1,192 results on '"Daniels, Karen"'
Search Results
2. Ex-Attorney For Stormy Daniels & Karen McDougal Resumes Testimony; Police & Protesters Confront Each Other At UNC Chapel Hill. Aired 2:30-3p ET
- Subjects
Attorneys -- Demonstrations and protests ,General interest ,News, opinion and commentary ,University of North Carolina at Chapel Hill -- Demonstrations and protests - Abstract
[14:30:00] ERIN BURNETT, CNN HOST: Marc Lotter is a former special assistant to President Trump, who also served as Trump's 2020 director of strategic communications. And he joins me now. [...]
- Published
- 2024
3. Judge Fines Trump $9K For Violating Gag Order Nine Times; Ex- Attorney For Stormy Daniels & Karen McDougal Testifies; Trump Rails Against Gag Order And Hush Money Trial. Aired 4-5p ET
- Subjects
National Enquirer (Periodical) ,Attorneys ,General interest ,News, opinion and commentary ,Truth Social (Online social network) - Abstract
[16:00:00] WOLF BLITZER, CNN HOST: Meanwhile, Trump or rather someone working on his behalf, just posted on Truth Social blasting the gag order and the judge in the trial this [...]
- Published
- 2024
4. Prosecutors Call Employee For Court Reporting Company To Testify In Trump Hush Money Trial; Prosecutors Play Clip Of Trump Deposition In E. Jean Carroll Case; Prosecutors Play Clip Of Trump Being Asked About 'Access Hollywood' Tape; Now: Ex-Attorney For Stormy Daniels & Karen McDougal Testifying. Aired 12-12:30p ET
- Subjects
Access Hollywood (Television program) ,Libel and slander ,Public prosecutors ,Ex-presidents ,General interest ,News, opinion and commentary - Abstract
[12:00:00] JAKE TAPPER, CNN HOST & CHIEF WASHINGTON CORRESPONDENT: Welcome back to CNN special live coverage. The former president's eyes are reportedly closed again as he listens to testimony from [...]
- Published
- 2024
5. Now: Ex-Attorney For Stormy Daniels & Karen McDougal Testifying; Now: Ex-Attorney For Karen McDougal Testifies Former Playmate Told Him Trump Relationship Was 'Sexual In Nature'. Aired 12:30-1p ET
- Subjects
ABC News Inc. ,National Enquirer (Periodical) ,General interest ,News, opinion and commentary - Abstract
[12:30:00] BILL BRENNAN, FORMER TRUMP PAYROLL CORP. ATTORNEY: -- break your legs, and he was acquitted. If the defense creates reasonable doubt that this was for political purposes, it's a [...]
- Published
- 2024
6. Now: Longtime Trump Asst, Ex-SR. VP Of Trump Org Testifies; Trump's Longtime Assistant Testifies That Two Of The Contacts She maintained Info For Were Stormy Daniels & Karen McDougal; Judge Hasn't Ruled Yet Whether Trump Has Violated Gag Order; Set To Hear Four More Allegations Thursday. Aired 3-3:30p ET
- Subjects
General interest ,News, opinion and commentary - Abstract
(COMMERCIAL BREAK) [15:00:13] WOLF BLITZER, CNN HOST: We're tracking the very fast-moving updates in the unprecedented hush money trial of the former President Donald Trump. I'm Wolf Blitzer here in [...]
- Published
- 2024
7. Particle scale anisotropy controls bulk properties in sheared granular materials
- Author
-
Lee, Carmen L., Bililign, Ephraim, Azéma, Emilien, and Daniels, Karen E.
- Subjects
Condensed Matter - Soft Condensed Matter - Abstract
The bulk dynamics of dense granular materials arise through a combination of particle-scale and mesoscale effects. Theoretical and numerical studies have shown that collective effects are created by particle-scale anisotropic structures such as grain connectivity (fabric), force transmission, and frictional mobilization, all of which influence bulk properties like bulk friction and the stress tensor through the Stress-Force-Fabric (SFF) relationship. To date, establishing the relevance of these effects to laboratory systems has remained elusive due to the challenge of measuring both normal and frictional contact forces at the particle scale. In this study, we perform experiments on a sheared photoelastic granular system in an quasi-2D annular (Couette) cell. During these experiments, we measure particle locations, contacts, and normal and frictional forces vectors during loading. We reconstruct the angular distributions of the contact and force vectors, and extract the corresponding emergent anisotropies for each of these metrics. Finally, we show that the SFF relation quantitatively predicts the relationship between particle scale anisotropies, the stress tensor components, and the bulk friction coefficient, capturing even transient behaviors. As such, this method shows promise for application to other dense particulate systems where fabric anisotropy can provide a useful measure of bulk friction., Comment: 5 pages, 3 figures
- Published
- 2024
8. Interfacial Tension Hysteresis of Eutectic Gallium-Indium
- Author
-
Hillaire, Keith D., Nithyanandam, Praneshnandan, Song, Minyung, Nadimi, Sahar Rashid, Kiani, Abolfazl, Dickey, Michael D., and Daniels, Karen E.
- Subjects
Condensed Matter - Materials Science ,Physics - Applied Physics - Abstract
When in a pristine state, gallium and its alloys have the largest interfacial tensions of any liquid at room temperature. Nonetheless, applying as little as 0.8 V of electric potential across eutectic gallium indium (EGaIn) placed within aqueous NaOH (or other electrolyte) solution will cause the metal to behave as if its interfacial tension is near zero. The mechanism behind this phenomenon has remained poorly understood because NaOH dissolves the oxide species, making it difficult to directly measure the concentration, thickness, or chemical composition of the film that forms at the interface. In addition, the oxide layers formed are atomically-thin. Here, we present a suite of techniques which allow us to simultaneously measure both electrical and interfacial properties as a function of applied electric potential, allowing for new insights into the mechanisms which cause the dramatic decrease in interfacial tension. A key discovery from this work is that the interfacial tension displays hysteresis while lowering the applied potential. We combine these observations with electrochemical impedance spectroscopy to evaluate how these changes in interfacial tension arise from chemical, electrical, and mechanical changes on the interface, and close with ideas for how to build a free energy model to predict these changes from first principles.
- Published
- 2023
9. The Onset Acceleration for Surfactant Covered Faraday Waves
- Author
-
Strickland, Stephen L., Daniels, Karen E., and Shearer, Michael
- Subjects
Physics - Fluid Dynamics - Abstract
Faraday waves are gravity-capillary waves that emerge on the surface of a vertically vibrated fluid when the energy injected via vibration exceeds the energy lost due to viscous dissipation. Because this dissipation primarily occurs in the free surface boundary layer, their emergence is particularly sensitive to free surface properties including the surface tension, elasticity, and viscosity of surfactants present at the free surface. We study this sensitivity by considering a Newtonian fluid bath covered by an insoluble surfactant subject to vertical vibrations which produce sub-harmonic Faraday waves. By assuming a finite-depth, infinite-breadth, low-viscosity bulk fluid and accounting for surface tension, Marangoni, and Boussinesq effects, we derive an expression for the onset acceleration up to second order in the expansion parameter $\Upsilon = \sqrt{\tfrac{1}{\mathcal{R}e}}$. We recover the results of previous numerical investigations, but only by modifying the Marangoni and Boussinesq numbers to account for the low-viscosity limit. The analytic expression allows us to consider a range of parameters not previously studied, including a wide variety of fluid depths and driving frequencies. In addition, we uncover regions of parameter space for which our model predicts that the addition of surfactant would lower, rather than elevate, the onset acceleration. We discuss the possible use of this model in developing a surface viscometer for surfactant monolayers., Comment: 31 pages , 12 figures , 3 tables , 3 appendices
- Published
- 2023
10. Soft matter physics of the ground beneath our feet
- Author
-
Voigtländer, Anne, Houssais, Morgane, Bacik, Karol A., Bourg, Ian C., Burton, Justin C., Daniels, Karen E., Datta, Sujit S., Del Gado, Emanuela, Deshpande, Nakul S., Devauchelle, Olivier, Ferdowsi, Behrooz, Glade, Rachel, Goehring, Lucas, Hewitt, Ian J., Jerolmack, Douglas, Juanes, Ruben, Kudrolli, Arshad, Lai, Ching-Yao, Li, Wei, Masteller, Claire, Nissanka, Kavinda, Rubin, Allan M., Stone, Howard A., Suckale, Jenny, Vriend, Nathalie M., Wettlaufer, John S., and Yang, Judy Q.
- Subjects
Condensed Matter - Soft Condensed Matter ,Physics - Geophysics - Abstract
Inspired by presentations by the authors during a workshop organized at the Princeton Center for Theoretical Science (PCTS) in January 2022, we present a perspective on some of the outstanding questions related to the "physics of the ground beneath our feet." These identified challenges are intrinsically shared with the field of Soft Matter but also have unique aspects when the natural environment is studied., Comment: Perspective Paper, 30 pages, 15 figures
- Published
- 2023
11. Community detection forecasts material failure in a sheared granular material
- Author
-
Fazelpour, Farnaz, Desai, Vrinda D., and Daniels, Karen E.
- Subjects
Condensed Matter - Soft Condensed Matter - Abstract
The stability of a granular material is a collective phenomenon controlled by individual particles through their interactions. Forecasting when granular materials will undergo an abrupt failure is an ongoing challenge due to the intricate interactions between particles. Here, we report experiments on photoelastic disks undergoing intermittent stick-slip dynamics in a quasi-2D annular shear apparatus, with the evolving network of contact forces made visible via polarized light. We characterize the system by interpreting the interparticle forces as a multilayer network, and apply GenLouvin community detection to identify strongly correlated groups of particles. We observe that the community structure becomes increasingly volatile as the material approaches failure, and that this volatility provides a forecast that precedes what is detectable by considering the forces alone. We additionally observe that both weak and strong forces contribute to the strength of this forecast. These findings provide a new approach to detect patterns of causality and forecast impending failures.
- Published
- 2023
12. Effects of reduced gravity on the granular fluid-solid transition: underexplored forces can dominate soft matter behaviors
- Author
-
Sánchez, Paul, Daniels, Karen E., Jaeger, Heinrich, and Shinbrot, Troy
- Subjects
Condensed Matter - Soft Condensed Matter - Abstract
Granular media are soft matter systems that exhibit some of the extreme behavior of complex fluids. Understanding of the natural formation of planetary bodies, landing on and exploring them, future engineering of structures beyond Earth and planetary defense all hinge on the ability to predict the complex mechanical behavior of granular matter. As we understand them, these behaviors are linked to the granular fluid to solid transition. In this white paper, we describe issues that emerge for granular systems under reduced gravity and their implications for basic science and space exploration. (Topical White Paper submitted to the NASA Biological and Physical Sciences in Space Decadal Survey 2023-2032), Comment: arXiv admin note: text overlap with arXiv:1002.2478
- Published
- 2023
13. Forecasting landslides using community detection on geophysical satellite data
- Author
-
Desai, Vrinda D, Fazelpour, Farnaz, Handwerger, Alexander L, and Daniels, Karen E
- Subjects
Geomatic Engineering ,Engineering ,Clinical Research ,Mathematical sciences ,Physical sciences - Abstract
As a result of extreme weather conditions, such as heavy precipitation, natural hillslopes can fail dramatically; these slope failures can occur on a dry day, due to time lags between rainfall and pore-water pressure change at depth, or even after days to years of slow motion. While the prefailure deformation is sometimes apparent in retrospect, it remains challenging to predict the sudden transition from gradual deformation (creep) to runaway failure. We use a network science method-multilayer modularity optimization-to investigate the spatiotemporal patterns of deformation in a region near the 2017 Mud Creek, California landslide. We transform satellite radar data from the study site into a spatially embedded network in which the nodes are patches of ground and the edges connect the nearest neighbors, with a series of layers representing consecutive transits of the satellite. Each edge is weighted by the product of the local slope (susceptibility to failure) measured from a digital elevation model and ground surface deformation (current rheological state) from interferometric synthetic aperture radar (InSAR). We use multilayer modularity optimization to identify strongly connected clusters of nodes (communities) and are able to identify both the location of Mud Creek and nearby creeping landslides which have not yet failed. We develop a metric, i.e., community persistence, to quantify patterns of ground deformation leading up to failure, and find that this metric increased from a baseline value in the weeks leading up to Mud Creek's failure. These methods hold promise as a technique for highlighting regions at risk of catastrophic failure.
- Published
- 2023
14. Forecasting landslides using community detection on geophysical satellite data
- Author
-
Desai, Vrinda, Fazelpour, Farnaz, Handwerger, Alexander L., and Daniels, Karen E.
- Subjects
Condensed Matter - Disordered Systems and Neural Networks ,Physics - Geophysics - Abstract
As a result of extreme weather conditions, such as heavy precipitation, natural hillslopes can fail dramatically; these slope failures can occur on a dry day due to time lags between rainfall and pore-water pressure change at depth, or even after days to years of slow-motion. While the pre-failure deformation is sometimes apparent in retrospect, it remains challenging to predict the sudden transition from gradual deformation (creep) to runaway failure. We use a network science method -- multilayer modularity optimization -- to investigate the spatiotemporal patterns of deformation in a region near the 2017 Mud Creek, California landslide. We transform satellite radar data from the study site into a spatially-embedded network in which the nodes are patches of ground and the edges connect the nearest neighbors, with a series of layers representing consecutive transits of the satellite. Each edge is weighted by the product of the local slope (susceptibility to failure) measured from a digital elevation model and ground surface deformation (current rheological state) from interferometric synthetic aperture radar (InSAR). We use multilayer modularity optimization to identify strongly-connected clusters of nodes (communities) and are able to identify both the location of Mud Creek and nearby creeping landslides which have not yet failed. We develop a metric, community persistence, to quantify patterns of ground deformation leading up to failure, and find that this metric increases from a baseline value in the weeks leading up to Mud Creek's failure. These methods promise as a technique for highlighting regions at risk of catastrophic failure., Comment: 10 pages, 7 figures
- Published
- 2022
- Full Text
- View/download PDF
15. Controlling rheology via boundary conditions in dense granular flows
- Author
-
Fazelpour, Farnaz and Daniels, Karen E.
- Subjects
Condensed Matter - Soft Condensed Matter - Abstract
Boundary shape, particularly roughness, strongly controls the amount of wall slip in dense granular flows. In this paper, we aim to quantify and understand which aspects of a dense granular flow are controlled by the boundary condition, and to incorporate these observations into a cooperative nonlocal model characterizing slow granular flows. To examine the influence of boundary properties, we perform experiments on a quasi-2D annular shear cell with a rotating inner wall and a fixed outer wall; the later is selected from among 6 walls with various roughness, local concavity, and compliance. We find that we can successfully capture the full flow profile using a single set of empirically determined model parameters, with only the wall slip velocity set by direct observation. Through the use of photoelastic particles, we observe how the internal stresses fluctuate more for rougher boundaries, corresponding to lower wall slip, and connect this observation to the propagation of nonlocal effects originating at the wall.
- Published
- 2022
16. Photoelastic Stress Response of Complex 3D-Printed Particle Shapes
- Author
-
Amini, Negin, Tuohey, Josh, Long, John M., Zhang, Jun, Morton, David A. V., Daniels, Karen, Fazelpour, Farnaz, and Hapgood, Karen P.
- Subjects
Condensed Matter - Soft Condensed Matter ,Physics - Applied Physics - Abstract
While stress visualization within 3-dimensional particles would greatly advance our understanding of the behaviors of complex particles, traditional photoelastic methods suffer from a lack of available technology for producing suitable complex particles. Recently, 3D-printing has created new possibilities for enhancing the scope of stress analysis within physically representative granules. Here, we investigate and evaluate opportunities offered by 3D-printing a single particle with a complex external shape with photoelastic properties. We report the results of X-ray computed tomography and 3D-printing, combined with traditional photoelastic analysis, to visualize strain for particles ranging from simple 2D discs to complex 3D printed coffee beans, including with internal voids. We find that the relative orientation of the print layers and the loading force affects the optical response of the discs, but without a significant difference in their mechanical properties. Furthermore, we present semi-quantitative measurements of stresses within 3D-printed complex particles. The paper outlines the potential limitations and areas of future interest for stress visualization of 3-dimensional particles.
- Published
- 2022
17. Gardner-like transition from variable to persistent force contacts in granular crystals
- Author
-
Kool, Lars, Charbonneau, Patrick, and Daniels, Karen E.
- Subjects
Condensed Matter - Soft Condensed Matter ,Condensed Matter - Statistical Mechanics - Abstract
We report experimental evidence of a Gardner-like transition from variable to persistent force contacts in a two-dimensional, bidisperse granular crystal by analyzing the variability of both particle positions and force networks formed under uniaxial compression. Starting from densities just above the freezing transition, and for variable amounts of additional compression, we compare configurations to both their own initial state, and to an ensemble of equivalent, reinitialized states. This protocol shows that force contacts are largely undetermined when the density is below a Gardner-like transition, after which they gradually transition to being persistent, being fully so only above the jamming point. We associate the disorder that underlies this effect to the size of the microscopic asperities of the photoelastic disks used, by analogy to other mechanisms that have been previously predicted theoretically.
- Published
- 2022
- Full Text
- View/download PDF
18. The effect of grain shape and material on the nonlocal rheology of dense granular flows
- Author
-
Fazelpour, Farnaz, Tang, Zhu, and Daniels, Karen E.
- Subjects
Condensed Matter - Soft Condensed Matter - Abstract
Nonlocal rheologies allow for the modeling of granular flows from the creeping to intermediate flow regimes, using a small number of parameters. In this paper, we report on experiments testing how particle properties affect model parameters, using particles of three different shapes (circles, ellipses, and pentagons) and three different materials, including one which allows for measurements of stresses via photoelasticity. Our experiments are performed on a quasi-2D annular shear cell with a rotating inner wall and a fixed outer wall. Each type of particle is found to exhibit flows which are well-fit by nonlocal rheology, with each particle having a distinct triad of the local, nonlocal, and frictional parameters. While the local parameter b is always approximately unity, the nonlocal parameter A depends sensitively on both the particle shape and material. The critical stress ratio mu_s, above which Coulomb failure occurs, varies for particles with the same material but different shapes, indicating that geometric friction can dominate over material friction.
- Published
- 2021
19. Stress propagation in locally loaded packings of disks and pentagons
- Author
-
Kozlowski, Ryan, Zheng, Hu, Daniels, Karen E., and Socolar, Joshua E. S.
- Subjects
Condensed Matter - Soft Condensed Matter ,Physics - Geophysics - Abstract
The mechanical strength and flow of granular materials can depend strongly on the shapes of individual grains. We report quantitative results obtained from photoelasticimetry experiments on locally loaded, quasi-two-dimensional granular packings of either disks or pentagons exhibiting stick-slip dynamics. Packings of pentagons resist the intruder at significantly lower packing fractions than packings of disks, transmitting stresses from the intruder to the boundaries over a smaller spatial extent. Moreover, packings of pentagons feature significantly fewer back-bending force chains than packings of disks. Data obtained on the forward spatial extent of stresses and back-bending force chains collapse when the packing fraction is rescaled according to the packing fraction of steady state open channel formation, though data on intruder forces and dynamics do not collapse. We comment on the influence of system size on these findings and highlight connections with the dynamics of the disks and pentagons during slip events., Comment: Updated after referee comments - new subsection 3.3 added along with a new figure; introduction reorganized; a few more details specified in the Methods section
- Published
- 2021
20. The delicate memory structure of origami switches
- Author
-
Jules, Théo, Reid, Austin, Daniels, Karen E., Mungan, Muhittin, and Lechenault, Frédéric
- Subjects
Condensed Matter - Soft Condensed Matter - Abstract
While memory effects emerge from systems of wildly varying length- and time-scales, the reduction of a complex system with many interacting elements into one simple enough to be understood without also losing the complex behavior continues to be a challenge. Here, we investigate how bistable cylindrical origamis provide such a reduction via tunably-interactive memory behaviors. We base our investigation on folded sheets of Kresling patterns that function as two-state memory units. By linking several units, each with a selected activation energy, we construct a one-dimensional material that exhibits return-point memory. After a comprehensive experimental analysis of the relation between the geometry of the pattern and the mechanical response for a single bit, we study the memory of a bellows composed of 4 bits arranged in series. Since these bits are decoupled, the system reduces to the Preisach model and we can drive the bellows to any of its 16 allowable states by following a prescribed sequence of compression and extension. We show how to reasonably discriminate between states by measuring the system's total height and stiffness near equilibrium. Furthermore, we establish the existence of geometrically-disallowed defective stable configurations which expand the configuration space to 64 states with a more complex transition pattern. Using empirical considerations of the mechanics, we analyze the hierarchical structure of the corresponding diagram, which includes Garden of Eden states and subgraphs. We highlight two irreversible transformations, shifting and erasure of the defect, leading to memory behaviors reminiscent of those observed with more complex glassy systems., Comment: Submitted to PRResearch
- Published
- 2021
21. Interfacial Tension Modulation of Liquid Metal via Electrochemical Oxidation
- Author
-
Song, Minyung, Daniels, Karen E., Kiani, Abolfazl, Rashidnadimi, Sahar, and Dickey, Michael D.
- Subjects
Physics - Fluid Dynamics ,Condensed Matter - Materials Science - Abstract
This progress report summarizes recent studies of electrochemical oxidation to modulate the interfacial tension of gallium-based alloys. These alloys, which are liquid at ambient conditions, have the largest interfacial tension of any liquid at room temperature. The ability to modulate the tension offers the possibility to create forces that change the shape and position of the metal. It has been known since the late 1800s that electrocapillarity-the use of potential to modulate the electric double layer on the surface of metals in electrolyte-lowers the interfacial tension of liquid metal. Yet, this phenomenon can only achieve modest changes in interfacial tension since it is limited to potential windows that avoid reactions. A recent discovery suggests that reactions driven by the electrochemical oxidation of gallium alloys cause the interfacial tension to decrease from ~500 mN/m at 0 V to ~0 mN/m at ~0.8 V, a change in tension that goes well beyond what is possible via conventional electrocapillarity or surfactants. The changes in tension are reversible; reductive potentials return the metal back to a state of high interfacial tension. This report aims to summarize key work and introduce beginners to this field by including electrochemistry basics while addressing misconceptions. We discuss applications that utilize modulations in interfacial tension of liquid metal and conclude with remaining opportunities and challenges that need further investigation.
- Published
- 2021
22. Betweenness centrality illuminates intermittent frictional dynamics
- Author
-
Dorostkar, Omid, Daniels, Karen E., Strebel, Dominik, and Carmeliet, Jan
- Subjects
Condensed Matter - Soft Condensed Matter - Abstract
Dense granular systems subjected to an imposed shear stress undergo stick-slip dynamics with systematic patterns of dilation-compaction. During each stick phase, as the frictional strength builds up, the granular system dilates to accommodate shear strain, developing stronger force networks. During each slip event, when the stored energy is released, particles experience large rearrangements and the granular network can significantly change. Here, we use numerical simulations of 3D, sheared frictional packings to show that the mean betweenness centrality -- a property of network of interparticle connections -- follows consistent patterns during the stick-slip dynamics, showing sharp spikes at each slip event. We identify the source of this behavior as arising from the connectivity and contact arrangements of granular network during dilation-compaction cycles, and find that a lower potential for connection between particles leads to an increase of mean betweenness centrality in the system. Furthermore, we show that at high confinements, few particles lose contact during slip events, leading to a smaller change in granular connectivity and betweenness centrality.
- Published
- 2021
23. Stick-slip dynamics in penetration experiments on simulated regolith
- Author
-
Featherstone, Jack, Bullard, Robert, Emm, Tristan, Jackson, Anna, Reid, Riley, Shefferman, Sean, Dove, Adrienne, Colwell, Joshua, Kollmer, Jonathan E., and Daniels, Karen E.
- Subjects
Astrophysics - Earth and Planetary Astrophysics ,Condensed Matter - Soft Condensed Matter - Abstract
The surfaces of many planetary bodies, including asteroids and small moons, are covered with dust to pebble-sized regolith held weakly to the surface by gravity and contact forces. Understanding the reaction of regolith to an external perturbation will allow for instruments, including sensors and anchoring mechanisms for use on such surfaces, to implement optimized design principles. We analyze the behavior of a flexible probe inserted into loose regolith simulant as a function of probe speed and ambient gravitational acceleration to explore the relevant dynamics. The EMPANADA experiment (Ejecta-Minimizing Protocols for Applications Needing Anchoring or Digging on Asteroids) flew on several parabolic flights. It employs a classic granular physics technique, photoelasticity, to quantify the dynamics of a flexible probe during its insertion into a system of bi-disperse, cm-sized model grains. We identify the force-chain structure throughout the system during probe insertion at a variety of speeds and for four different levels of gravity: terrestrial, martian, lunar, and microgravity. We identify discrete, stick-slip failure events that increase in frequency as a function of the gravitational acceleration. In microgravity environments, stick-slip behaviors are negligible, and we find that faster probe insertion can suppress stick-slip behaviors where they are present. We conclude that the mechanical response of regolith on rubble pile asteroids is likely quite distinct from that found on larger planetary objects, and scaling terrestrial experiments to microgravity conditions may not capture the full physical dynamics.
- Published
- 2020
24. Marangoni Fingering Instabilities in Oxidizing Liquid Metals
- Author
-
Hillaire, Keith D., Dickey, Michael D., and Daniels, Karen E.
- Subjects
Physics - Fluid Dynamics ,Condensed Matter - Soft Condensed Matter - Abstract
Eutectic gallium-indium (EGaIn), a room-temperature liquid metal alloy, has the largest tension of any liquid at room temperature, and yet can nonetheless undergo fingering instabilities. This effect arises because, under an applied voltage, oxides deposit on the surface of the metal, which leads to a lowering of the interfacial tension, allowing spreading under gravity. Understanding the spreading dynamics of room temperature liquid metals is important for developing soft electronics and understanding fluid dynamics of liquids with extreme surface tensions. When the applied voltage or the oxidation rate becomes too high, the EGaIn undergoes fingering instabilities, including tip-splitting, which occur due to a Marangoni stress on the interface. Our experiments are performed with EGaIn droplets placed in an electrolyte (sodium hydroxide); by placing the EGaIn on copper electrodes, which EGaIn readily wets, we are able to control the initial width of EGaIn fingers, setting the initial conditions of the spreading. Two transitions are observed: (1) a minimum current density at which all fingers become unstable to narrower fingers; (2) a current density at which the wider fingers undergo a single splitting event into two narrower fingers. We present a phase diagram as a function of current density and initial finger width, and identify the minimum width below which the single tip-splitting does not occur.
- Published
- 2020
25. Sponge-like rigid structures in frictional granular packings
- Author
-
Liu, Kuang, Kollmer, Jonathan E., Daniels, Karen E., Schwarz, J. M., and Henkes, Silke
- Subjects
Condensed Matter - Soft Condensed Matter - Abstract
We show how rigidity emerges in experiments of sheared frictional granular materials by using generalizations of two methods for identifying rigid structures. Both approaches, the force-based dynamical matrix and the topology-based rigidity percolation, agree with each other and identify similar rigid structures. As the system becomes jammed, at a contact number of $z=2.4\pm 0.1$, a rigid backbone interspersed with floppy, particle-filled holes of a broad range of sizes emerges, creating a sponge-like morphology. We also find that the pressure within rigid structures always exceeds the pressure outside the rigid structures, i.e. that the backbone is load-bearing. These findings shows that it is necessary to go beyond mean-field theory to capture the physics of frictional jamming and also suggests that mechanical stability arises through arch structures and hinges at the mesoscale., Comment: 19 pages, 19 figures
- Published
- 2020
- Full Text
- View/download PDF
26. A Multitiered Professional Learning Training Package to Increase Teacher Praise Rate and Decrease Disruptive Student Behavior
- Author
-
Daniels, Karen
- Abstract
Behavior-specific praise is an evidenced-based and effective classroom and behavior management strategy. Despite the effectiveness of behavior-specific praise, low rates of classroom implementation and expressed needs for additional professional learning on classroom and behavior management strategies persist. School leaders can use existing staff and resources to address these needs by providing professional learning and subsequent support to teachers. A multitiered, systematic, and structured professional learning approach can be used to meet most teachers' individual learning needs. This study evaluated the effects of using a training package with teachers to increase their rate of behavior-specific praise to decrease disruptive student behavior. Three early childhood teachers who displayed low rates of behavior-specific praise participated in the study. Teachers received virtual training and visual performance feedback within a multiple probe across participants design. Results indicated teachers increased their rate of behavior-specific praise following introduction of the professional learning intervention package and maintained following withdrawal. This study could not establish the impact of behavior-specific praise on disruptive student behavior. Implications for practice and future research are discussed. [The dissertation citations contained here are published with the permission of ProQuest LLC. Further reproduction is prohibited without permission. Copies of dissertations may be obtained by Telephone (800) 1-800-521-0600. Web page: http://www.proquest.com/en-US/products/dissertations/individuals.shtml.]
- Published
- 2022
27. Notions of Agency in Early Literacy Classrooms: Assemblages and Productive Intersections
- Author
-
Daniels, Karen
- Abstract
Agency and its role in the early literacy classroom has long been a topic for debate. While sociocultural accounts often portray the child as a cultural agent who negotiates their own participation in classroom culture and literacy learning, more recent framings draw attention from the individual subject, instead seeing agency as dispersed across people and materials. In this article, I draw on my experiences of following children as they followed their interests in an early literacy classroom, drawing on the concepts of "assemblage" and "people yet to come," as defined by Deleuze and Guattari and Spinoza's "common notion." I provide one illustrative account of moment-by-moment activity and suggest that in education settings it is useful to see activity as a direct and ongoing interplay of three dimensions: children's moving bodies; the classroom; and its materials. I propose that children's ongoing movements create possibilities for 'doing' and 'being' that flow across and between children. I argue that thinking with assemblages can draw attention to both the potentiality and the power dynamics inherent in the ongoing present and also counter preconceived notions of individual child agency and linear trajectories of literacy development, and the inequalities that these concepts can perpetuate within early education settings.
- Published
- 2021
- Full Text
- View/download PDF
28. Particle Size Effects in Flow-Stabilized Solids
- Author
-
Lindauer, Scott, Ortiz, Carlos P., Riehn, Robert, and Daniels, Karen E.
- Subjects
Condensed Matter - Soft Condensed Matter ,Physics - Fluid Dynamics - Abstract
Flow-stabilized solids are a class of fragile matter that forms when a dense suspension of colloids accumulates against a semi-permeable barrier, for flow rates above a critical value. In order to probe the effect of particle size on the formation of these solids, we perform experiments on micron-sized monodisperse spherical polystyrene spheres in a Hele-Shaw geometry. We examine the spatial extent, internal fluctuations, and fluid permeability of the solids deposited against the barrier, and find that these do not scale with the P\'eclet number. Instead, we find distinct behaviors at higher Peclet numbers, suggesting a transition from thermal- to athermal-solids which we connect to particle-scale fluctuations in the liquid-like layer at the upstream surface of the solid. We further observe that while the Carman-Kozeny model does not accurately predict the permeability of flow-stabilized solids, we do find a new scaling which predicts the permeability.
- Published
- 2019
29. Distinguishing deformation mechanisms in elastocapillary experiments
- Author
-
Chen, Shih-Yuan, Bardall, Aaron, Shearer, Michael, and Daniels, Karen E.
- Subjects
Condensed Matter - Soft Condensed Matter - Abstract
Soft materials are known to deform due to a variety of mechanisms, including capillarity, buoyancy, and swelling. In this paper, we present experiments on polyvinylsiloxane gel threads partially-immersed in three liquids with different solubility, wettability, and swellability. Our results demonstrate that deformations due to capillarity, buoyancy, and swelling can be of similar magnitude as such threads come to static equilibrium. To account for all three effects being present in a single system, we derive a model capable of explaining the observed data and use it to determine the force law at the three-phase contact line. The results show that the measured forces are consistent with the expected Young-Dupr\'e equation, and do not require the inclusion of a tangential contact line force.
- Published
- 2019
30. Gradient Induced Droplet Motion Over Soft Solids
- Author
-
Bardall, Aaron, Chen, Shih-Yuan, Daniels, Karen E., and Shearer, Michael
- Subjects
Condensed Matter - Soft Condensed Matter - Abstract
Fluid droplets can be induced to move over rigid or flexible surfaces under external or body forces. We describe the effect of variations in material properties of a flexible substrate as a mechanism for motion. In this paper, we consider a droplet placed on a substrate with either a stiffness or surface energy gradient, and consider its potential for motion via coupling to elastic deformations of the substrate. In order to clarify the role of contact angles and to obtain a tractable model, we consider a two-dimensional droplet. The gradients in substrate material properties give rise to asymmetric solid deformation and to unequal contact angles, thereby producing a force on the droplet. We then use a dynamic viscoelastic model to predict the resulting dynamics of droplets. Numerical results quantifying the effect of the gradients establish that it is more feasible to induce droplet motion with a gradient in surface energy. The results show that the magnitude of elastic modulus gradient needed to induce droplet motion exceeds experimentally feasible limits in the production of soft solids and is therefore unlikely as a passive mechanism for cell motion. In both cases, of surface energy or elastic modulus, the threshold to initiate motion is achieved at lower mean values of the material properties., Comment: 13 pages, 3 figures
- Published
- 2019
31. Dynamics of a grain-scale intruder in a two-dimensional granular medium with and without basal friction
- Author
-
Kozlowski, Ryan, Carlevaro, C. Manuel, Daniels, Karen E., Kondic, Lou, Pugnaloni, Luis A., Socolar, Joshua E. S., Zheng, Hu, and Behringer, Robert P.
- Subjects
Condensed Matter - Soft Condensed Matter - Abstract
We report on a series of experiments in which a grain-sized intruder is pushed by a spring through a 2D granular material comprised of photoelastic disks in a Couette geometry. We study the intruder dynamics as a function of packing fraction for two types of supporting substrates: a frictional glass plate and a layer of water for which basal friction forces are negligible. We observe two dynamical regimes: intermittent flow, in which the intruder moves freely most of the time but occasionally gets stuck, and stick-slip dynamics, in which the intruder advances via a sequence of distinct, rapid events. When basal friction is present, we observe a smooth crossover between the two regimes as a function of packing fraction, and we find that reducing the interparticle friction coefficient causes the stick-slip regime to shift to higher packing fractions. When basal friction is eliminated, we observe intermittent flow at all accessible packing fractions. For all cases, we present results for the statistics of stick events, the intruder velocity, and the force exerted on the intruder by the grains. Our results indicate the qualitative importance of basal friction at high packing fractions and suggest a possible connection between intruder dynamics in a static material and clogging dynamics in granular flows., Comment: 10 pages, 11 figures, 1 table. V2: What is now Fig. 5 was added to clarify the raw data measured. References [27] and [37] were updated since they were published only recently
- Published
- 2019
- Full Text
- View/download PDF
32. Viewing Earth's surface as a soft matter landscape
- Author
-
Jerolmack, Douglas J. and Daniels, Karen E.
- Subjects
Condensed Matter - Soft Condensed Matter ,Physics - Geophysics - Abstract
The Earth's surface is composed of a staggering diversity of particulate-fluid mixtures: dry to wet, dilute to dense, colloidal to granular, and attractive to repulsive particles. This material variety is matched by the range of relevant stresses and strain rates, from laminar to turbulent flows, and steady to intermittent forcing, leading to anything from rapid and catastrophic landslides to the slow relaxation of soil and rocks over geologic timescales. Geophysical flows sculpt landscapes, but also threaten human lives and infrastructure. From a physics point of view, virtually all Earth and planetary landscapes are composed of soft matter, in the sense they are both deformable and sensitive to collective effects. Geophysical materials, however, often involve compositions and flow geometries that have not yet been examined in physics. In this review we explore how a soft-matter perspective has helped to illuminate, and even predict, the rich dynamics of Earth materials and their associated landscapes. We also highlight some novel phenomena of geophysical flows that challenge, and will hopefully inspire, more fundamental work in soft matter.
- Published
- 2019
33. Enlightening force chains: a review of photoelasticimetry in granular matter
- Author
-
Zadeh, Aghil Abed, Barés, Jonathan, Brzinski, Theodore A., Daniels, Karen E., Dijksman, Joshua, Docquier, Nicolas, Everitt, Henry, Kollmer, Jonathan E., Lantsoght, Olivier, Wang, Dong, Workamp, Marcel, Zhao, Yiqiu, and Zheng, Hu
- Subjects
Condensed Matter - Soft Condensed Matter ,Condensed Matter - Statistical Mechanics - Abstract
A photoelastic material will reveal its internal stresses when observed through polarizing filters. This eye-catching property has enlightened our understanding of granular materials for over half a century, whether in the service of art, education, or scientific research. In this review article in honor of Robert Behringer, we highlight both his pioneering use of the method in physics research, and its reach into the public sphere through museum exhibits and outreach programs. We aim to provide clear protocols for artists, exhibit-designers, educators, and scientists to use in their own endeavors. It is our hope that this will build awareness about the ubiquitous presence of granular matter in our lives, enlighten its puzzling behavior, and promote conversations about its importance in environmental and industrial contexts. To aid in this endeavor, this paper also serves as a front door to a detailed wiki containing open, community-curated guidance on putting these methods into practice., Comment: 13 pages
- Published
- 2019
- Full Text
- View/download PDF
34. Forecasting failure locations in two-dimensional disordered lattices
- Author
-
Berthier, Estelle, Porter, Mason A., and Daniels, Karen E.
- Subjects
Condensed Matter - Soft Condensed Matter ,Condensed Matter - Disordered Systems and Neural Networks ,Condensed Matter - Materials Science ,Nonlinear Sciences - Adaptation and Self-Organizing Systems - Abstract
Forecasting fracture locations in a progressively failing disordered structure is of paramount importance when considering structural materials. We explore this issue for gradual deterioration via beam breakage of two-dimensional disordered lattices, which we represent as networks, for various values of mean degree. We study experimental samples with geometric structures that we construct based on observed contact networks in 2D granular media. We calculate geodesic edge betweenness centrality, which helps quantify which edges are on many shortest paths in a network, to forecast the failure locations. We demonstrate for the tested samples that, for a variety of failure behaviors, failures occur predominantly at locations that have larger geodesic edge betweenness values than the mean one in the structure. Because only a small fraction of edges have values above the mean, this is a relevant diagnostic to assess failure locations. Our results demonstrate that one can consider only specific parts of a system as likely failure locations and that, with reasonable success, one can assess possible failure locations of a structure without needing to study its detailed energetic states., Comment: Extended discussion, added supplementary information
- Published
- 2018
- Full Text
- View/download PDF
35. Rigidity percolation control of the brittle-ductile transition in disordered networks
- Author
-
Berthier, Estelle, Kollmer, Jonathan E., Henkes, Silke E., Liu, Kuang, Schwarz, Jennifer M., and Daniels, Karen E.
- Subjects
Condensed Matter - Soft Condensed Matter ,Condensed Matter - Materials Science - Abstract
In ordinary solids, material disorder is known to increase the size of the process zone in which stress concentrates at the crack tip, causing a transition from localized to diffuse failure. Here, we report experiments on disordered 2D lattices, derived from frictional particle packings, in which the mean coordination number $\langle z \rangle$ of the underlying network provides a similar control. Our experiments show that tuning the connectivity of the network provides access to a range of behaviors from brittle to ductile failure. We elucidate the cooperative origins of this transition using a frictional pebble game algorithm on the original, intact lattices. We find that the transition corresponds to the isostatic value $\langle z \rangle = 3$ in the large-friction limit, with brittle failure occurring for structures vertically spanned by a rigid cluster, and ductile failure for floppy networks containing nonspanning rigid clusters. Furthermore, we find that individual failure events typically occur within the floppy regions separated by the rigid clusters.
- Published
- 2018
- Full Text
- View/download PDF
36. Betweenness Centrality as Predictor for Forces in Granular Packings
- Author
-
Kollmer, Jonathan E. and Daniels, Karen E.
- Subjects
Condensed Matter - Soft Condensed Matter - Abstract
A load applied to a jammed frictional granular system will be localized into a network of force chains making inter-particle connections throughout the system. Because such systems are typically under-constrained, the observed force network is not unique to a given particle configuration, but instead varies upon repeated formation. In this paper, we examine the ensemble of force chain configurations created under repeated assembly in order to develop tools to statistically forecast the observed force network. In experiments on a gently suspended 2D layer of photoelastic particles, we subject the assembly to hundreds of repeated cyclic compressions. As expected, we observe the non-unique nature of the force network, which differs for each compression cycle, by measuring all vector inter-particle contact forces using our open source PeGS software. We find that total pressure on each particle in the system correlates to its betweenness centrality value extracted from the geometric contact network. Thus, the mesoscale network structure is a key control on individual particle pressures.
- Published
- 2018
37. Protocol-Dependence and State Variables in the Force-Moment Ensemble
- Author
-
Bililign, Ephraim S., Kollmer, Jonathan E., and Daniels, Karen E.
- Subjects
Condensed Matter - Soft Condensed Matter ,Condensed Matter - Statistical Mechanics - Abstract
Stress-based ensembles incorporating temperature-like variables have been proposed as a route to an equation of state for granular materials. To test the efficacy of this approach, we perform experiments on a two-dimensional photoelastic granular system under three loading conditions: uniaxial compression, biaxial compression, and simple shear. From the interparticle forces, we find that the distributions of the normal component of the coarse-grained force-moment tensor are exponential-tailed, while the deviatoric component is Gaussian-distributed. This implies that the correct stress-based statistical mechanics conserves both the force-moment tensor and the Maxwell-Cremona force-tiling area. As such, two variables of state arise: the tensorial angoricity ($\hat{\alpha}$) and a new temperature-like quantity associated with the force-tile area which we name {\it keramicity} ($\kappa$). Each quantity is observed to be inversely proportional to the global confining pressure; however only $\kappa$ exhibits the protocol-independence expected of a state variable, while $\hat{\alpha}$ behaves as a variable of process.
- Published
- 2018
- Full Text
- View/download PDF
38. Former lawyer for Stormy Daniels, Karen McDougal cooperating with Cohen probe
- Subjects
Company legal issue ,General interest ,News, opinion and commentary - Abstract
Byline: Sara Sidner and Eli Watkins, CNN (CNN) -- Keith Davidson, the lawyer at the center of agreements with two women paid to keep silent about alleged affairs from more [...]
- Published
- 2018
39. Movement, Meaning and Affect and Young Children's Early Literacy Practices
- Author
-
Daniels, Karen
- Abstract
This paper reports on an analysis of patterns of children's bodily movements in an Early Years classroom. I illustrate two prevalent patterns identified during close observations of children's walking movements as they as they followed their interests while accessing continuous provision in an Early Years setting in England. I termed the patterned pathways movement/ interest formations and draw a relationship between these formations and affective atmospheres, suggesting that these atmospheres were created by the dynamics and flows of children's ongoing bodily movements. I propose that affective atmospheres and movement/interest formations are intricately connected to child-produced meanings as children re-imagine, re-shape and re-purpose classroom spaces and materials. In this way I contribute to conceptual understandings role of children's whole bodily movements and the accompanying affective atmospheres in the emergence of young children's literacy practices. My findings substantiate viewpoints that children should be provided with the opportunity to engage in exploratory play and move freely in education settings. Furthermore, I suggest that practitioners be attuned to the the affective dimensions of young children's emerging literacy practices in Early Years classrooms.
- Published
- 2021
- Full Text
- View/download PDF
40. Understanding the local and international stakeholders in rheumatic heart disease field in Tanzania and Uganda: A systematic stakeholder mapping
- Author
-
Moloi, Hlengiwe, Tulloch, Nathaniel L., Watkins, David, Perkins, Susan, Engel, Mark, Abdullahi, Leila, Daniels, Karen, and Zühlke, Liesl
- Published
- 2022
- Full Text
- View/download PDF
41. Movement, meaning and affect : the stuff childhood literacies are made of
- Author
-
Daniels, Karen Diane and Burnett, Cathy
- Subjects
372.21 - Abstract
This thesis emanates from an ethnographically informed study involving a close examination of the multiple ways that meaning making emerges in children’s ongoing, self-initiated activity. I adopt a poststructuralist frame which provides conceptual tools of emergence, movement and affect and pay attention to activity that spontaneously arose across children. I present a detailed description of the significance of movement in young children’s meaning making that involves the re-shaping, re-imagining and repurposing of materials and classroom areas. Movements are seen as integral to children’s symbolic meaning making and the kinds of practices that emerge. I make four contributions to knowledge through presenting new insights into movement during the process of meaning making in one Early Years settings as follows. I have shown the way children’s interest played out in their movement and identified three prevalent interest/ movement formations. I have underlined the importance of movement by illustrating the ways in which movement is deeply implicated within material arrangements of the classroom. I have suggested that the quality or dynamics of movement are related to affective atmospheres. Through juxtaposing movement, materials and classrooms, I have generated a conceptual framework for analysing the way in which agency is distributed across children’s moving bodies, the classroom, and its materials. My account of children’s activity has implications for the way that teachers might work to: • see literacy as a collective endeavour deeply implicated with available materials; • be open to diverse pathways to literacy learning; • acknowledge literacy development as a non-linear trajectory; • take account of children’s spontaneous exploratory movement in classrooms; • take account of the way that movement contributes to the affective atmospheres in classrooms; • offer children opportunity for spontaneous exploration of meanings, real and imagined, so allowing diverse child-generated sites for participation; • forge broader understanding of the relationship between literacy and play.
- Published
- 2018
42. Network Analysis of Particles and Grains
- Author
-
Papadopoulos, Lia, Porter, Mason A., Daniels, Karen E., and Bassett, Danielle S.
- Subjects
Condensed Matter - Soft Condensed Matter ,Condensed Matter - Disordered Systems and Neural Networks ,Mathematics - Algebraic Topology ,Nonlinear Sciences - Adaptation and Self-Organizing Systems ,Physics - Data Analysis, Statistics and Probability - Abstract
The arrangements of particles and forces in granular materials have a complex organization on multiple spatial scales that ranges from local structures to mesoscale and system-wide ones. This multiscale organization can affect how a material responds or reconfigures when exposed to external perturbations or loading. The theoretical study of particle-level, force-chain, domain, and bulk properties requires the development and application of appropriate physical, mathematical, statistical, and computational frameworks. Traditionally, granular materials have been investigated using particulate or continuum models, each of which tends to be implicitly agnostic to multiscale organization. Recently, tools from network science have emerged as powerful approaches for probing and characterizing heterogeneous architectures across different scales in complex systems, and a diverse set of methods have yielded fascinating insights into granular materials. In this paper, we review work on network-based approaches to studying granular matter and explore the potential of such frameworks to provide a useful description of these systems and to enhance understanding of their underlying physics. We also outline a few open questions and highlight particularly promising future directions in the analysis and design of granular matter and other kinds of material networks.
- Published
- 2017
- Full Text
- View/download PDF
43. Granular rheology: measuring boundary forces with laser-cut leaf springs
- Author
-
Tang, Zhu, Brzinski, Theodore A., and Daniels, Karen E.
- Subjects
Physics - Fluid Dynamics - Abstract
In granular physics experiments, it is a persistent challenge to obtain the boundary stress measurements necessary to provide full a rheological characterization of the dynamics. Here, we describe a new technique by which the outer boundary of a 2D Couette cell both confines the granular material and provides spatially- and temporally- resolved stress measurements. This key advance is enabled by desktop laser-cutting technology, which allows us to design and cut linearly-deformable walls with a specified spring constant. By tracking the position of each segment of the wall, we measure both the normal and tangential stress throughout the experiment. This permits us to calculate the amount of shear stress provided by basal friction, and thereby determine accurate values of $\mu(I)$., Comment: 4 pages, 5 figures, powder and grains 2017 conference
- Published
- 2017
- Full Text
- View/download PDF
44. An experimental investigation of the force network ensemble
- Author
-
Kollmer, Jonathan E. and Daniels, Karen E.
- Subjects
Condensed Matter - Soft Condensed Matter - Abstract
We present an experiment in which a horizontal quasi-2D granular system with a fixed neighbor network is cyclically compressed and decompressed over 1000 cycles. We remove basal friction by floating the particles on a thin air cushion, so that particles only interact in-plane. As expected for a granular system, the applied load is not distributed uniformly, but is instead concentrated in force chains which form a network throughout the system. To visualize the structure of these networks, we use particles made from photoelastic material. The experimental setup and a new data-processing pipeline allow us to map out the evolution subject to the cyclic compressions. We characterize several statistical properties of the packing, including the probability density function of the contact force, and compare them with theoretical and numerical predictions from the force network ensemble theory., Comment: accepted for publication in the conference proceedings of Powders and Grains 2017
- Published
- 2017
- Full Text
- View/download PDF
45. Oxidation-Mediated Fingering in Liquid Metals
- Author
-
Eaker, Collin B., Hight, David C., O'Regan, John D., Dickey, Michael D., and Daniels, Karen E.
- Subjects
Condensed Matter - Soft Condensed Matter ,Nonlinear Sciences - Pattern Formation and Solitons - Abstract
We identify and characterize a new class of fingering instabilities in liquid metals; these instabilities are unexpected due to the large interfacial tension of metals. Electrochemical oxidation lowers the effective interfacial tension of a gallium-based liquid metal alloy to values approaching zero, thereby inducing drastic shape changes, including the formation of fractals. The measured fractal dimension ($D = 1.3 \pm 0.05$) places the instability in a different universality class than other fingering instabilities. By characterizing changes in morphology and dynamics as a function of droplet volume and applied electric potential, we identify the three main forces involved in this process: interfacial tension, gravity, and oxidative stress. Importantly, we find that electrochemical oxidation can generate compressive interfacial forces that oppose the tensile forces at a liquid interface. Thus, the surface oxide layer not only induces instabilities, but ultimately provides a physical barrier that halts the instabilities at larger positive potentials. Controlling the competition between surface tension and oxidative (compressive) stresses at the interface is important for the development of reconfigurable electronic, electromagnetic, and optical devices that take advantage of the metallic properties of liquid metals.
- Published
- 2017
- Full Text
- View/download PDF
46. Focus on Imaging Methods in Granular Physics
- Author
-
Amon, Axelle, Born, Philip, Daniels, Karen E., Dijksman, Joshua A., Huang, Kai, Parker, David, Schröter, Matthias, Stannarius, Ralf, and Wierschem, Andreas
- Subjects
Physics - Instrumentation and Detectors ,Condensed Matter - Soft Condensed Matter - Abstract
Granular materials are complex multi-particle ensembles in which macroscopic properties are largely determined by inter-particle interactions between their numerous constituents. In order to understand and to predict their macroscopic physical behavior, it is necessary to analyze the composition and interactions at the level of individual contacts and grains. To do so requires the ability to image individual particles and their local configurations to high precision. A variety of competing and complementary imaging techniques have been developed for that task. In this introductory paper accompanying the Focus Issue, we provide an overview of these imaging methods and discuss their advantages and drawbacks, as well as their limits of application., Comment: Submitted to Review of Scientific Instruments as introduction for: Focus on Imaging Methods in Granular Physics
- Published
- 2017
- Full Text
- View/download PDF
47. Soft matter physics of the ground beneath our feet.
- Author
-
Voigtländer, Anne, Houssais, Morgane, Bacik, Karol A., Bourg, Ian C., Burton, Justin C., Daniels, Karen E., Datta, Sujit S., Del Gado, Emanuela, Deshpande, Nakul S., Devauchelle, Olivier, Ferdowsi, Behrooz, Glade, Rachel, Goehring, Lucas, Hewitt, Ian J., Jerolmack, Douglas, Juanes, Ruben, Kudrolli, Arshad, Ching-Yao Lai, Wei Li, and Masteller, Claire
- Published
- 2024
- Full Text
- View/download PDF
48. Interfacial Tension Hysteresis of Eutectic Gallium‐Indium.
- Author
-
Hillaire, Keith D., Nithyanandam, Praneshnandan, Song, Minyung, Nadimi, Sahar Rashid, Kiani, Abolfazl, Dickey, Michael D., and Daniels, Karen E.
- Subjects
INTERFACIAL tension ,GALLIUM alloys ,LIQUID metals ,ELECTRIC potential ,IMPEDANCE spectroscopy - Abstract
When in a pristine state, gallium and its alloys have the largest interfacial tensions of any liquid at room temperature. Nonetheless, applying as little as 0.8 V of electric potential across eutectic gallium indium (EGaIn) placed within aqueous sodium hydroxide (NaOH, or other electrolyte) solution will cause the metal to behave as if its interfacial tension is near zero. The mechanism behind this phenomenon has remained poorly understood because NaOH dissolves the oxide species, making it difficult to directly measure the concentration, thickness, or chemical composition of the film that forms at the interface. In addition, the oxide layers formed are atomically‐thin. Here, it presents a suite of techniques that allow to simultaneously measure both electrical and interfacial properties as a function of applied electric potential, allowing for new insights into the mechanisms, which cause the dramatic decrease in interfacial tension. A key discovery from this work is that the interfacial tension displays hysteresis while lowering the applied potential. It combines these observations with electrochemical impedance spectroscopy to evaluate how these changes in interfacial tension arise from chemical, electrical, and mechanical changes on the interface, and close with ideas for how to build a free energy model to predict these changes from first principles. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
49. Photoelastic force measurements in granular materials
- Author
-
Daniels, Karen E., Kollmer, Jonathan E., and Puckett, James G.
- Subjects
Condensed Matter - Soft Condensed Matter - Abstract
Photoelastic techniques are used to make both qualitative and quantitative measurements of the forces within idealized granular materials. The method is based on placing a birefringent granular material between a pair of polarizing filters, so that each region of the material rotates the polarization of light according to the amount of local of stress. In this review paper, we summarize past work using the technique, describe the optics underlying the technique, and illustrate how it can be used to quantitatively determine the vector contact forces between particles in a 2D granular system. We provide a description of software resources available to perform this task, as well as key techniques and resources for building an experimental apparatus.
- Published
- 2016
- Full Text
- View/download PDF
50. Sounds of Failure: Passive Acoustic Measurements of Excited Vibrational Modes
- Author
-
Brzinski, Theodore A. and Daniels, Karen E.
- Subjects
Condensed Matter - Soft Condensed Matter ,Condensed Matter - Statistical Mechanics - Abstract
Granular materials can fail through spontaneous events like earthquakes or brittle fracture. However, measurements and analytic models which forecast failure in this class of materials, while of both fundamental and practical interest, remain elusive. Materials including numerical packings of spheres, colloidal glasses, and granular materials have been known to develop an excess of low-frequency vibrational modes as the confining pressure is reduced. Here, we report experiments on sheared granular materials in which we monitor the evolving density of excited modes via passive monitoring of acoustic emissions. We observe a broadening of the distribution of excited modes coincident with both bulk and local plasticity, and clear evolution in the shape of the distribution before and after bulk failure. These results provide a new interpretation of the changing state of the material on its approach to stick-slip failure., Comment: 5 pages, 5 figures
- Published
- 2016
- Full Text
- View/download PDF
Catalog
Discovery Service for Jio Institute Digital Library
For full access to our library's resources, please sign in.