Aerospace Engineering
Erosion Mechanisms in the Hall Effect Thruster
Wednesday, September 19, 2018;
4:30 PM - 5:30 PM
220 Hammond Building
Speaker: Mitchell L. R. Walker from Georgia Institute of Technology
Electric propulsion devices are rapidly replacing traditional chemical rockets on government and commercial spacecraft. Electric propulsion devices possess a combination of high specific impulse and high thrust efficiency that drastically reduce the mass of propellant required to perform a specific mission. Satellite operators leverage these characteristics to reduce the mass and related size of a spacecraft while maintaining its payload capability. Thus, the same on-orbit capability is achieved at a significantly lower launch cost. Concurrently, NASA uses electric propulsion to execute missions that are not possible with chemical rockets. The drawback of electric propulsion is that the thrust level is limited by the electrical power available on the spacecraft. Thus, the required operational life of contemporary electric propulsion devices is thousands of hours.
The Hall effect thruster (HET) is a type of electric propulsion that has a high thrust density. HETs are routinely flown on geosynchronous spacecraft. Currently, HET development requires expensive, high-risk, ground-based qualification tests that exceed 7,000 hours to demonstrate the necessary on-orbit lifetime. To date, modeling efforts have been unable to predict the dominant failure mechanism observed in HET qualification tests. In particular, how quickly is the ceramic HET discharge channel eroded by the accelerated plasma?
In response to this issue, the Air Force Office of Scientific Research (AFOSR) has initiated a research program to study plasma-wall interactions. This presentation discusses an AFOSR-sponsored effort to develop a fundamental understanding of how the HET discharge plasma erodes the boron-nitride discharge channel. This knowledge will facilitate our ability to predict HET lifetime and will influence the design of future high-power HETs.
Hosted by: Michelle Barnyak, Aerospace Engineering
(mlf1@psu.edu)
Biomedical Engineering
Red Blood Cell Released ATP in Disturbed Blood Flow-Initiated Vascular Inflammation and Atherosclerosis
Thursday, September 20, 2018;
12:05 PM - 1:20 PM
158 Willard Building
Speaker: Dr. Ping Nian He from Penn State
Vascular inflammation and atherosclerosis are implicated in many cardiovascular diseases. While the systemic risk factors such as hyperlipidemia are exposed to entire vasculature under pathological conditions, the atherosclerotic plaques often preferentially develop at sites with disturbed flow, indicating a role of hemodynamic forces in atherogenesis. For decades, endothelial cell (EC) responses to the changes in wall shear stress (WSS) have been the main focus of the flow dynamics related studies, which basically consider the circulating blood as a cell-free fluid and completely overlooked the impact of mechanical force-activated blood cells on the vascular walls. Our recent studies conducted in intact venules provided the first experimental evidence that changes in blood flow alter EC function through both WSS and flow dynamics-triggered ATP release from RBCs, and that the released ATP via RBC pannexin 1 (Panx1) channels alters EC barrier integrity and vascular permeability. These observations led us to hypothesize that the RBC-released ATP during blood flow changes plays a significant role in site-specific vascular vulnerability and synergistically contributes to the initiation and progression of vascular inflammation and atherosclerosis in the presence of systemic risk factors. Two hypercholesterolemia mouse models with blood cell specific deletion of Panx1 (ApoE-/-Panx1-/- and AAV-PCSK9DYPanx1-/- fed with high fat diet) were developed to investigate the role of RBC-released ATP in high fat diet-induced site-specific plaque formation and atherosclerotic progression in major arteries. Our study found reduced leukocyte adhesion in venules and about 40-60% reduction of atherosclerotic plaque formation in mouse aorta at regions of disturbed flow with RBC Panx1 deletion. Our results indicate an important role of RBC released ATP in the site-specific vascular pathogenesis. We are in the process of establishing collaborations to develop computational models of shear stress effects on RBCs and the distribution of RBC released ATPs during blood flow pattern changes. We aim to provide new mechanistic insight into mechanical force-initiated vascular pathogenesis with both experimental evidence and computational support.
Hosted by: Jenna Sieber, Biomedical Engineering
(jns5431)
Engineering Science and Mechanics
Study of the Anterior Cruciate Ligament-My Cross to Bear
Wednesday, September 19, 2018;
3:35pm - 4:25pm
114 EES Building
Speaker: Professor Patrick Smolinski from University of Pittsburgh
The anterior cruciate ligament (ACL) is the most often injured ligament in the knee and is a common activity related injury. In the United States, it is estimated that 100,000-200,000 ACL injuries occur and over 100,000 ACL reconstructions are performed
annually. Although ACL reconstruction has been performed for nearly 100 years, and is now a very common arthroscopic surgery, there is not agreement on methods of the reconstruction. Moreover, there are still unresolved issues in ACL reconstruction with
long term results generally leading to joint arthritis. Due to its complex mechanical behavior, the study of the knee is still an active area of research. This is also true of the ACL which has an irregular morphology with a composite construction and nonlinear material properties. This talk will give an overview of the knee function and anatomy and then discuss the anterior cruciate ligament, its function, anatomy and mechanisms of injury. Aspects of ACL reconstruction surgery will also be discussed. A variety of examples of the application of engineering and technology to study aspects of ACL anatomy, function and reconstruction will be presented. This will include both experimental and computational studies.
Bio sketch
Hosted by: Dr. Akhlesh Lakhtakia, Engineering Science and Mechanics
(814 865-4523)
Fluid Dynamics Research Consortium
Fluid Dynamics and Local Scour around Complex In-Stream Structures
Thursday, September 20, 2018;
9:00 AM
22 Deike Building
Speaker: Yuncheng Xu from Department of Civil and Environmental Engineering, The Pennsylvania State University
Abstract: In-stream structures play a significant role in flow resistance, sediment transport, invertebrate habitats and other biogeochemical functionalities of rivers and streams. Typical natural and engineered in-stream structures include large woody debris, engineered log jams, rock vanes and weirs. They are often used in engineering practice to restore impaired and disturbed rivers. River restoration is a billion-dollar industry which has impacts on our daily life. All the physical and ecological functions of these structures depend on the flow processes around and inside them. However, due to geometrical complexity and interstitial space within, the flow process is often very complex. In previous studies, these porous complex structures are often simplified as solid cylinders or blocks due to technical limitations in experiments and numerical models. The first part of this talk will demonstrate how much geometrical details is necessary to resolve the hydrodynamics around these complex structures, and the consequences of simplifications in terms of wake dynamics and mixing processes. The second part will show the progress made in simulating sediment transport and local scour around these structures with an immersed boundary method. Since wall shear stress is of critical importance to the motion of sediment particles, our new immersed boundary method utilizes a y+-adaptive strategy which produces much smoother and well-behaved wall shear. The use of immersed boundary method makes it possible to simulate scour around complex structures, and thus its application for real-world projects. Preliminary example simulations will be demonstrated and discussed.
Biography: Yuncheng Xu is a Ph.D. candidate in the Department of Civil & Environmental Engineering at Pennsylvania State University. He got his bachelor’s degree in Engineering Mechanics and master’s degree in Agricultural Engineering from China Agricultural University. He started working with Dr. Xiaofeng Liu since 2014. His doctoral thesis topic is about simulating hydrodynamics and morphodynamics around complex in-stream structures. He specializes in computational hydraulics and developing numerical models in OpenFOAM.
www.FDRC.psu.edu
Hosted by: Dr. Ying Pan, Fluid Dynamics Research Consortium
(yyp5033@psu.edu)
Mechanical and Nuclear Engineering
Distributed Schemes for Networked Stochastic Optimization and Nash Games
Monday, September 17, 2018;
4:00pm-5:00pm
125 Reber Building
Speaker: Jinlong Lei from Penn State Industrial Engineering
There are a broad range of optimization and equilibrium problems in
networks, arising in power grids, wireless communication networks, and
sensor networks. Such networked problems are complicated by various
challenges such as uncertainty and nonconvexity. This talk will focus on the
following research questions: (i) How to deal with uncertainty in networked
settings? (ii) How may such problems be solved in limited communication
regimes? (iii) How such problems be solved asynchronously? In this
presentation, we show that these challenges can be addressed by a
combination of distributed and Monte-Carlo sampling algorithms,
asynchronous fixed-point iterations, quantization methods, etc. We present
several schemes: (i) We propose a stochastic approximation-based distributed
primal-dual algorithm to solve the distributed stochastic convex optimization
problem and prove a.s. convergence along with the asymptotic normality and
efficiency; (ii) We then present a variable sample-size stochastic gradient
method with increasing batch-sizes to solve the stochastic nonconvex
optimization, prove a.s. convergence to stationary points, and establish the
oracle and iteration complexity bounds; (iii) Our third scheme is a
distributed quantized algorithm for solving networked linear equations,
where we obtain the exponential convergence with a minimal bit rates
statement; (iv) Finally, we design an asynchronous inexact proximal best response
scheme for potential stochastic Nash games, where a.s. and mean
convergence are shown under suitable conditions on the inexactness
sequences.
Hosted by: Hosam Fothy, Mechanical Engineering
(hkf2@psu.edu)
How to Start and Grow a Business Out of Grad School
Tuesday, September 18, 2018;
3:35 pm
135 Reber Building
Speaker: Jeremy Frank from KFC Technologies
Jeremy Frank will discuss the pitfalls and failures (and how to overcome them!) on the path to building a successful company out of graduate research.
Hosted by: Mary Frecker, Mechanical Engineering
(amb52@psu.edu)
The International Nuclear Nonproliferation Regime
Thursday, September 20, 2018;
4:00pm-5:00pm
135 Reber Building
Speaker: Katherine Bachner from Brookhaven National Laboratory
The lecture will introduce students to the international nuclear nonproliferation regime at a high level, focusing on safeguards and security. It will touch upon key historical moments that have driven nonproliferation as it exists today, the development of essential legal instruments used by the international community to fight further proliferation, diplomatic tensions that exist surrounding the nuclear ‘haves’ versus ‘have-nots’, and as time permits, will include an overview on the logic of nuclear deterrence.
Hosted by: Kenan Unlu, Mechanical Engineering
(amb52@psu.edu)
Biomedical Engineering
Neural Circuits and Systemic Factors Controlling Cerebral Blood Flow and Oxygenation
Thursday, September 27, 2018;
12:05 PM - 1:20 PM
158 Willard Building
Speaker: Dr. Patrick Drew from Penn State
The brain has an enormous metabolic demand that can only be met with an uninterrupted blood supply. Though it has been known for over a century that increases in neural activity in the brain are followed by increases in the local blood flow, the cellular and molecular mechanisms linking neural activity and blood flow in the brain are unresolved, as is the question to how oxygen levels in the brain relate to neural activity and blood flow. I will present recent work from my lab where we dissect the role of different neuron types in controlling basal and sensory-evoked blood flow and we determine how systemic factors influence the oxygen levels in the brain.
To determine which of neuron types that control local cerebral blood flow, we disrupted the activity of specific neural populations in awake mice using cell-type specific activation and inactivation with DREADDs (Designer Receptors Exclusively Activated by Designer Drugs), and targeted pharmacological infusions. We assayed the neural and vascular impacts of these manipulations with electrophysiology, genetically-encoded calcium indicators, and longitudinal 2-photon microscopy. Surprisingly, we find that blood flow is not controlled by overall population activity, but rather by small group of interneurons. This result implies that blood flow changes can completely decouple from the overall population neural activity.
To test the role respiration plays in determining tissue oxygenation, we measured respiration, blood flow, neural activity, and oxygen tension in the cortex of awake, head-fixed mice free to run on a spherical treadmill. Cortical oxygen levels were more correlated with respiration than neural activity or blood flow, particularly during bouts of exercise when respiration was elevated. Exercise drove rapid tissue and blood oxygen increases in both somatosensory and frontal cortex, even though exercise did not cause blood flow increases in frontal cortex. Local silencing of neural activity blocked vasodilation, but exercise-induced oxygen increases persisted. This shows respiration is a key regulator of cortical oxygenation in the behaving animal.
Hosted by: Jenna Sieber, Biomedical Engineering
(jns5431)
Chemical Engineering
CO2-Derived Carbon Materials for Energy Conversion and Storage
Thursday, September 27, 2018;
10:45 - 11:45 am
102 Chemistry Building
Speaker: Jae W. Lee from Korea Advanced Institute of Science and Technology
CO2-Derived Carbon Materials for Energy Conversion and Storage
Hosted by: Lisa Haines, Chemical Engineering
(lhaines@engr.psu.edu)
Electrical Engineering
Colloquium
Tuesday, September 25, 2018;
4:35 p.m.
358 Willard Building
Speaker: Prof. Cong Shen from University of Science and Technology of China
TBA
Hosted by: Dr. Jing Yang, Electrical Engineering
(juy157@psu.edu)
Colloquium
Thursday, September 27, 2018;
4:35 p.m.
358 Willard Building
Speaker: Wayne L. Mowery from Senior Director of Compliance and University Export Compliance Officer, Penn State
Program-specific SARI Seminar
Hosted by: Dr. Vishal Monga, Electrical Engineering
(vum4@psu.edu)
Engineering Science and Mechanics
Linking Material Microstructure with Damage Diagnostics and Prognostics
Wednesday, September 26, 2018;
3:35pm - 4:25pm
114 EES Building
Speaker: Professor Antonios Kontsos from Drexel University
Two recent science and technology developments allow a renewed viewpoint in understanding material structure-properties-behavior relationships, which is in general challenging due to the several time and length scales involved. First, the widespread use of
material characterization equipment capable to zoom into the structure of matter and reveal effects in almost real testing time. The second relates to the development of testing tools coupled with novel computational methods that are capable to explore the spatial and temporal degrees of freedom involved when investigating the behavior of materials. In this context, this talk will
attempt to demonstrate that classical topics of solid mechanics such as the ones involving ductile fracture can now be revisited with the intend to better understand both physically and mechanistically relationships between material structure and multiscale behavior. To demonstrate elements of this new era in the field of mechanics this talk will show how the combination of mechanical testing at several scales coupled with material characterization and monitoring of structural and behavioral changes can assist in the development of both theoretical knowledge and practical engineering insights into what happens when damage initiates as well
as what precedes this state of incipient failure. A particular aluminum alloy class is used for demonstration purposes while the results are cast into a more generic engineering framework created to link diagnostics with prognostics.
Hosted by: Dr. Akhlesh Lakhtakia, Engineering Science and Mechanics
(814 865-4523)
Mechanical and Nuclear Engineering
Extrinsic Effects on Phonon Thermal Transport in Oxides
Tuesday, September 25, 2018;
3:35 pm
135 Reber Building
Speaker: Brian Foley from The Pennsylvania State University
This presentation will cover several phonon scattering mechanisms in a variety of materials to shed light on how nano-structuring affects the thermal conductivity of a material. Various mechanisms include scattering at incoherent interfaces, such as grain boundaries in nano-grained SrTiO3 and BaTiO3, scattering at coherent interfaces such as weakly bonded layers in Sr2Nb2O7 and ferroelastic domain boundaries in BiFeO3, and scattering due to point defects such as impurities/dopants in solid-solution alloys such as PZT. The overarching goal is that the attendees will be able to leave with an improved understanding of phonon thermal transport.
Hosted by: Mary Frecker, Mechanical Engineering
(amb52@psu.edu)
Chemical Engineering
Understanding the role of solvent effects in the thermal and electrochemical hydrogeneration of organics"
Thursday, October 4, 2018;
10:45 am - 11:45 am
102 Chemistry Building
Speaker: Roger Rousseau from Pacific Northwest National Laboratory
Understanding the role of solvent effects in the thermal and electrochemical hydrogeneration of organics"
Hosted by: Lisa Haines, Chemical Engineering
(lhaines@engr.psu.edu)
Electrical Engineering
Colloquium
Thursday, October 4, 2018;
4:35 p.m.
358 Willard Building
Speaker: Prof. Galina Rogova from State University of New York at Buffalo
TBA
Hosted by: Dr. Ram Narayanan, Electrical Engineering
(rmn12@psu.edu)
Engineering Science and Mechanics
Optimal Bounds and Optimal Microstructures for Multiphase Composites
Wednesday, October 3, 2018;
3:35pm - 4:25pm
114 EES Building
Speaker: Professor Liping Liu from Rutgers University
This talk will focus on an optimal design problem for multiphase composites. Mathematically,this optimal design problem is equivalent to the quasi-convexification of a multi-well energy function and is addressed by an indirect method. That is, a microstructure-independent bound is first derived for the effective energy function, and then, an optimal microstructure is explicitly constructed to attain this bound. Both directions can be quite non-trivial and are not fully solved for composites of three or more phases.
In the first part of the talk, I will present a new method of deriving the Hashin-Shtrikman boundsfor multiphase composites which turn out to be the best known bounds. This method conveniently yields the optimality conditions for microstructures. Secondly, we show the optimality conditions cannot always be satisfied for composites of three or more phases. In particular, we find an explicit necessary and sufficient conditions for the optimality of the Hashin-Shtrikman bounds for three-phase isotropic conductive composites of isotropic materials. Finally, we present a necessary condition for smooth optimal microstructures and
propose some open problems that may be of interest to analysts.
Hosted by: Dr. Akhlesh Lakhtakia, Engineering Science and Mechanics
(814 865-4523)
Biomedical Engineering
Biomechanics of Plant Cell Wall Growth: Nano-Scale and Macro-Scale Behaviors
Thursday, October 11, 2018;
12:05 PM - 1:20 PM
158 Willard Building
Speaker: Dr. Daniel Cosgrove from Penn State
Cell growth is an essential determinant of the size and shape of plants, from miniscule mosses to massive redwoods. Enlargement of the cellulosic cell wall limits growth. Here I will outline our current understanding of the biophysics of cell growth and the complex structure of the cell wall before presenting current research into the molecular control of cell wall extensibility.
Hosted by: Jenna Sieber, Biomedical Engineering
(jns5431)
Chemical Engineering
Ion Solubility, Diffusivity, and Transport in Charged Polymer Membranes
Thursday, October 11, 2018;
10:45 - 11:45 am
102 Chemistry Building
Speaker: Benny D. Freeman from The University of Texas at Austin
Ion Solubility, Diffusivity, and Transport in Charged Polymer Membranes
Hosted by: Lisa Haines, Chemical Engineering
(lhaines@engr.psu.edu)
Electrical Engineering
Colloquium
Thursday, October 11, 2018;
4:35 p.m.
358 Willard Building
Speaker: Prof. Kamesh Namuduri from University of North Texas
TBA
Hosted by: Dr. Sven Bilén, Electrical Engineering
(sgb100@psu.edu)
Engineering Science and Mechanics
Patterns, Growth and Energy - Lessons from Biology for Architectural Design
Wednesday, October 10, 2018;
3:35pm - 4:25pm
114 EES Building
Speaker: Professor Peter Gruber from University of Akron, Ohio
A biological paradigm is underlying current research and development interests in architectural
design. Biomimetics as a strategic approach to translate information from biology to technology
serves as a base for the projects presented in this talk. Different pathways to translate concepts of
life to innovative design proposals and prototypes will be presented with a special focus on
methods and tools.
Patterns and specifically growth in biology was investigated in a research project at the
University of Applied Arts Vienna, Austria, aiming at the transfer of growth concepts to the
design of materials and structures. Main parts of the research focused on mycelium material, use
of slime mold as a co-designer, use of algae in a bio-reactor and improving 3D printing as a tool
for producing adaptive structures.
Thermodynamics of plants was identified as an interesting field delivering concepts for technical
applications. Leaf morphology is influenced by a variety of factors, also affecting plant water
balance and energy budget. In a current research project at the University of Akron, we
investigate to correlation of leaf shape with evapotranspiration and thermal dynamics, to better
understand the biological model and transfer the working principles to technical energy
dissipation systems.
Bird’s nests are buildings that are generated in a wide variety of shapes and using locally
available materials. Stick nests consisting of non-woven straight elements deliver an interesting example of an aggregate tructure made of more or less randomly assembled elements without connections, but still delivering interesting mechanical properties. Research on birds nests was taken on in a recent workshop at the Bauhaus in Bernau, Germany, and interpreted in a range of
prototypical structures.
The research presented led to prototypical solutions, laying the groundwork for future product oriented technological solutions.
Hosted by: Dr. Akhlesh Lakhtakia, Engineering Science and Mechanics
(814 865-4523)
