2020 Faculty and Student Summer Talks

Ryan Allaire

Thermal Effects in Nanoscale Thin Liquids Heated by a Laser with Applications to Liquid Metal Assembly

Professor David Shirokoff

Stability and Numerics in Differential Equations

Professor Enkeleida Lushi​

Micro-swimmers Moving in Complex Confinement

Interactions between micro-swimmers and solid boundaries play an important role in many biological and technological processes. I will discuss recent results in experiments and simulations that aim to understand the motion of micro-swimmers such as bacteria, micro-algae, spermatozoa or active colloids in various confinements or structured environments. Our results highlight the complex interplay of the fluidic and contact interactions of the individuals with each-other and the boundaries to give rise to complex individual and collective behavior.

Professor Cyrill Muratov​

The Mathematics of Charged Liquid Drops

In this talk, I will present an overview of recent analytical developments in the studies of equilibrium configurations of liquid drops in the presence of repulsive Coulombic forces. Due to the fundamental nature of Coulombic interaction, these problems arise in systems of very different physical nature and on vastly different scales: from femtometer scale of a single atomic nucleus to micrometer scale of droplets in electrosprays to kilometer scale of neutron stars. Mathematically, these problems all share a common feature that the equilibrium shape of a charged drop is determined by an interplay of the cohesive action of surface tension and the repulsive effect of long-range forces that favor drop fragmentation. More generally, these problems present a prime example of problems of energy driven pattern formation via a competition of long-range attraction and long-range repulsion. In the talk, I will focus on two classical models - Gamow's liquid drop model of an atomic nucleus and Rayleigh's model of perfectly conducting liquid drops. Surprisingly, despite a very similar physical background these two models exhibit drastically different mathematical properties. I will discuss the basic questions of existence vs. non-existence, as well as some qualitative properties of global energy minimizers in these models, and present the current state of the art for this class of geometric problems of calculus of variations.

Axel Turnquist

Elliptic PDE and Some Regularity Questions

We desire to solve the Monge-Amp\'{e}re, a fully nonlinear second-order elliptic PDE, on the unit sphere using numerical schemes. In order to prove a convergence of the scheme, it is important to understand the function space we expect the solution to be in: this is the realm of regularity theory of elliptic PDE. In order to understand the regularity theory for our PDE, it requires a fundamental understanding of how nonlinearity, the degree of the PDE, the property of uniform ellipticity, and the geometry of the sphere all affect the regularity of the solution. This leads us to an examination as to what it means fundamentally to be an elliptic PDE, and why the conditions we commonly see in the literature are so important conceptually. This also leads us to examine some more technical cases that extend beyond the usual classical literature, and their ramifications.

Professor Linda Cummings

Wetting and Dewetting of Nanoscale Nematic Liquid Crystal Films

Rituparna Basak

Application of Machine Learning Techniques for the Stick Slip Dynamics of a Particulate Media

Chao Cheng

The Force Network Precursors to Slip Events in Sheared Granular Systems

The stick-slip transition of granular systems is related to earthquakes and avalanches, and therefore understanding the conditions leading to slip events is of general importance. Although stick-slip behavior has been studied extensively, what triggers a slip event still remains unclear. The purpose of our study is to explore the existence of precursors to slip events. For this purpose, we study a sheared system in a stick-slip regime via two-dimensional discrete element simulations. Particular focus is on the evolution of force networks before and during slip events. We apply the persistence diagrams and other classic measures to the force networks' evolution of slip events. Persistence homology to granular systems can reveal the changes in the topological structure of the force networks, which can be shown that relate the macro behavior of the system. We will show that some features of force network evolution could be used to gain insight into the occurrence of a slip event.

Guangyuan Liao

Model Reduction Techniques for Coupled Circadian Oscillators

The circadian rhythm refers to an internal body process that regulates many body processes including the sleep-wake cycle, digestion and hormone release. The ability of a circadian system to entrain to the 24-hour light-dark cycle is one of the most important properties. There are several scenarios in which circadian oscillators do not directly receive light-dark forcing. Instead they are part of hierarchical systems in which, as “peripheral” oscillators, they are periodically forced by other “central” circadian oscillators that do directly receive light input. Such dynamics are modeled as hierarchical coupled limit cycle systems. Those models usually have a large population, and are non-autonomous. Direct simulations usually are incapable of understanding the full dynamics of such models. One topic of this talk is to apply proper mathematical methods on simplification of the original systems. A phase reduction method is applied for reducing the original system to phase model. A parameterization method is introduced for simplifying such systems, and it is also applied for computing invariant manifolds of some biological oscillators. Another topic of this talk is to develop new tools. A novel tool, entrainment map, is developed. Compared with direct simulations, the map has great advantages of describing the conditions for existence and stability of the limit-cycle solutions, studying the bifurcations on forcing strength and coupling strength. It is also more practical to calculate the entrainment times by just iterating the map than direct simulations.

Diego Rios

Sound Propagation Modeling for Geoacoustic Inversion

A sound source is transmitting acoustic signals in an oceanic environment that are received at vertically separated hydrophones in the water column. Using ray theory, we focus on four travel paths the emitted signal travels by and generate replica arrival times, which will allow for the inverse problem to be solved. This problem is simply the estimation of parameters that affect sound propagation by employing mathematical propagation modeling and received data.  The generated arrival times will eventually be compared with arrival time estimates obtained from recorded time-series, allowing us to estimate properties of the seabed such as thickness and sound speed. Challenges in the estimation of the arriving times of the travel paths (especially of the one that propagates through the sediment) will be discussed.

Connor Robertson 

Discovering the Governing PDE of an Active Nematic System from Video Data

Gan Luan

Parameter Estimation and Inference of Spatial Autoregressive Model by Stochastic Gradient Descent

Yixuan Sun

Membrane Filtration with Multiple Species of Particles

Ruqi Pei

A New Panel-based scheme for the Discretization of Boundary Integral Equations

Atefeh Javidialsaadi

Model Checks for Two-Sample Location-Scale

Beibei Li

On Weighted Holm Procedures

In many statistical applications, such as clinical studies and a genome-wide association study (GWAS), it often happens that some hypotheses are more important than the others, which suggests us to assign different weights to hypotheses according to their different importance. Recently, many weighted procedures have been developed for controlling the familywise error rate (FWER) when conducting multiple hypotheses testing. Among these procedures, weighted Holm procedures are the most popular and easy to be applied without any assumption of dependence structure. There are two common weighted Holm procedures. One is based on ordered weighted p-values that we called WHP; the alternative weighted Holm procedure that is based on ordered original p-values is named WAP.  The objective of this project is to study these two weighted Holm procedures and make recommendations for their use. In this talk, by constructing and comparing their corresponding closed testing procedures, graphical approaches, and adjusted p-values, we show that WHP is more powerful than WAP. Also, we provide a theoretical result that WHP is an optimal procedure in the sense that the procedure cannot be improved by increasing even one of its critical values without losing control over the FWER. Simulations were conducted to provide numerical evidence of superior performance of WHP in terms of the FWER controlling and average power.

Yuexin Liu

How to Train Stokes Swimmer Using Machine Learning

Machine learning has been applied to an increasing range of  physics and  engineering, and recently it has been  applied in zero-Reynolds number flow for flow control and designing of swimmers. Artificial micro-swimmers in engineering and medical applications such as drug delivery and cell manipulation show great success, however, hydrodynamic interactions in low Reynolds number environments and the uncontrolled environmental factors will also influence the swimmer’s behavior. Here, we present a reinforcement learning paradigm to design a new set of self-learning, adaptive linear N-swimmer and N-sphere rotator (N=3, 4) in a viscous Stokes fluid. Different from the typical designed autonomous rotators, we do not prescribe any propulsion strategy but allow the rotator to self-learn its own rotating gaits based on its interactions with the surrounding environment through reinforcement learning. We show the ability of the N-sphere rotator to obtain the optimal propulsion policies. Our study illustrates the potential of reinforcement learning in fluid mechanics and provides a new way for designing smart artificial swimmers.

Erli Wind-Anderson

Introduction to Convolution Quadrature

This talk will explore solving the exterior wave equation in an unbounded domain. The method that will be used to do this is the Convolution Quadrature method (CQ) , which is a fast numerical solution. The benefits of CQ lies in its ability to transform the exterior wave scattering problem into many decoupled Helmholtz Equations, which can then be solved via a boundary integral formulation. The talk will focus on a basic derivation of the CQ scheme along with reductions in the number of Helmholtz equation solves that need to be computed.

Professor Yuan-Nan Young 

Cellular Dynamics and Fluid-Structure Interactions

Kosuke Sugita

Boundary Integral Equation Methods on Stokes Flow Equations in Two Dimensions

Professor James MacLaurin

Emergent Dynamics in Interacting Particle Models with Random Connections

Ryan Atwater

Studies of Two-Phase Flow with Soluble Surfactant

Brandon Behring

Dances and Escapes of the Vortex Quartet

The leapfrogging motion of two pairs of equal strength point vortices has fascinated researchers since its discovery 150 years ago by Grobli and by Love. This talk will focus on the mechanisms by which orbits transition from a neighborhood of this bounded (relative) periodic motion into orbits that either remain bounded but 'dance' or orbits in which the vortices escape to infinity as pairs along two transverse rays. By observing that the dances of vortex quartet are, in many parts of the phase space, close to those of a related integrable three-vortex system, we reframe the problem as a near-integrable two degree-of-freedom Hamiltonian system. By visualizing the geometry of this dynamical system, we can understand the role that phase space structures such as periodic orbits (along with their corresponding invariant manifolds) and KAM tori (and their breakup) play in allowing or forbidding the transition from dance to escape.

Nicholas Dubicki

Electrostatics

Professor Zuofeng Shang

Statistical Optimality of Deep Neural Networks in Regression and Classification

Professor Christina Frederick

Some Open Problems in Frame Theory

Professor Victor Matveev

Deterministic vs Stochastic Modeling of First Passage Time to Calcium-Triggered Vesicle Release

Like most physiological cell mechanisms, synaptic neurotransmitter vesicle release is characterized by a high degree of variability in all steps of the process, from Ca2+ channel gating to the final triggering of membrane fusion by the SNARE machinery. The associated fluctuations can be quite large since only a small number of Ca2+ ions enter the cell through a single channel during an action potential, and these fluctuations are further increased by the stochasticity in Ca2+ interactions with Ca2+ buffers and sensors. This leads to a widely-held assumption that solving mass-action reaction-diffusion equations for buffered Ca2+ diffusion does not provide sufficient accuracy when modeling Ca2+-dependent cell processes. However, comparative studies show a surprisingly close agreement between deterministic and trial-averaged stochastic simulations of Ca2+ diffusion, buffering and binding. I this talk I will present further analysis and comparison of stochastic and mass-action simulations, focusing on Ca2+ dynamics downstream of Ca2+ channel gating. Namely, we will compare the distributions of first-passage-times (FPT) to full binding of the model Ca2+ sensor for vesicle fusion, when calculated using stochastic and deterministic approaches. I will start with the definition of first-passage time using a highly simplified single compartment model, and then progress to a two-compartment model of Ca2+ dynamics which will allow rigorous comparison of deterministic (mass-action) and stochastic calculation of FPT distribution. I will show that the discrepancy between deterministic and stochastic estimates of FPT density can be surprisingly small even when only a few Ca2+ ions enter the cell per single channel-vesicle complex, despite the fluctuations caused by the Ca2+ binding and unbinding. The reason for the close agreement between the two methods is that the non-linearities in the exocytosis process involve only bi-molecular reactions. In this case the discrepancy between the two approaches is primarily determined by the size of correlations between reactant molecule number fluctuations rather than the fluctuation amplitudes. The small size of reactant correlations is in turn determined by the relationship between the rate of diffusion relative the rate of Ca2+ buffering and binding. Finally, I will show that several open question still remain in fully understanding the relationship between mass-action and stochastic FPT computation. This work is supported by NSF grant DMS-1517085.

Jose Pabon

Research Work Update - on the Hydrodynamics of Interacting Swimmers, Potential Flow Around Slender Bodies and Related Uniform Asymptotic Solutions.  

Alternate Title: Three Papers in Three and a Third Minutes Each.