Erick HernandezMassachusetts Institute of Technology, Materials Science and Engineering, B.S.
University of Illinois at Urbana-Champaign, Materials Science and Engineering, Ph.D. candidate
Quantum dots are a type of light-emitting nanocrystalline semiconductors with applications in consumer electronics and in biological imaging. Today's best performing quantum dots are toxic when they degrade, preventing their widespread use. In order to design better, safer quantum dots we need to understand how the nanocrystal's composition, shape, size, and internal structure affect its optical properties. The overarching goal of my research is to use experimental and computational techniques to explore the structure-function relationship between these characteristics and the optical properties of nanocrystals.
Jiaxing QuUniversity of Illinois at Urbana-Champaign, Mechanical Engineering, PhD, 2018-current
Shanghai Jiao Tong University, Mechanics, M.S., 2016-2018
Hohai University, Mechanics, B.S., 2012-2016
Jiaxing's research interest focuses on computational discovery for novel thermoelectric materials.
Josh VitaUniversity of Arizona, Materials Science and Engineering, Mathematics, B.S., 2017
Originally from Tucson, Josh did his undergraduate degree at the University of Arizona, receiving bachelor's degrees in both materials science and mathematics. Since joining Illinois in 2017 as a member of Dallas Trinkle's group, Josh's research has focused on developing efficient and scalable software for building inter-atomic potentials for molecular dynamics. Josh says, ultimately, the purpose of his research is to leverage modern computational resources and materials databases to help lower the barrier to entry for new studies in computational materials science.
Mengchen WangUniversity of Science and Technology of China, Statistics, B.S., 2018
Mengchen's research interests focuses on spatio-temporal modeling and functional data analysis.
Xiaoyang WangNorthwestern University, Computer Science, M.S., 2017 Central South University (China), Automation, B.E., 2016
Xiaoyang is a Ph.D. student in Computer Science. He is currently working on causal reasoning. More specifically, he is developing algorithms to diagnose failures in material science experiments.
Ferdaushi Alam BipashaBangladesh University of Engineering and Technology, Mechanical Engineering, B.S., 2016
Bipasha completed her Bachelors in Mechanical engineering from BUET in 2016 and after that worked in industries for three years. In Fall 2019, Bipasha joined MechSE at Illinois to pursue her PhD in Mechanical Engineering. She is currently working in Dr. Ertekin's research group and working on computational study of thermoelectric materials.
Sharon EdwardUniversity of Kentucky, Mechanical Engineering, B.S., 2019
Sharon's current research interests are in fluid mechanics, molecular dynamics and dynamical systems. Her research focuses on the study of hyperthermal collisions of atomic oxygen with graphene using molecular dynamics based programs like LAMMPS.
Robert Charles GarrettMiami University, Mathematics & Statistics, B.S., 2019
Robert graduated with a B.S. in Mathematics & Statistics from Miami University in 2019. Recently, he has recently finished his first year in the Statistics PhD Program at Illinois. As part of DIGI-MAT, Robert will be working with Dr. Bo Li to develop a new method for functional kriging, which would allow for better predictions of curves and surfaces across spatial regions.
Jeffrey HuangCornell University, Engineering Physics, B.S., 2019
(Scanning) transmission electron microscopy can be used to study the structure of materials at the atomic scale. Jeffrey is using machine learning to process TEM diffraction data and atomic resolution STEM images, especially in application to metallic antiferromagnetic materials.
Kevin Gordon KleinerUniversity of Tennessee Knoxville, Physics, B.S., 2019
Summa Cum Laude
Chancellor's Honors Program
Kevin says modern technologies including quantum computers, transistors, and solar cells rely on semiconductor materials. Thanks to implanting small defects into the atomic pattern, semiconductors can host useful, controllable behaviors such as electrical conductivity, light sensing, and long-lived quantum information. These behaviors originate from the interplay of the electrons and atomic nuclei, but the precise role of defects in realistic systems is still under debate. Aided by first principles physics simulations and data science techniques, I will build simplified quantum models for the crystal vibrations and electronic structures in various semiconductors. These models link a system's atomic pattern to accurate descriptions of its behaviors, which can guide materials engineers when tuning semiconductors for relevant technologies.
Zachary RiedelClemson University, Materials Science and Engineering, B.S., 2019
minors: mathematics, chemistry
Zach is a PhD student in Materials Science and Engineering, working in Dr. Daniel P. Shoemaker's group on two materials chemistry focused projects. The first involves isolating a novel Ni-V-O phase in order to solve its structure and probe its electronic and magnetic properties. His DIGI-MAT involvement stems from his second project. This project seeks to utilize the advantageous properties of rare earth materials for quantum information storage. Quantum information and computing can offer benefits ranging from massively increased computational capacity to enhanced cryptographic security. By cataloging previously discovered, environmentally stable candidates and by predicting undiscovered materials, Zach hopes to expand the materials options for the emerging quantum information field. Zach says, "I am excited about the (DIGI-MAT) program and look forward to learning about the intersection of materials and data science."
Aagam ShahIIT-Gandhinagar, Materials Science and Engineering, B.S., 2019
Aagam received his Bachelor's in Materials Science and Engineering from the Indian Institute of Technology Gandhinagar, where he worked on biotemplating to synthesise inverse gyroid photonic crystals. He joined the Master's program in the same discipline at Illinois in Fall 2019. Here, he works with Prof. Sameh Tawfick and Prof. Elif Ertekin on the Gr-ResQ tool. This is a nanoHUB tool designed to be a one-stop solution for analysis of graphene synthesis by chemical vapor deposition, which acts as a database for recipes and provides tools for users to quantitatively analyse microscopy images and Raman spectra. Aagam studies the synthesis of graphene by chemical vapor deposition and works on the tool analyzing Raman spectra.
Micah ArmstrongUniversity of Alabama at Birmingham, Materials Engineering, B.S., 2020
As a part of Dr. Nicola Perry's research group Micah is working on the development of high-throughput methods for the analysis of combinatorial thin films. These films can be used to analyze the transport properties and defect chemistries of ionic materials, such as those used in emerging energy conversion and storage technologies. The goal of this project is to develop efficient methods for analyzing the electrochemical properties of broad ranges of oxide compositions at a wide range of thermal and atmospheric conditions, using advanced data science methods to receive and analyze the large, complex data sets produced in the process.
Rees ChangCornell University, Materials Science and Engineering, B.S., 2020
Rees is a PhD student in materials science and engineering. He is broadly interested in advancing and applying methods at the intersection of computational materials science and machine learning to accelerate materials design.
Austin Ellis-MohrCornell University, Electrical & Computer Engineering, B.S., 2020
As the size and depth of neural networks utilized continues to increase, a critical bottleneck is the data communication between off-chip memory and the on-chip caches. non-von Neumann architectures in which memory and processing coexist in some form. Austin's work is focused on advancing machine learning hardware by creating new architectures designed specially for neural networks using standard CMOS technology and by developing new types of in-memory and neuromorphic computing devices.
Ben JaspersonUniversity of Wisconsin-Madison, Mechanical Engineering, M.S.
University of Wisconsin-Madison, Mechanical Engineering, B.S.
Ben received his B.S. and M.S. in mechanical engineering from the University of Wisconsin-Madison. His current research topic involves using machine learning to identify 2D materials with desired non-linear optical properties.
Sonali JoshiUniversity of Central Florida, Physics, B.S., 2020 (with honors)
Sonali is a Ph.D. student in Physics at UIUC. She is interested in the development and use of computational techniques in physics that can be used towards finding potential new and existing materials for future technologies. An important part of realizing new materials if determining their thermodynamic stability, which requires exploring their formation energy. Currently she is introducing herself to various first principles techniques to calculate the formation energy of various systems. The hope for these new materials is that they could be valuable in catalytic reactions, energy storage, and many other areas.
Cindy Ying WongArizona State University, Materials Science and Engineering, B.S., 2020
The current paradigm in materials research which focuses on trial-and-error can be costly. Cindy's current research focuses on using machine learning to understand the structure-property relation of complex materials for inverse materials design. By using data-driven methods in materials design and discovery, we can overcome challenges in experimental and computational work that rely on human intuition.