Seminar - Combinatorial Nano-Biomaterials with Intelligent Polymer Automation

Thursday, October 1, 2020; 12:05 p.m. to 1:20 p.m.
Via Zoom
Speaker: Dr. Adam Gormley from Rutgers University

Dr. Adam Gormley
Assistant Professor of Biomedical Engineering
Rutgers University

Seminar via Zoom, please email acv5167@psu.edu for link and password.

Abstract/Bio

Hosted by: Jamie Oberdick,  jco11@psu.edu

EE Colloquium: The Fourth Generation Optics: The Concept, Materials, Technology, and Applications

Friday, October 2, 2020; 1:25 p.m.
Zoom
Speaker: Nelson Tabiryan from BEAM Corporation

Abstract: The Seminar provides an intuitive introduction into the underlying principles of the new generation of optical components and systems, requiring only basic knowledge (or just an interest) in optics. The course will make it evident for attendees that:

- a micrometer-thin film may perform as a high power lens, prism, spiral phase plate, beam shaper, etc., and in a broadband of wavelengths comparable to that of glass and other transparent optical materials;

- optical functions can be switched on and off with low voltage controls;

- thin film optical components can be combined to provide versatile beam control functions such as all-electronic beam steering, switching between multiple focal points, spectral tuning, variable transmission, etc.

- an ultralight and ultrathin film may be used as primary optics for a very large telescope, both for deep space communication as well as imaging.

The first generation of optics relied on shaping an optically transparent material such as glass. Modulating refractive index instead of shape – the second generation of optics – allows thinner components but compromises bandwidth. Anisotropic materials make available two more parameters for controlling light beams. LCD industry is exploring one of them, modulation of effective birefringence - the third generation of optics. A recent breakthrough, the fourth generation of optics, relates to patterning optical axis orientation in the plane of anisotropic films. Obtained as thin film coatings on any desired substrate, including plastic, flat or curved, all different varieties of optical functions can now be obtained using the same materials and processes. 4G lenses, prisms, vortex waveplates, etc., are thin films of continuous structure allowing low-cost manufacturing just by inducing desired orientation patterns by a touch of polarization modulated light.

Unlike metamaterials, 4G optics technology is at a high level of maturity and is being studied and adapted for modern applications including LiDARs for auto-navigation, augmented reality displays, adaptive ophthalmic lenses, space telescopes, and even solar sails.

[1] N. Tabiryan, D. Roberts, D. Steeves, and B. Kimball, “4G Optics: New Technology Extends Limits to the Extremes,” Photonics Spectra, March, 2017, pp. 46-50.

Biography: Dr. Nelson Tabiryan pioneered development of the Fourth Generation Optics technology - Diffractive Waveplates - marking a major breakthrough in planar optics. He is the CEO of Beam Engineering for Advanced Measurements Corporation that demonstrated the first thinnest and largest planar lenses, prisms, and other spectrally and angularly broadband optics and photonics devices. He received a Ph.D. degree in Physics and Mathematics from the Institute of Physical Investigations of the Armenian Academy of Sciences, Yerevan (1982), and D. Sc. Degree from the Highest Certifying Commission of the USSR (1986). Dr. Tabiryan is OSA Fellow, NIAC (NASA) Fellow, Alexander Von Humboldt Research Scholar, recipient of the Frederiks Medal, and the American Chemical Society’s Cooperative Research Award (2013). He is the chairman of the International Meeting on Photoalignment and Soft Matter (PhoSM-2020) and other international meeting. Dr. Tabiryan is the program committee member, keynote, plenary and invited speaker in numerous conferences, and principal investigator of many advanced research programs being conducted for the Governmental and commercial organizations. He has over 250 refereed publications and 50 issued patents.

Hosted by: I.C. Khoo,  ick1@psu.edu

Gap plasmon resonance and coupling with epsilon-near-zero mode

Wednesday, September 30, 2020; 3:35 PM - 4:25 PM
ZOOM
Speaker: Junpeng Guo from University of Alabama in Huntsville

Abstract: When a plasmonic nanostructure is placed near a metal surface with a deep subwavelength insulating gap, a gap plasmon resonance mode can be excited.  A gap plasmon mode is non-radiative dark mode which traps optical energy in a small volume inside the gap.  In this talk, I will give a review on gap plasmon resonance and discuss the coupling of gap plasmon resonance with epsilon-near-zero mode for applications such as wideband perfect light absorption, nonlinear optics, and quantum nanophotonics.

Bio: Junpeng Guo earned his Ph.D. degree in Electrical Engineering from the University of Illinois at Urbana-Champaign. After receiving his Ph.D. degree, he started his career as a research scientist in the former Rockwell Science Center in Thousand Oaks, California and then moved to Sandia National Laboratories in Albuquerque, New Mexico as a member of technical staff. He joined the faculty of University of Alabama in Huntsville in 2005 and now is a Professor of Electrical Engineering and Optics. He received the Alan Berman Research Publication Award from in 2013 and was the only recipient of the University Distinguished Faculty Research Award in 2016. He is a Fellow of the SPIE-International Society for Optics and Photonics and currently serves as an Associate Editor of the Journal of Photonics Research and also as an Associate Editor of Journal of Nanophotonics. His research interest is nanophotonics, plasmonics, and quantum nanophotonics.

https://psu.zoom.us/j/91823970096

For password please contact Lisa Spicer@lms8@psu.edu

Hosted by: Lisa Spicer,  lms8@psu.edu

Artificial Intelligence in Mechanical Engineering

Tuesday, September 29, 2020; 3:35 p.m. (EST)
via Zoom (Contact sps5072@psu.edu for details)
Speaker: Dr. Amir Barati Faramani from Carnegie Mellon University

ABSTRACT: With the rise of Artificial Intelligence (AI) and Machine Learning (ML) in recent years, many complex problems in vision and computer science have been solved that were intractable for decades. In mechanical engineering (ME), complex problems still exist that conventional techniques could not offer viable solutions. Recent advances in AI has provided us with opportunities to merge and apply them to challenges in mechanical engineering, however; to accurately model and predict an engineering system, the representation and formulation of that problem into AI frameworks remain a challenge. The domain knowledge of ME is needed to represent and beneficially use AI algorithms to achieve viable solutions. To this end, I will talk about how effectively different areas of engineering can take advantage of AI to find solutions by integrating the physics and engineering domain knowledge. I will focus on examples in transport phenomena, material discovery, and manufacturing. I will then show how modern deep learning models, such as generative adversarial networks, can be used to learn the physics of transport without the knowledge of underlying constitutive equations and how novel feature extraction techniques can lead to the discovery of complex Partial Differential Equations. In addition, I will demonstrate how integration of chemistry and physics into graph convolutional neural networks can enhance the accuracy of material property prediction.

BIOGRAPHY: Professor Farimani joined the Department of Mechanical Engineering at Carnegie Mellon University in the fall of 2018. He was previously a postdoctoral fellow at Stanford University. He received his PhD in Mechanical Engineering in 2015 from University of Illinois at Urbana-Champaign. His lab at CMU focuses on the problems at the interface of Mechanical Engineering, data science and machine learning. His lab uses the state-of-the-art deep learning and machine learning algorithms and tools to learn, infer and predict the physical phenomena pertinent to mechanical engineering. Currently, he is teaching AI and ML to a large class of graduate students at CMU. He received the Stanley I. Weiss best thesis award from the University of Illinois in 2016 and was recognized as an Outstanding Graduate Student in 2015. During his post-doctoral fellowship at Stanford, Dr. Barati Farimani has developed data-driven, deep learning techniques for inferring, modeling, and simulating the physics of transport phenomena and for materials discovery for energy harvesting applications.

Hosted by: Serena Sidwell,  sps5072@psu.edu

Seminar - Dynamic Reorganization of Cardiac Nanodomains: A New Mechanism for Arrhythmia

Thursday, October 8, 2020; 12:05 p.m. to 1:20 p.m.
Via Zoom
Speaker: Dr. Sai Veeraraghavan from Ohio State University

Dr. Sai Veeraraghavan
Assistant Professor, Biomedical Engineering
Ohio State University

Seminar via Zoom, please email acv5167@psu.edu for link and password.

Abstract/Bio

Hosted by: Jamie Oberdick,  jco11@psu.edu

EE Colloquium: TBD

Friday, October 9, 2020; 1:25 p.m.
Zoom
Speaker: Ayman Abouraddy from UCF CREOL

Hosted by: Chris Giebink,  ncg2@psu.edu

Recent advancement on energy materials and microdevices: New nitrogen-doped graphene electrochemical catalysts with MOF (NG/MOF), and electrochemical biosensor microdevices

Wednesday, October 7, 2020; 3:35 PM - 4:25 PM
ZOOM
Speaker: Eon Soo Lee from New Jersey Institute of Technology

Abstract: This talk presents the recent advancements of the research on new nanomaterials for advanced electrochemical energy systems, and new electrochemical microdevices for disease detection and diagnosis for biomedical applications in The Advanced Energy Systems and Microdevices Laboratory at NJIT. The Lab’s energy research focuses on the non-platinum group of metal (non-PGM) catalysts to replace PGM catalysts for electrochemical-energy systems, such as fuel cells and batteries, and industrial applications such as gas exhaust catalytic converting systems and petroleum-processing systems. Principal research includes synthesizing and characterizing new high-performance non-PGM catalysts from carbon materials, and understanding the fundamental mechanisms of the structures. The Lab’s electrochemical biosensor microdevices research concentrates on applying micro- and nanotechnology to diagnose complex diseases, such as cancers, at their early stages using a nano-biochip. The biochip incorporates microchannels with a self-driven ?ow mechanism of bio?uid and nanocircuits to sense the existence and the level of severity of a disease with high sensitivity and selectivity. Those researches have been supported by the National Science Foundation, the New Jersey Health Foundation, NJIT and a private company, Abonics, Inc., in collaboration with and support from the Brookhaven National Laboratory- Center for Functional Nanomaterials, the John Theurer Cancer Center at Hackensack University Medical Center, CUNY’s Advanced Science Research Center and Rutgers University. The researches have several patents applied in PCT and US for the technology innovations.

Bio: Dr. Eon Soo Lee is Associate Professor with Tenure in Mechanical and Industrial Engineering and the Principal Investigator in Advanced Energy Systems and Microdevices Laboratory at New Jersey Institute of Technology (NJIT) where he joined in 2013, and Founder of ABONICS, INC which is a newly established startup company for the biochip technology for disease detection, diagnosis and monitoring. 
His pioneering research on graphene-based new electrochemical catalysts and biochip technologies has gained many international recognitions in conferences and journals, and has received many honors and awards including Vanguard Higher Education Leader in NJ (2018), New Jersey Health Foundation Innovation Award (2017), NIH/IEEE-EMBS Best Design Award (2017), TechConnect National Innovation Award (2017) and Defense Innovation Award (2017). 

He has established extensive researches on energy materials, electrochemical systems, microfluidics, and bio-agent reactions in both academia and industries including Stanford University, Samsung and Hyundai, before joining at NJIT in 2013. In particular, at Samsung R&D Center as a Principal Research Engineer, Dr. Lee was awarded a prestigious Samsung Technology Award in 2011 due to his significant contribution to the innovative nano materials and electrochemical systems. He holds PHD (2007) and MS (2004) at Stanford University, and BS (1999) at Yonsei University, Seoul, Korea, all in Mechanical Engineering.

https://psu.zoom.us/j/91823970096

For password please contact Lisa Spicer @ lms8@psu.edu

Hosted by: Lisa Spicer,  lms8@psu.edu

EE Colloquium: The NASA CYGNSS MicroSat Constellation

Friday, October 16, 2020; 1:25 p.m.
Zoom
Speaker: Chris Ruf from University of Michigan

Abstract: The CYGNSS constellation of eight microsatellites was successfully launched in December 2016 into a low inclination (tropical) Earth orbit. Each satellite carries a four-channel bistatic radar receiver which measures signals transmitted by Global Positioning System (GPS) satellites and scattered back into space by the Earth surface. Over the ocean, surface roughness, near-surface wind speed and air-sea latent heat flux are estimated from the direct measurements of surface scattering cross section. Over the land, estimates of near-surface soil moisture and imaging of flood inundation are also possible. Engineering commissioning of the constellation was completed in March 2017 and the mission is currently in its science operations phase.

Assimilation of CYGNSS wind speed data into the NOAA HWRF hurricane weather prediction model has also been studied, and their impact on forecast skill demonstrated. Level 2 science data products over land related to near-surface volumetric soil moisture content and flood inundation extent have also been developed.

An overview and current status of the mission will be presented, together with highlights of recent science and applications results.

Biography: Chris Ruf received the B.A. degree in physics from Reed College and the Ph.D. degree in electrical and computer engineering from the University of Massachusetts. He is the Fredrick Bartman Collegiate Professor of Climate and Space Science at the University of Michigan. He has worked previously at Intel Corporation, Hughes Space and Communication, the NASA Jet Propulsion Laboratory, and Penn State University. Dr. Ruf’s research interests include GNSS-R remote sensing, microwave radiometry, atmosphere and ocean geophysical retrieval algorithm development, and sensor technology development. He is former Editor-in-Chief of the IEEE Transactions on Geoscience and Remote Sensing and has served on the editorial boards of Radio Science and the Journal of Atmospheric and Oceanic Technology. He also served on the 2006 and 2016 U.S. National Academy of Sciences Earth Science Decadal Survey Panels. Dr. Ruf has been the recipient of four NASA Certificates of Recognition and seven NASA Group Achievement Awards, as well as the 1997 TGRS Best Paper Award, the 1999 IEEE Resnik Technical Field Award, the 2006 IGARSS Best Paper Award, and the 2014 IEEE GRS-S Outstanding Service Award. He is currently Principal Investigator of the NASA Cyclone Global Navigation Satellite System (CYGNSS) mission.

Hosted by: Tim Kane,  tjk7@psu.edu

Smart structures for Smart cities: Real-time dynamic control of civil engineering structures in the face of natural disasters

Wednesday, October 14, 2020; 3:35 PM - 4:25 PM
ZOOM
Speaker: Mariatonieta Gutierrez Soto from University of Kentucky

Abstract: Multiple natural hazards pose a significant threat to critical infrastructure in many parts of the world that directly affect people's lives. The protection of the built environment from natural hazards is a vital and complex issue facing engineers. With the increased interest in smart cities, there is a need for an intelligent built environment. This research talk will present on-going projects towards the Design of Resilient, Economic, Appropriate, and Multidimensional (DREAM) communities. The latest innovation to fight natural hazards is the development of smart structures. The goal is to design a new generation of intelligent structures equipped with sensors and control devices that can react in real-time during multiple hazards. We create these adaptive structures with human-like capabilities by using agent-based modeling, vibration control, evolutionary game theory, and neural dynamic optimization. We tested the method on buildings and bridge structures. This unique intersection allows for other exciting projects such as aerodynamic mitigation through the origami-inspired morphing building envelope, and biomimicry design applying aquatic life adaptations and patterns into urban planning and structural design. To bring computational discovery to reality, we investigate integrative design or "control co-design" methods to simultaneously design the structure and control devices, optimal placement of sensor and control devices, and distribution of tasks during failure mechanisms. We study large-scale structures using testing technologies such as hybrid simulation that combines numerical and experimental substructures. Furthermore, there are social, behavioral, and economic barriers related to adopting mitigating solutions. To tackle these problems, we develop computational models. We use the data from field reconnaissance recovery of physical and social aspects related to the built environment from communities affected by natural hazards to quantify resilience. These efforts open the pathways for investigation of the next generation of sustainable smart communities that are significantly more resilient against natural disasters.

Bio: Mariantonieta Gutierrez Soto received a B.S. in Civil Engineering from Lamar University, Beaumont, TX, and M.S. and Ph.D. degrees in Civil Engineering from the Ohio State University, Columbus, OH, under mentorship of renowned Prof. Hojjat Adeli. She was awarded the Faculty Research Mentor of the Week in 2019 from the University of Kentucky, and the Presidential Fellowship in 2016 and received the Distinguished Graduate Student awards in 2011 and 2017 from the Ohio State University. Her current research interests focus on DREAM structures for smart cities.

https://psu.zoom.us/j/91823970096

For password please contact Lisa Spicer @ lms8@psu.edu

Hosted by: Lisa Spicer,  lms8@psu.edu