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• Oct

  27

  ME512 Seminar: Oluwaseyi Balogun

  McCormick - Mechanical Engineering (ME)

  3:00 PM LR3, Technological Institute

  EVENT DETAILS

  Monday, October 27, 2025
  3:00 PM LR3

  Zoom Link: https://northwestern.zoom.us/j/99215996751

  ABSTRACT
  My research group explores high-resolution optical techniques to investigate elastic wave and heat transport phenomena in condensed matter. In the first half of my talk, I will describe our work on thermal conductivity imaging near single grain boundaries (GBs) in thermoelectric materials. GBs are critical microstructural components that control the performance of thermoelectric materials by reducing the bulk thermal conductivity through the scattering of lattice waves. To date, most GB-thermal conductivity studies have primarily focused on grain size as a fundamental structural property that is important for reducing thermal conductivity. However, it is unclear if the right strategy for optimizing the thermoelectric performance is suppressing the thermal conductivity using small (or nanosized) grains or proliferating thermally resistive GBs. Addressing this fundamental question will be critical to developing next-generation thermoelectric generators for deep space exploration and commercial solid-state refrigerators for mobile phone and electric vehicle applications. In our work, we examine the impact of the GB morphology (e.g., misorientation angle, roughness of the GB plane, nanotwinning, porosity, etc.) on the local thermal conductivity suppression near individual GBs. Our measurements show that the “all GBs are the same” picture adopted in thermal conductivity homogenization modeling is not accurate. Alternatively, each GB is best described as a unique complexion that differs from the surrounding bulk phase. The GB complexion may be controlled by adjusting the thermodynamic parameters of processing methods, leading to complexion transitions similar to those in bulk materials, which can result in drastic changes in bulk transport properties and enhance thermoelectric performance. In the last half of my talk, I will present a dynamic optical coherence elastography (OCE) technique that relies on optical measurement of bulk shear wave propagation for the characterization and mapping of shear viscoelastic properties. My group has adapted the method for viscoelastic characterization of wastewater biofilm membranes and beads. These materials are heterogeneous and may be layered, leading to guided or interfacial elastic waves. I will discuss how we harnessed these wave modes to probe spatial variations in viscoelastic properties, track changes in pH and crosslinking time, and address the influence of stretch-dependent properties.

  BIO
  Oluwaseyi Balogun is an Associate Professor of Mechanical Engineering and Civil and Environmental Engineering at Northwestern University. He received the B.S. degree from the University of Lagos, Nigeria, and the M.S. and Ph.D. degrees from Boston University, all in Mechanical Engineering. Dr. Balogun’s research focuses on micro- and nanoscale heat transport, elastic wave phenomena, and high-resolution optical and scanning probe microscopy. His research is relevant to applications that involve heat conduction in condensed matter, material characterization based on optical and elastic wave measurements, and high-frequency nanoacoustic devices. He currently serves as the co-director for the Center for Smart Structures and Materials at Northwestern University. He is a member of the IEEE UFFC and IEEE Nanotechnology Societies and a recipient of the 2020 & 2021 IEEE Nanotechnology Council Distinguished Lecturer awards.

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  TIME Monday, October 27, 2025 at 3:00 PM - 4:00 PM

  LOCATION LR3, Technological Institute    map it

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  CONTACT Jeremy Wells    jeremywells@northwestern.edu EMAIL

  CALENDAR McCormick - Mechanical Engineering (ME)

• Jan

  12

  From Clocks to Clouds: How Scientific Revolutions Reshaped Reality and Our Place Within It

  McCormick - Mechanical Engineering (ME)

  3:00 PM LR3, Technological Institute

  EVENT DETAILS

  Abstract:

  For three centuries, Western thought lived under Newton’s clockwork paradigm—a
  worldview of predictability, control, and linear causation. It shaped institutions from
  Madison’s checks and balances to Taylor’s scientific management, defining modernity.
  But successive scientific revolutions—statistical thermodynamics, relativity, quantum
  mechanics, evolution, game theory, DNA, and AI—revealed a radically different
  universe: dynamic, probabilistic, and deeply complex. We have shifted from Newton’s
  clocks to what Popper called a “cloud world,” marked by emergence, interdependence,
  and irreducible uncertainty.

  This talk traces how these revolutions reshaped our understanding of reality and
  explores their leadership implications: why navigating 21st-century challenges demands
  embracing complexity, cultivating resilience, and designing organizations that work with,
  rather than against, dynamic systems.

  Bio:

  Julio Mario Ottino is a researcher, engineering scientist, academic leader, educator, artist, and author. He is Founder and Co-Director of the Northwestern Institute on Complex Systems, McCormick Institute Professor of Engineering, W.P. Murphy Professor of Chemical Engineering, with a courtesy appointment in Mechanical Engineering at the McCormick School of Engineering, and Professor of Management and Organizations at Northwestern at the Kellogg School of Management in Northwestern University. Widely recognized as a world authority on mixing, chaos, and complexity, he has been a Guggenheim Fellow and is a member of the National Academy of Engineering, the National Academy of Sciences, and the American Academy of Arts and Sciences. As Dean of Engineering, he launched major university-wide initiatives, programs, degrees, and centers spanning design, energy and sustainability, synthetic biology, human–computer interaction, and entrepreneurship. His most recent book, The Nexus (MIT Press, 2022) was a category winner in Engineering and Technology, from the Association of American Publishers

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  TIME Monday, January 12, 2026 at 3:00 PM - 4:00 PM

  LOCATION LR3, Technological Institute    map it

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  CONTACT Jeremy Wells    jeremywells@northwestern.edu EMAIL

  CALENDAR McCormick - Mechanical Engineering (ME)

• Feb

  2

  ME512 Seminar Series- Anthony Rollett

  McCormick - Mechanical Engineering (ME)

  3:00 PM LR3, Technological Institute

  EVENT DETAILS

  Abstract:

  We provide an overview of a recent NASA University Leadership Initiative project entitled “Development of an Ecosystem for Qualification of Additive Manufacturing Processes and Materials in Aviation”. This work demonstrated the dependence of fatigue on defect structures in AM Ti-6Al-4V. Our current NASA Science & Technology Research Institute “Institute for Model-Based Qualification & Certification of Additive Manufacturing (IMQCAM)” is creating a numerical digital twin (DT) for predicting fatigue as a function of process parameters. The key result of a systematic variation across power-velocity space was that the defect number density was anti-correlated with fatigue life. The fatigue-based process window was much narrower compared to typical reports and explainable in terms of observed variations based on spatter rates and intermittent lack of melt pool overlap. We report on recent developments in modeling microstructure, texture and pores along with variations in heat treatment. We conclude that establishing a qualified materials process is feasible via an efficient survey of a limited domain of process space. Linking models together in the DT requires substantial effort in terms of data exchange. In terms of predictability of fatigue, the limited data suggests that the scatter in life is smallest in the long crack (Paris Law) regime, intermediate for short cracks and largest for crack nucleation. This provides an important background for Uncertainty Quantification (UQ), which is a major focus for the IMQCAM team and which has already revealed a significant sensitivity to compositional variations, for example.

  Support from multiple agencies is gratefully acknowledged, including NASA, DOE/BES, DOE/NNSA, ONR, NSF, OEA, Commonwealth of Pennsylvania, and Ametek. I am indebted to my many collaborators.

  Bio:

  I have been a member of the faculty at Carnegie Mellon University since 1995. I am also the Co-Director of the NextManufacturing Center on additive manufacturing. Previously, I worked for the University of California at the Los Alamos National Laboratory. I spent nine years in management with four years as a Group Leader (and then Deputy Division Director) at Los Alamos, followed by five years as Department Head at CMU (up to 2000). I have been a Fellow of ASM since 1996, Fellow of the Institute of Physics (UK) since 2004 and Fellow of TMS since 2011. I received the Cyril Stanley Smith Award from TMS in 2014, was elected as Member of Honor by the French Metallurgical Society in 2015 and then became the US Steel Professor of Metallurgical Engineering and Materials Science in 2017. I received Cyril Stanley Smith Award from the International Conference on Recrystallization and Grain Growth in 2019 and the Hans Bunge Award from the Intl. Conf. on Textures of Materials (ICOTOM) in 2024. I was an International Francqui Professor (Belgium) in 2022 and I received the ASM Gold Medal and was promoted to University Professor, both in 2024. My research focuses on processing-microstructure-properties relationships with interests in additive manufacturing, the measurement and prediction of microstructural evolution, the relationship between microstructure and properties, especially three-dimensional effects, texture & anisotropy and the use of synchrotron x-rays.

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  TIME Monday, February 2, 2026 at 3:00 PM - 4:00 PM

  LOCATION LR3, Technological Institute    map it

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  CONTACT Jeremy Wells    jeremywells@northwestern.edu EMAIL

  CALENDAR McCormick - Mechanical Engineering (ME)