Your search keyword '"Howard, Michael P."' showing total 32 results

1. Effects of Ligand vs. Linker on Phase Behavior and Mechanical Properties of Nanoparticle Gels

Author

Chen, Qizan, Devarajan, Dinesh Sundaravadivelu, Nikoubashman, Arash, Howard, Michael P., and Mittal, Jeetain

Subjects

Condensed Matter - Soft Condensed Matter, Condensed Matter - Materials Science

Abstract

Nanoparticle gels have attracted considerable attention due to their highly tunable properties. One strategy for producing nanoparticle gels involves utilizing strong local attractions between polymeric molecules, such as DNA hybridization or dynamic covalent chemistry, to form percolated nanoparticle networks. These molecules can be used in two distinct roles: as ``ligands'' with one end grafted to a nanoparticle or as ``linkers'' with both ends free. Here, we explore how these roles shape the phase behavior and mechanical properties of gel-like nanoparticle assemblies using coarse-grained simulations. We systematically vary the interaction strength and bending stiffness of both ligands and linkers. We find that phase separation can be limited to low nanoparticle volume fractions by making the ligands rigid, consistent with previous studies on linked nanoparticle gels. At fixed interaction strength and volume fraction, both ligand- and linker-mediated nanoparticle assemblies show similar mechanical responses to variations in bending stiffness. However, a comparison between the two association schemes reveals that the linked nanoparticles form rigid percolated networks that are less stretchable than the ligand-grafted gels, despite exhibiting similar tensile strength. We attribute these differences between ligands and linkers to the distinct structural arrangement of nanoparticles. Our findings highlight the potential to utilize different association schemes to tune specific mechanical properties.

Published

2024

2. relentless: Transparent, reproducible molecular dynamics simulations for optimization

Author

Sreenivasan, Adithya N, Petix, C. Levi, Sherman, Zachary M., and Howard, Michael P.

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Computational Physics

Abstract

relentless is an open-source Python package that enables the optimization of objective functions computed using molecular dynamics simulations. It has a high-level, extensible interface for model parametrization; setting up, running, and analyzing simulations natively in established software packages; and gradient-based optimization. We describe the design and implementation of relentless in the context of relative entropy minimization, and we demonstrate its abilities to design pairwise interactions between particles that form targeted structures. relentless aims to streamline the development of computational materials design methodologies and promote the transparency and reproducibility of complex workflows integrating molecular dynamics simulations., Comment: 13 pages, 6 figures

Published

2024

3. Evaluation of NoSQL in the Energy Marketplace with GraphQL Optimization

Author

Howard, Michael

Subjects

Computer Science - Databases

Abstract

The growing popularity of electric vehicles in the United States requires an ever-expanding infrastructure of commercial DC fast charging stations. The U.S. Department of Energy estimates 33,355 publicly available DC fast charging stations as of September 2023. Range anxiety is an important impediment to the adoption of electric vehicles and is even more relevant in underserved regions in the country. The peer-to-peer energy marketplace helps fill the demand by allowing private home and small business owners to rent their 240 Volt, level-2 charging facilities. The existing, publicly accessible outlets are wrapped with a Cloud-connected microcontroller managing security and charging sessions. These microcontrollers act as Edge devices communicating with a Cloud message broker, while both buyer and seller users interact with the framework via a web-based user interface. The database storage used by the marketplace framework is a key component in both the cost of development and the performance that contributes to the user experience. A traditional storage solution is the SQL database. However, difficulty in scaling across multiple nodes and cost of its server-based compute have resulted in a trend in the last 20 years towards other NoSQL, serverless approaches. In this study, we evaluate the NoSQL vs. SQL solutions through a comparison of Google Cloud Firestore and Cloud SQL MySQL offerings. The comparison pits Google's serverless, document-model, non-relational, NoSQL against the server-base, table-model, relational, SQL service. The evaluation is based on query latency, flexibility/scalability, and cost criteria. Through benchmarking and analysis of the architecture, we determine whether Firestore can support the energy marketplace storage needs and if the introduction of a GraphQL middleware layer can overcome its deficiencies.

Published

2024

4. Mesoscale simulations of diffusion and sedimentation in shape-anisotropic nanoparticle suspensions

Author

Wani, Yashraj M., Kovakas, Penelope Grace, Nikoubashman, Arash, and Howard, Michael P.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

We determine the long-time self-diffusion coefficient and sedimentation coefficient for suspensions of nanoparticles with anisotropic shapes (octahedra, cubes, tetrahedra, and spherocylinders) as a function of nanoparticle concentration using mesoscale simulations. We use a discrete particle model for the nanoparticles, and we account for solvent-mediated hydrodynamic interactions between nanoparticles using the multiparticle collision dynamics method. Our simulations are compared to theoretical predictions and experimental data from existing literature, demonstrating good agreement in the majority of cases. Further, we find that the self-diffusion coefficient of the regular polyhedral shapes can be estimated from that of a sphere whose diameter is average of their inscribed and circumscribed sphere diameters., Comment: 13 pages, 7 figures

Published

2024

5. ESP32: QEMU Emulation within a Docker Container

Author

Howard, Michael and Irvin, R. Bruce

Subjects

Computer Science - Operating Systems, F.2.2, I.2.7

Abstract

The ESP32 is a popular microcontroller from Espressif that can be used in many embedded applications. Robotic joints, smart car chargers, beer vat agitators and automated bread mixers are a few examples where this system-on-a-chip excels. It is cheap to buy and has a number of vendors providing low-cost development board kits that come with the microcontroller and many external connection points with peripherals. There is a large software ecosystem for the ESP32. Espressif maintains an SDK containing many C-language sample projects providing a starting point for a huge variety of software services and I/O needs. Third party projects provide additional sample code as well as support for other programming languages. For example, MicroPython is a mature project with sample code and officially supported by Espressif. The SDK provides tools to not just build an application but also merge a flash image, flash to the microcontroller and monitor the output. Is it possible to build the ESP32 load and emulate on another host OS? This paper explores the QEMU emulator and its ability to emulate the ethernet interface for the guest OS. Additionally, we look into the concept of containerizing the entire emulator and ESP32 load package such that a microcontroller flash image can successfully run with a one-step deployment of a Docker container., Comment: 7 pages and 9 figures

Published

2023

6. Multiscale modeling of solute diffusion in triblock copolymer membranes

Author

Cooper, Anthony J., Howard, Michael P., Kadulkar, Sanket, Zhao, David, Delaney, Kris T., Ganesan, Venkat, Truskett, Thomas M., and Fredrickson, Glenn H.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

We develop a multiscale simulation model for diffusion of solutes through porous triblock copolymer membranes. The approach combines two techniques: self-consistent field theory (SCFT) to predict the structure of the self-assembled, solvated membrane and on-lattice kinetic Monte Carlo (kMC) simulations to model diffusion of solutes. Solvation is simulated in SCFT by constraining the glassy membrane matrix while relaxing the brush-like membrane pore coating against the solvent. The kMC simulations capture the resulting solute spatial distribution and concentration-dependent local diffusivity in the polymer-coated pores; we parameterize the latter using particle-based simulations. We apply our approach to simulate solute diffusion through nonequilibrium morphologies of a model triblock copolymer, and we correlate diffusivity with structural descriptors of the morphologies. We also compare the model's predictions to alternative approaches based on simple lattice random walks and find our multiscale model to be more robust and systematic to parameterize. Our multiscale modeling approach is general and can be readily extended in the future to other chemistries, morphologies, and models for the local solute diffusivity and interactions with the membrane.

Published

2022

7. Dynamic density functional theory for drying colloidal suspensions: Comparison of hard-sphere free-energy functionals

Author

Kundu, Mayukh and Howard, Michael P.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

Dynamic density functional theory (DDFT) is a promising approach for predicting the structural evolution of a drying suspension containing one or more types of colloidal particles. The assumed free-energy functional is a key component of DDFT that dictates the thermodynamics of the model and, in turn, the density flux due to a concentration gradient. In this work, we compare several commonly used free-energy functionals for drying hard-sphere suspensions including local-density approximations based on the ideal-gas, virial, and Boubl\'{i}k-Mansoori-Carnahan-Starling-Leland (BMCSL) equations of state as well as a weighted-density approximation based on fundamental measure theory (FMT). To determine the accuracy of each functional, we model one- and two-component hard-sphere suspensions in a drying film with varied initial heights and compositions, and we compare the DDFT-predicted volume-fraction profiles to particle-based Brownian dynamics (BD) simulations. FMT accurately predicts the structure of the one-component suspensions even at high concentrations and when significant density gradients develop, but the virial and BMCSL equations of state provide reasonable approximations for smaller concentrations at a reduced computational cost. In the two-component suspensions, FMT and BMCSL are similar to each other but modestly overpredict the extent of stratification by size compared to BD simulations. This work provides helpful guidance for selecting thermodynamic models for soft materials in nonequilibrium processes such as solvent drying, solvent freezing, and sedimentation.

Published

2022

8. Cloud Computing -- Everything As A Service

Author

Howard, Michael

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Software Engineering

Abstract

Compute infrastructure hosted by a cloud provider allows an application to scale without limit. The application developer no longer needs to worry about the up-front investment in a server farm provisioned for a worst-case load scenario. However, managing cloud deployments requires a sophisticated framework that can autoscale the infrastructure and guarantee the up-time of running container images. This paper surveys existing research addressing the management and orchestration of cloud deployments as well as the modelling framework to abstract away the low-level details of the host infrastructure. We investigate blockchain distributed ledgers, quantum computing and Internet of Things application stacks to show how they can utilize cloud deployments.

Published

2022

9. Helm -- What It Can Do and Where Is It Going?

Author

Howard, Michael

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

Deploying an application into a Kubernetes cluster requires sending a manifest file to the cluster's control plane interface. This action is typically performed through a kubectl client which is configured and authorized to communicate with the control plane's Uniform Resource Locator (URL). An application typically requires many Kubernetes resources such as pods, deployments, secrets, service and volumes. Configuring each of these through manifest files requires complex scripting, especially when there are numerous resources needed. A solution to the complex management tasks is Helm. Helm provides both a tool and underlying framework that packages the necessary manifest files. These packages are deployed through a single step install command which abstracts all the underlying control plane interaction from the user. Similar to application installs through Debian's package manager dpkg, packages are shared through local and remote repositories and allow the user to easily install, update, delete or handle concurrent versions.

Published

2022

10. Terraform -- Automating Infrastructure as a Service

Author

Howard, Michael

Subjects

Computer Science - Software Engineering, Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

Developing a software service requires a strict software development life cycle and process. This process demands controlling all application code through source control management as well as a rigorous versioning and branching strategy. However, the platform and infrastructure also benefit from this rigor. Software services must be deployed to a target run time environment and provisioning that environment through manual user actions is tedious and error-prone. Provisioning manually also becomes prohibitive as the number of resources grow and spread globally over multiple regions. The answer is to apply the same rigor to provisioning the infrastructure as applied to developing the application software. Terraform provides a platform allowing infrastructure resources to be defined in code. This code not only allows the automation of the infrastructure provisioning but also allows for a strict development and review life cycle, same as the application software.

Published

2022

11. Diffusion and sedimentation in colloidal suspensions using multiparticle collision dynamics with a discrete particle model

Author

Wani, Yashraj M., Kovakas, Penelope Grace, Nikoubashman, Arash, and Howard, Michael P.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

We study self-diffusion and sedimentation in colloidal suspensions of nearly-hard spheres using the multiparticle collision dynamics simulation method for the solvent with a discrete mesh model for the colloidal particles (MD+MPCD). We cover colloid volume fractions from 0.01 to 0.40 and compare the MD+MPCD simulations to Brownian dynamics simulations with free-draining hydrodynamics (BD) as well as pairwise far-field hydrodynamics described using the Rotne--Prager--Yamakawa mobility tensor (BD+RPY). The dynamics in MD+MPCD suggest that the colloidal particles are only partially coupled to the solvent at short times. However, the long-time self-diffusion coefficient in MD+MPCD is comparable to that in BD and BD+RPY, and the sedimentation coefficient in MD+MPCD is in good agreement with that in BD+RPY, suggesting that MD+MPCD gives a reasonable description of the hydrodynamic interactions in colloidal suspensions. The discrete-particle MD+MPCD approach is convenient and readily extended to more complex shapes, and we determine the long-time self-diffusion coefficient in suspensions of nearly-hard cubes to demonstrate its generality., Comment: 13 pages, 8 figures

Published

2021

12. Effects of linker flexibility on phase behavior and structure of linked colloidal gels

Author

Howard, Michael P., Sherman, Zachary M., Sreenivasan, Adithya N, Valenzuela, Stephanie A., Anslyn, Eric V., Milliron, Delia J., and Truskett, Thomas M.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

Colloidal nanocrystal gels can be assembled using a difunctional "linker" molecule to mediate bonding between nanocrystals. The conditions for gelation and the structure of the gel are controlled macroscopically by the linker concentration and microscopically by the linker's molecular characteristics. Here, we demonstrate using a toy model for a colloid-linker mixture that linker flexibility plays a key role in determining both phase behavior and structure of the mixture. We fix the linker length and systematically vary its bending stiffness to span the flexible, semiflexible, and rigid regimes. At fixed linker concentration, flexible-linker and rigid-linker mixtures phase separate at low colloid volume fractions in agreement with predictions of first-order thermodynamic perturbation theory, but the semiflexible-linker mixtures do not. We correlate and attribute this qualitatively different behavior to undesirable "loop" linking motifs that are predicted to be more prevalent for linkers with end-to-end distances commensurate with the locations of chemical bonding sites on the colloids. Linker flexibility also influences the spacing between linked colloids, suggesting strategies to design gels with desired phase behavior, structure, and by extension, structure-dependent properties., Comment: 11 pages, 8 figures, supplementary material

Published

2020

13. Wertheim's thermodynamic perturbation theory with double-bond association and its application to colloid-linker mixtures

Author

Howard, Michael P., Sherman, Zachary M., Milliron, Delia J., and Truskett, Thomas M.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

We extend Wertheim's thermodynamic perturbation theory to derive the association free energy of a multicomponent mixture for which double bonds can form between any two pairs of the molecules' arbitrary number of bonding sites. This generalization reduces in limiting cases to prior theories that restrict double bonding to at most one pair of sites per molecule. We apply the new theory to an associating mixture of colloidal particles ("colloids") and flexible chain molecules ("linkers"). The linkers have two functional end groups, each of which may bond to one of several sites on the colloids. Due to their flexibility, a significant fraction of linkers can "loop" with both ends bonding to sites on the same colloid instead of bridging sites on different colloids. We use the theory to show that the fraction of linkers in loops depends sensitively on the linker end-to-end distance relative to the colloid bonding-site distance, which suggests strategies for mitigating the loop formation that may otherwise hinder linker-mediated colloidal assembly., Comment: 19 pages, 9 figures

Published

2020

14. Stratification of polymer mixtures in drying droplets: hydrodynamics and diffusion

Author

Howard, Michael P. and Nikoubashman, Arash

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

We study the evaporation-induced stratification of a mixture of short and long polymer chains in a drying droplet using molecular simulations. We systematically investigate the effects of hydrodynamic interactions (HI) on this process by comparing hybrid simulations accounting for HI between polymers through the multiparticle collision dynamics technique with free-draining Langevin dynamics simulations neglecting the same. We find that the dried supraparticle morphologies are homogeneous when HI are included but are stratified in core--shell structures (with the short polymers forming the shell) when HI are neglected. The simulation methodology unambiguously attributes this difference to the treatment of the solvent in the two models. We rationalize the presence (or absence) of stratification by measuring phenomenological multicomponent diffusion coefficients for the polymer mixtures. The diffusion coefficients show the importance of not only solvent backflow but also HI between polymers in controlling the dried supraparticle morphology., Comment: 13 pages, 9 figures

Published

2020

15. Inverse methods for design of soft materials

Author

Sherman, Zachary M., Howard, Michael P., Lindquist, Beth A., Jadrich, Ryan B., and Truskett, Thomas M.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

Functional soft materials, comprising colloidal and molecular building blocks that self-organize into complex structures as a result of their tunable interactions, enable a wide array of technological applications. Inverse methods provide systematic means for navigating their inherently high-dimensional design spaces to create materials with targeted properties. While multiple physically motivated inverse strategies have been successfully implemented in silico, their translation to guiding experimental materials discovery has thus far been limited to a handful of proof-of-concept studies. In this Perspective, we discuss recent advances in inverse methods for design of soft materials that address two challenges: (1) methodological limitations that prevent such approaches from satisfying design constraints and (2) computational challenges that limit the size and complexity of systems that can be addressed. Strategies that leverage machine learning have proven particularly effective, including methods to discover order parameters that characterize complex structural motifs and schemes to efficiently compute macroscopic properties from the underlying structure. We also highlight promising opportunities to improve the experimental realizability of materials designed computationally, including discovery of materials with functionality at multiple thermodynamic states, design of externally directed assembly protocols that are simple to implement in experiments, and strategies to improve the accuracy and computational efficiency of experimentally relevant models.

Published

2020

16. Universal Gelation of Metal Oxide Nanocrystals via Depletion Attractions

Author

Cabezas, Camila A. Saez, Sherman, Zachary M., Howard, Michael P., Dominguez, Manuel N., Cho, Shin Hum, Ong, Gary K., Green, Allison, Truskett, Thomas M., and Milliron, Delia J.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

Nanocrystal gelation provides a powerful framework to translate nanoscale properties into bulk materials and to engineer emergent properties through the assembled microstructure. However, many established gelation strategies rely on chemical reactions and specific interactions, e.g., stabilizing ligands or ions on the surface of the nanocrystals, and are therefore not easily transferrable. Here, we report a general gelation strategy via non-specific and purely entropic depletion attractions applied to three types of metal oxide nanocrystals. The gelation thresholds of two compositionally distinct spherical nanocrystals agree quantitatively, demonstrating the adaptability of the approach for different chemistries. Consistent with theoretical phase behavior predictions, nanocrystal cubes form gels at a lower polymer concentration than nanocrystal spheres, allowing shape to serve as a handle to control gelation. These results suggest that the fundamental underpinnings of depletion-driven assembly, traditionally associated with larger colloidal particles, are also applicable at the nanoscale.

Published

2020

17. Stability of force-driven shear flows in nonequilibrium molecular simulations with periodic boundaries

Author

Howard, Michael P., Statt, Antonia, Stone, Howard A., and Truskett, Thomas M.

Subjects

Physics - Fluid Dynamics

Abstract

We analyze the hydrodynamic stability of force-driven parallel shear flows in nonequilibrium molecular simulations with three-dimensional periodic boundary conditions. We show that flows simulated in this way can be linearly unstable, and we derive an expression for the critical Reynolds number as a function of the geometric aspect ratio of the simulation domain. Approximate periodic extensions of Couette and Poiseuille flows are unstable at Reynolds numbers two orders of magnitude smaller than their aperiodic equivalents because the periodic boundaries impose fundamentally different constraints on the flow. This instability has important implications for simulating shear rheology and for designing nonequilibrium simulation methods that are compatible with periodic boundary conditions., Comment: 10 pages, 6 figures

Published

2019

18. Structure and phase behavior of polymer-linked colloidal gels

Author

Howard, Michael P., Jadrich, Ryan B., Lindquist, Beth A., Khabaz, Fardin, Bonnecaze, Roger T., Milliron, Delia J., and Truskett, Thomas M.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

Low-density "equilibrium" gels that consist of a percolated, kinetically arrested network of colloidal particles and are resilient to aging can be fabricated by restricting the number of effective bonds that form between the colloids. Valence-restricted patchy particles have long served as one archetypal example of such materials, but equilibrium gels can also be realized through a synthetically simpler and scalable strategy that introduces a secondary linker, such as a small ditopic molecule, to mediate the bonds between the colloids. Here, we consider the case where the ditopic linker molecules are low-molecular-weight polymers and demonstrate using a model colloid-polymer mixture how macroscopic properties such as the phase behavior as well as the microstructure of the gel can be designed through the polymer molecular weight and concentration. The low-density window for equilibrium gel formation is favorably expanded using longer linkers, while necessarily increasing the spacing between all colloids. However, we show that blends of linkers with different sizes enable wider variation in microstructure for a given target phase behavior. Our computational study suggests a robust and tunable strategy for the experimental realization of equilibrium colloidal gels., Comment: 11 pages, 8 figures

Published

2019

19. The Role of Pressure in Inverse Design for Assembly

Author

Lindquist, Beth A., Jadrich, Ryan B., Howard, Michael P., and Truskett, Thomas M.

Subjects

Condensed Matter - Statistical Mechanics, Condensed Matter - Soft Condensed Matter

Abstract

Isotropic pairwise interactions that promote the self assembly of complex particle morphologies have been discovered by inverse design strategies derived from the molecular coarse-graining literature. While such approaches provide an avenue to reproduce structural correlations, thermodynamic quantities such as the pressure have typically not been considered in self-assembly applications. In this work, we demonstrate that relative entropy optimization can be used to discover potentials that self-assemble into targeted cluster morphologies with a prescribed pressure when the iterative simulations are performed in the isothermal-isobaric ensemble. By tuning the pressure in the optimization, we generate a family of simple pair potentials that all self-assemble the same structure. Selecting an appropriate simulation ensemble to control the thermodynamic properties of interest is a general design strategy that could also be used to discover interaction potentials that self-assemble structures having, for example, a specified chemical potential., Comment: 29 pages, 8 figures

Published

2019

20. Crack formation and self-closing in shrinkable, granular packings

Author

Cho, H. Jeremy, Lu, Nancy B., Howard, Michael P., Adams, Rebekah A., and Datta, Sujit S.

Subjects

Condensed Matter - Soft Condensed Matter, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Materials Science, Condensed Matter - Statistical Mechanics, Physics - Fluid Dynamics

Abstract

Many clays, soils, biological tissues, foods, and coatings are shrinkable, granular materials: they are composed of packed, hydrated grains that shrink when dried. In many cases, these packings crack during drying, critically hindering applications. However, while cracking has been widely studied for bulk gels and packings of non-shrinkable grains, little is known about how packings of shrinkable grains crack. Here, we elucidate how grain shrinkage alters cracking during drying. Using experiments with model shrinkable hydrogel beads, we show that differential shrinkage can dramatically alter crack evolution during drying---in some cases, even causing cracks to spontaneously "self-close". In other cases, packings shrink without cracking or crack irreversibly. We developed both granular and continuum models to quantify the interplay between grain shrinkage, poromechanics, packing size, drying rate, capillarity, and substrate friction on cracking. Guided by the theory, we also found that cracking can be completely altered by varying the spatial profile of drying. Our work elucidates the rich physics underlying cracking in shrinkable, granular packings, and yields new strategies for controlling crack evolution., Comment: In press

Published

2019

21. Modeling hydrodynamic interactions in soft materials with multiparticle collision dynamics

Author

Howard, Michael P., Nikoubashman, Arash, and Palmer, Jeremy C.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

Multiparticle collision dynamics (MPCD) is a flexible and robust mesoscale computational technique for simulating solvent-mediated hydrodynamic interactions in soft materials. Here, we provide a critical overview of the MPCD method and summarize its current strengths and limitations. The capabilities of the method are highlighted by reviewing its recent applications to simulate diverse phenomena, ranging from the flow of complex fluids and thermo-osmotic transport to bacterial swimming and active particle self-assembly. We also discuss outstanding challenges and emerging methodological developments that are expected to greatly expand the applicability of MPCD to other systems of technological importance., Comment: 3 figures

Published

2019

22. Quantized bounding volume hierarchies for neighbor search in molecular simulations on graphics processing units

Author

Howard, Michael P., Statt, Antonia, Madutsa, Felix, Truskett, Thomas M., and Panagiotopoulos, Athanassios Z.

Subjects

Physics - Computational Physics

Abstract

We present an algorithm for neighbor search in molecular simulations on graphics processing units (GPUs) based on bounding volume hierarchies (BVHs). The BVH is compressed into a low-precision, quantized representation to increase the BVH traversal speed compared to a previous implementation. We find that neighbor search using the quantized BVH is roughly two to four times faster than current state-of-the-art methods using uniform grids (cell lists) for a suite of benchmarks for common molecular simulation models. Based on the benchmark results, we recommend using the BVH instead of a single cell list for neighbor list generation in molecular simulations on GPUs., Comment: 28 pages, 8 figures

Published

2019

23. Cross-stream migration of a Brownian droplet in a polymer solution under Poiseuille flow

Author

Howard, Michael P., Truskett, Thomas M., and Nikoubashman, Arash

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Fluid Dynamics

Abstract

The migration of a Brownian fluid droplet in a parallel-plate microchannel was investigated using dissipative particle dynamics computer simulations. In a Newtonian solvent, the droplet migrated toward the channel walls due to inertial effects at the studied flow conditions, in agreement with theoretical predictions and recent simulations. However, the droplet focused onto the channel centerline when polymer chains were added to the solvent. Focusing was typically enhanced for longer polymers and higher polymer concentrations with a nontrivial flow-rate dependence due to droplet and polymer deformability. Brownian motion caused the droplet position to fluctuate with a distribution that primarily depended on the balance between inertial lift forces pushing the droplet outward and elastic forces from the polymers driving it inward. The droplet shape was controlled by the local shear rate, and so its average shape depended on the droplet distribution., Comment: 10 pages, 9 figures

Published

2018

24. Unexpected secondary flows in reverse nonequilibrium shear flow simulations

Author

Statt, Antonia, Howard, Michael P., and Panagiotopoulos, Athanassios Z.

Subjects

Physics - Fluid Dynamics, Physics - Computational Physics

Abstract

We simulated two particle-based fluid models, namely multiparticle collision dynamics and dissipative particle dynamics, under shear using reverse nonequilibrium simulations (RNES). In cubic periodic simulation boxes, the expected shear flow profile for a Newtonian fluid developed, consistent with the fluid viscosities. However, unexpected secondary flows along the shear gradient formed when the simulation box was elongated in the flow direction. The standard shear flow profile was obtained when the simulation box was longer in the shear-gradient dimension than the flow dimension, while the secondary flows were always present when the flow dimension was at least 25% larger than the shear-gradient dimension. The secondary flows satisfy the boundary conditions imposed by the RNES and have a lower rate of viscous dissipation in the fluid than the corresponding unidirectional flows. This work highlights a previously unappreciated limitation of RNES for generating shear flow in simulation boxes that are elongated in the flow dimension, an important consideration when applying RNES to complex fluids like polymer solutions.

Published

2018

25. Influence of hydrodynamic interactions on stratification in drying mixtures

Author

Statt, Antonia, Howard, Michael P., and Panagiotopoulos, Athanassios Z.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

Nonequilibrium molecular dynamics simulations are used to investigate the influence of hydrodynamic interactions on vertical segregation (stratification) in drying mixtures of long and short polymer chains. In agreement with previous computer simulations and theoretical modeling, the short polymers stratify on top of the long polymers at the top of the drying film when hydrodynamic interactions between polymers are neglected. However, no stratification occurs at the same drying conditions when hydrodynamic interactions are incorporated through an explicit solvent model. Our analysis demonstrates that models lacking hydrodynamic interactions do not faithfully represent stratification in drying mixtures, in agreement with recent analysis of an idealized model for diffusiophoresis, and must be incorporated into such models in future.

Published

2018

26. Efficient mesoscale hydrodynamics: multiparticle collision dynamics with massively parallel GPU acceleration

Author

Howard, Michael P., Panagiotopoulos, Athanassios Z., and Nikoubashman, Arash

Subjects

Condensed Matter - Soft Condensed Matter, Physics - Computational Physics

Abstract

We present an efficient open-source implementation of the multiparticle collision dynamics (MPCD) algorithm that scales to run on hundreds of graphics processing units (GPUs). We especially focus on optimizations for modern GPU architectures and communication patterns between multiple GPUs. We show that a mixed-precision computing model can improve performance compared to a fully double-precision model while still providing good numerical accuracy. We report weak and strong scaling benchmarks of a reference MPCD solvent and a benchmark of a polymer solution with research-relevant interactions and system size. Our MPCD software enables simulations of mesoscale hydrodynamics at length and time scales that would be otherwise challenging or impossible to access.

Published

2018

27. Coupling of nanoparticle dynamics to polymer center-of-mass motion in semidilute polymer solutions

Author

Chen, Renjie, Poling-Skutvik, Ryan, Nikoubashman, Arash, Howard, Michael P., Conrad, Jacinta C., and Palmer, Jeremy C.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

We investigate the dynamics of nanoparticles in semidilute polymer solutions when the nanoparticles are comparably sized to the polymer coils using explicit- and implicit-solvent simulation methods. The nanoparticle dynamics are subdiffusive on short time scales before transitioning to diffusive motion on long time scales. The long-time diffusivities scale according to theoretical predictions based on full dynamic coupling to the polymer segmental relaxations. In agreement with our recent experiments, however, we observe that the nanoparticle subdiffusive exponents are significantly larger than predicted by the coupling theory over a broad range of polymer concentrations. We attribute this discrepancy in the subdiffusive regime to the presence of an additional coupling mechanism between the nanoparticle dynamics and the polymer center-of-mass motion, which differs from the polymer relaxations that control the long-time diffusion. This coupling is retained even in the absence of many-body hydrodynamic interactions when the long-time dynamics of the colloids and polymers are matched.

Published

2017

28. Artificial Intelligence Based Malware Analysis

Author

Pfeffer, Avi, Ruttenberg, Brian, Kellogg, Lee, Howard, Michael, Call, Catherine, O'Connor, Alison, Takata, Glenn, Reilly, Scott Neal, Patten, Terry, Taylor, Jason, Hall, Robert, Lakhotia, Arun, Miles, Craig, Scofield, Dan, and Frank, Jared

Subjects

Computer Science - Cryptography and Security, Computer Science - Artificial Intelligence

Abstract

Artificial intelligence methods have often been applied to perform specific functions or tasks in the cyber-defense realm. However, as adversary methods become more complex and difficult to divine, piecemeal efforts to understand cyber-attacks, and malware-based attacks in particular, are not providing sufficient means for malware analysts to understand the past, present and future characteristics of malware. In this paper, we present the Malware Analysis and Attributed using Genetic Information (MAAGI) system. The underlying idea behind the MAAGI system is that there are strong similarities between malware behavior and biological organism behavior, and applying biologically inspired methods to corpora of malware can help analysts better understand the ecosystem of malware attacks. Due to the sophistication of the malware and the analysis, the MAAGI system relies heavily on artificial intelligence techniques to provide this capability. It has already yielded promising results over its development life, and will hopefully inspire more integration between the artificial intelligence and cyber--defense communities.

Published

2017

29. Lazy Factored Inference for Functional Probabilistic Programming

Author

Pfeffer, Avi, Ruttenberg, Brian, Sliva, Amy, Howard, Michael, and Takata, Glenn

Subjects

Computer Science - Artificial Intelligence

Abstract

Probabilistic programming provides the means to represent and reason about complex probabilistic models using programming language constructs. Even simple probabilistic programs can produce models with infinitely many variables. Factored inference algorithms are widely used for probabilistic graphical models, but cannot be applied to these programs because all the variables and factors have to be enumerated. In this paper, we present a new inference framework, lazy factored inference (LFI), that enables factored algorithms to be used for models with infinitely many variables. LFI expands the model to a bounded depth and uses the structure of the program to precisely quantify the effect of the unexpanded part of the model, producing lower and upper bounds to the probability of the query.

Published

2015

30. Final Report on the Study of the Impact of the Statewide Systemic Initiatives. Lessons Learned about Designing, Implementing, and Evaluating Statewide Systemic Reform. WCER Working Paper No. 2003-12

Author

Wisconsin Center for Education Research, Madison., Heck, Daniel J., Weiss, Iris R., Boyd, Sally E., Howard, Michael N., and Supovitz, Jonathan A.

Abstract

This document represents the first of two volumes presented in "Study of the Impact of the Statewide Systemic Initiatives Program" (Norman L. Webb and Iris R. Weiss). In an effort to evaluate the impact of the Statewide Systemic Initiatives (SSIs) on student achievement and the lessons that could be learned from the National Science Foundation's effort to reform mathematics and science education on a statewide basis, research studies identified the technical strategies, the political strategies, and the interactions with funders that were critical factors in the attempt to effect significant change in student learning over large populations. Documents were received on 21 of the 26 SSIs. More intensive data were collected via telephone interviews of key personnel in seven of these states and during site visits in six other states. Among a number of lessons learned were the following: It was vital to incorporate enough flexibility within the design so that information produced by research, evaluation, and monitoring could be effectively used (technical lesson); the creation of partnerships with policy organizations significantly advanced policy work (political lesson); and, SSI leaders and funders needed to develop a shared, in-depth understanding of the reform strategies as these fit the local context (interaction with funders). The following are appended: (1) SRI International Evaluation Reports; (2) Abt Associates Inc. Monitoring Reports; (3) Coding Scheme: Chronology and Components; (4) Coding Scheme: Strategic Planning, Decision-Making, and Thinking; (5) Coding Scheme: Key Challenges; (6) Interview Protocol for Telephone Interviews and Site Visits; (7) Case Report: Arkansas Statewide Systemic Initiative; (8) Case Report: Maine Statewide Systemic Initiative; (9) Case Report: Michigan Statewide Systemic Initiative; (10) Case Report: Nebraska Statewide Systemic Initiative; (11) Case Report: Puerto Rico Statewide Systemic Initiative; and (12) Case Report: Vermont Statewide Systemic Initiative. [For Volume II of this report, see ED497577.]

Published

2003

31. Setting the Foundation for Reform: The Work of the Rural Systemic Initiatives. An Executive Summary of Conference Proceedings.

Author

Inverness Research Associates, CA., Heenan, Barbara, St. John, Mark, Broun, Samantha, Howard, Michael, and Becerra, Ana

Abstract

A conference brought together the leaders of the 11 projects funded by the National Science Foundation's Rural Systemic Initiative (RSI) to reflect upon their efforts to improve mathematics and science education in poor rural communities. A variety of themes emerged. The RSI projects serve small, rural communities suffering from decades of oppression, exploitation, and chronic poverty. Rural communities are ambivalent toward education and wary of "outside" efforts to improve education. RSIs have made progress in setting foundations for reform by helping local communities understand the need for improved educational opportunities, particularly in mathematics and science; developing local leaders committed to reforming mathematics and science education; helping these local leaders work with each other and with state and regional resources; and implementing new curricula, professional development offerings, and evaluation processes that improve the quality of mathematics and science programs. Because of the nature and depth of the challenges facing chronically poor, rural communities, the work done by the RSIs may appear slow, but an essential prerequisite to further mathematics and science reform is community development work. Assessment of RSIs should therefore focus not on student achievement, but on the degree to which the capacity of the community to initiate and sustain ongoing reform is enhanced. Appendices present information about the conference, case studies of four matureRSI projects, and a history of the RSI initiatives. (TD)

Published

2001

32. SCIS-II and the Elementary Teacher: A Program Analysis.

Author

Atwood, Ronald K. and Howard, Michael N.

Abstract

A significant alternative to the traditional text-based approach to elementary science has been represented by the Science Curriculum Improvement Study (SCIS). Although the literature documents the process of the investigative approach, greater utilization of available programs and support from teachers are not evidenced. This investigation was devised to determine teacher perceptions and their relationships to this concern. These questions were addressed: (1) "To what extent are teacher variables, such as grade level, years of experience, and frequency of scheduling science time, related to teacher evaluation of the SCIS-II program?" (2) "How do teachers perceive the barriers and support systems that exist in their district's elementary science program?" (3) "What student outcomes do teachers see as significant results of the SCIS-II program? Are these perceptions related to teachers' degree of positive attitude about the program? Are they consistent with the body of research? and (4) "What specific concepts, materials, activities, etc., do teachers find to be problems in the present program, and what changes do they feel might alleviate the problems?" It was concluded that teachers in grades 3-6 perceived more barriers to effective instruction and experienced greater problems with management, materials, and equipment during activities than their colleagues in the lower grades. (RT)

Published

1989