteries
Nickel’s role in the future of electric vehicle batteries is clear: It’s more abundant and easier to obtain than widely used cobalt, and its higher energy density means longer driving distances between charges.
Graphene Double Moiré System Revolutionizes Quantum Materials Research
An international research team, led by scientists from The University of Texas at Austin, has unveiled a groundbreaking double moiré system made of four graphene layers. In this innovative structure, the top and bottom pairs form small-twist-angle bilayer graphene, while the middle interface is characterized by a large rotational mismatch. Fabricated using opto-thermoplasmonic nanolithography, this system introduces a new platform for exploring independently tunable flat bands in twisted bilayer graphene (TBG) structures.
Dr. Deji Akinwande Publishes in Nature Electronics
Dr. Deji Akinwande, Professor at The University of Texas at Austin, has made a notable contribution to the field of semiconductor physics with his latest publication, “The quantum limits of contact resistance and ballistic transport in 2D transistors” in Nature Electronics.
Fast-charging Lithium-ion Batteries: Advanced 3D Analysis of Electrode-electrolyte Interfaces with Secondary Ion Mass Spectrometry
Chen Liu, Andrei Dolocan, Zehao Cui, and Arumugam Manthiram have made significant progress in improving the fast-charging capabilities of lithium-ion batteries (LIBs), which are crucial for devices like smartphones and electric vehicles. Their work, published in The Journal of the American Chemical Society, focuses on how the chemistry of the interface between the battery electrodes and electrolyte can be optimized to make charging faster and more efficient.
$12M+
In Grant Funding
20+
Research Patents
10K+
