Yang Zhang

Yang Zhang
Yang Zhang

Yang Zhang

Assistant Professor
Materials Science and Engineering
  • Nuclear, Plasma, and Raiological Engineering
111A Talbot Laboratory MC 234
104 S. Wright Street
Urbana Illinois 61801
(217) 300-0452

Academic and Scientific Experience

Education

  • Ph.D., Nuclear Science and Engineering, Massachusetts Institute of Technology (MIT), 2010
  • B.S., Electrical Science and Technology, University of Science and Technology of China (USTC), 2004

Academic Positions

  • 2012 - present, Assistant Professor, Department of Nuclear, Plasma, and Radiological Engineering (100%), Department of Materials Science and Engineering (0%), Program of Computational Science and Engineering (0%), Center for Biophysics and Quantitative Biology (0%); Core Faculty Member (0%) and Group Leader, Computational Molecular Science Group, Beckman Institute for Advanced Science and Technology
  • 2010 - 2012, Clifford G. Shull Fellow, Oak Ridge National Laboratory.

Courses Taught

  • NPRE 446 - Radiation Interact w/Matter I
  • NPRE 447 - Radiation Interact w/Matter II
  • NPRE 498 - Multiple Events&Comp Methods
  • NPRE 498 - Multiple Events&Compu Methods
  • NPRE 521 - Interact of Radiation w/Matter
  • NPRE 529 - Interact of Rad w/Matter II
  • NPRE 595 - Student Research Seminar
  • NPRE 598 - Interact Radiation w/Matter II

Journal Editorships

  • Associate Editor, Science and Technology of Advanced Materials, 2016 – present
  • Associate Editor, Frontiers in Materials, Glass Science section, owned by Springer Nature, 2015 – present
  • Associate Editor, Frontiers in Physics, and Frontiers in Chemistry, Physical Chemistry and Chemical Physics section, owned by Springer Nature, 2015 – present
  • Guest Editor, MRS Advances, Theory, Characterization, and Modeling section, Fall 2015

Research Statement

The understanding of collective phenomena is one of the major intellectual challenges in many research fields. Conventional statistical methods have been successfully applied to describe systems at or near equilibrium, but they often fail to provide accurate predictions for systems and processes away from equilibrium, where time reversal symmetry and ergodicity are readily broken. Yet, patterns of amazing complexity spanning an immense range of hierarchical spatial and temporal scales – ubiquitous in the world around us – are formed from non-equilibrium conditions, such as turbulent flow, structure of the universe, social activities, and life itself. Research on such systems and processes may help identify the rule of randomness and recognize the role of correlated degrees of freedom in the organization and transport of energy and matter. Such quest for universality is motivated by a hope of identifying emergent principles governing non-equilibrium systems.

His research focuses on the study of extreme/non-equilibrium properties of matter using synergistically integrated theory-driven atomistic simulations and neutron and X-ray experiments, which can be roughly divided into two areas: 1) extreme/non-equilibrium properties of liquids; 2) glassy, jammed, and kinetically trapped soft matter. The goal is to understand long timescale phenomena and rare events in matter and engineer them into transformative applications. 

To date, how to characterize and control matter away from equilibrium remains a grand challenge. From the fundamental science perspective, research on non-equilibrium matter may shed light on a class of scientific problems involving phenomena emerging from self-organization, symmetry breaking, and rare events, such as viscous flow of supercooled liquids and glasses, nucleation and crystal growth, folding of polypeptide chains into structured proteins, and self-assembly of micro-units into functional objects. From the application perspective, research on non-equilibrium matter may yield transformative knowledge that directly influence countless pivotal applications, such as understanding and preventing the aging and degradation of materials, bio-preservation by kinetically blocking the transition pathways, design and manufacture of novel amorphous materials with otherwise unattainable properties, and control of non-equilibrium processing techniques, as part of an overarching mission of fostering secure and reliable energy infrastructures that are environmentally and economically sustainable.

Research Interests

  • Extreme/non-equilibrium properties of liquids
  • Glassy, jammed, and kinetically trapped soft matter
  • Self-healing soft robotics
  • Long timescale phenomena and rare events
  • Theory-driven atomistic simulations
  • Neutron and X-ray experiments

Selected Articles in Journals

Honors

  • Landis Young Member Engineering Achievement Award, American Nuclear Society, , “in recognition of his contributions to nuclear and advanced experimental techniques to understand the complex makeup, nature and performance of materials in the far-from-equilibrium state” (2017)
  • Doctoral New Investigator Award, American Chemical Society Petroleum Research Fund (2015)
  • Collins Fellow, UIUC (2013)
  • List of Teachers Ranked as Excellent (Fall 2013, Fall 2014, Spring 2015, Spring 2017) (2013-2015)
  • Clifford G. Shull Fellowship, ORNL (2010)
  • Manson Benedict Award, MIT (2008)
  • Neutron Scattering Society of America Prize (2008)