Your search keyword '"Daniels, Karen"' showing total 13 results

1. Forecasting landslides using community detection on geophysical satellite data

Author

Desai, Vrinda, Fazelpour, Farnaz, Handwerger, Alexander L., and Daniels, Karen E.

Subjects

Physics - Geophysics, FOS: Physical sciences, Disordered Systems and Neural Networks (cond-mat.dis-nn), Condensed Matter - Disordered Systems and Neural Networks, Geophysics (physics.geo-ph)

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

2. Movement, meaning and affect and young children’s early literacy practices

Author

Daniels, Karen

Subjects

Movement (music), media_common.quotation_subject, education, 05 social sciences, 050301 education, Affect (psychology), Viewpoints, Motion (physics), Literacy, Education, Developmental psychology, Nonverbal communication, Dynamics (music), Developmental and Educational Psychology, 0501 psychology and cognitive sciences, Psychology, 0503 education, 050104 developmental & child psychology, Meaning (linguistics), media_common

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

2019

3. Notions of agency in early literacy classrooms: Assemblages and productive intersections

Author

Daniels, Karen

Subjects

Early literacy, 05 social sciences, Agency (sociology), Pedagogy, 050301 education, 0501 psychology and cognitive sciences, Sociology, Sociocultural evolution, 0503 education, 050104 developmental & child psychology, Education

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

2019

4. The delicate memory structure of origami switches

Author

Jules, Théo, Reid, Austin, Daniels, Karen E., Mungan, Muhittin, and Lechenault, Frédéric

Subjects

Soft Condensed Matter (cond-mat.soft), FOS: Physical sciences, 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

5. Viewing Earth's surface as a soft matter landscape

Author

Jerolmack, Douglas J. and Daniels, Karen E.

Subjects

Physics - Geophysics, Physics::Fluid Dynamics, Soft Condensed Matter (cond-mat.soft), FOS: Physical sciences, Condensed Matter - Soft Condensed Matter, Physics::Geophysics, Geophysics (physics.geo-ph)

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

6. 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, Fluid Dynamics (physics.flu-dyn), Soft Condensed Matter (cond-mat.soft), FOS: Physical sciences, Physics - Fluid Dynamics, Condensed Matter - Soft Condensed Matter

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

7. Additional file 2: of Primary care clinical practice guidelines in South Africa: qualitative study exploring perspectives of national stakeholders

Author

Kredo, Tamara, Abrams, Amber, Young, Taryn, Quinette Louw, Volmink, Jimmy, and Daniels, Karen

Abstract

Analysis â Sub-themes for theme context (Codes generated from the analysis). (DOCX 16Â kb)

Published

2017

8. Additional file 1: of Primary care clinical practice guidelines in South Africa: qualitative study exploring perspectives of national stakeholders

Author

Kredo, Tamara, Abrams, Amber, Young, Taryn, Quinette Louw, Volmink, Jimmy, and Daniels, Karen

Abstract

Interview schedule for semi-structured interviews (Table of questions asked to participants). (DOCX 13Â kb)

Published

2017

9. Capillary fracture of ultrasoft gels: heterogeneity and delayed nucleation

Author

Grzelka, Marion, Bostwick, Joshua B., and Daniels, Karen E.

Subjects

Soft Condensed Matter (cond-mat.soft), FOS: Physical sciences, Condensed Matter - Soft Condensed Matter

Abstract

A droplet of surfactant spreading on an ultrasoft ($E \lesssim 100$ Pa) gel substrate will produce capillary fractures at the gel surface; these fractures originate at the contact-line and propagate outwards in a starburst pattern. There is an inherent variability in both the number of fractures formed and the time delay before fractures form. In the regime where single fractures form, we observe a Weibull-like distribution of delay times, consistent with a thermally-activated process. The shape parameter is close to 1 for softer gels (a Poisson process), and larger for stiffer gels (indicative of aging). For single fractures, the characteristic delay time is primarily set by the elastocapillary length of the system, calculated from the differential in surface tension between the droplet and the substrate, rather than the elastic modulus as for stiffer systems. For multiple fractures, all fractures appear simultaneously and long delay times are suppressed. The delay time distribution provides a new technique for probing the energy landscape and fracture toughness of ultrasoft materials.

Published

2016

10. High refractive index immersion liquid for super-resolution 3D imaging using sapphire-based aNAIL optics

Author

Laskar, Junaid M., Kumar, P. Shravan, Herminghaus, Stephan, Daniels, Karen E., and Schröter, Matthias

Subjects

FOS: Physical sciences, Physics - Optics, Optics (physics.optics)

Abstract

Optically-transparent immersion liquids with refractive index (n ~ 1.77) to match sapphire-based aplanatic numerical aperture increasing lens (aNAIL) are necessary for achieving deep 3D imaging with high spatial resolution. We report that antimony tribromide (SbBr$_{3}$) salt dissolved in liquid diiodomethane (CH$_{2}$I$_{2}$) provides a new high refractive index immersion liquid for optics applications. The refractive index is tunable from n = 1.74 (pure) to n = 1.873 (saturated), by adjusting either salt concentration or temperature; this allows it to match (or even exceed) the refractive index of sapphire. Importantly, the solution gives excellent light transmittance in the ultraviolet to near-infrared range, an improvement over commercially-available immersion liquids. This refractive index matched immersion liquid formulation has enabled us to develop a sapphire-based aNAIL objective that has both high numerical aperture (NA = 1.17) and long working distance (WD = 12 mm). This opens up new possibilities for deep 3D imaging with high spatial resolution.

Published

2015

11. Stretching Rubber, Stretching Minds: a polymer physics lab for teaching entropy

Author

Brzinski, Theodore A. and Daniels, Karen E.

Subjects

Physics Education (physics.ed-ph), Physics - Physics Education, FOS: Physical sciences

Abstract

Entropy is a difficult concept to teach using real-world examples. Unlike temperature, pressure, volume, or work, it's not a quantity which most students encounter in their day-to-day lives. Even the way entropy is often qualitatively described, as a measure of disorder, is incomplete and can be misleading. In an effort to address these obstacles, we have developed a simple laboratory activity, the stretching of an elastic rubber sheet, intended to give students hands-on experience with the concepts of entropy, temperature and work in both adiabatic and quasistatic processes. We present two versions of the apparatus: a double-lever system, which may be reproduced with relatively little cost, and a commercial materials testing system, which provides students experience with scientific instrumentation that is used in research., Comment: Submitted to the American Journal of Physics

Published

2015

12. Nonlinear Elasticity of Flow-Stabilized Solids

Author

Ortiz, Carlos P., Daniels, Karen E., and Riehn, Robert

Subjects

Soft Condensed Matter (cond-mat.soft), FOS: Physical sciences, Condensed Matter - Soft Condensed Matter

Abstract

Thermal fluctuations, geometric exclusion, and external driving all govern the mechanical response of dense particulate suspensions. Here, we measure the stress-strain response of quasi-two-dimensional flow-stabilized microsphere heaps in a regime in which all three effects are present using a microfluidic device. We observe that the elastic modulus and the mean interparticle separation of the heaps are tunable via the confining stress provided by the fluid flow. Furthermore, the measured stress-strain curves exhibit a universal nonlinear shape which can be predicted from a thermal van der Waals equation of state with excluded volume. This analysis indicates that many-body interactions contribute a significant fraction of the stress supported by the heap.

Published

2014

13. Advancing the field of health systems research synthesis

Author

Langlois, Etienne V., Ranson, Michael K., Bärnighausen, Till, Bosch-Capblanch, Xavier, Daniels, Karen, El-Jardali, Fadi, Ghaffar, Abdul, Grimshaw, Jeremy, Haines, Andy, Lavis, John N., Lewin, Simon, Meng, Qingyue, Oliver, Sandy, Pantoja, Tomás, Straus, Sharon, Shemilt, Ian, Tovey, David, Tugwell, Peter, Waddington, Hugh, Wilson, Mark, Yuan, Beibei, and Røttingen, John-Arne

Subjects

3. Good health