Your search keyword '"Daniels, Karen"' showing total 3 results

1. Correlations between electrical and mechanical signals during granular stick-slip events.

Author

Daniels, Karen, Bauer, Caroline, and Shinbrot, Troy

Subjects

GRANULAR computing, GRANULAR materials sampling, GRANULAR material testing, PHOTOELASTICITY, SLIP flows (Physics)

Abstract

Powders and grains exhibit unpredictable jamming-to-flow transitions that manifest themselves on geophysical scales in catastrophic slip events such as landslides and earthquakes, and on laboratory/industrial scales in profound processing difficulties. Over the past few years, insight into these transitions has been provided by new evidence that slip events may be accompanied, or even preceded, by electrical effects. In the present work, we quantify the correlation between slip and the separation of electrical charges, using an archetypal granular material: photoelastic polymers. We measure a strong correlation between material displacement, acoustic emissions, and voltage. We find that the generation of voltage is associated with surface, rather than bulk properties of the granular materials. While voltage precursors are only occasionally observed in this system, there is some asymmetry in the cross-correlation between the slip and voltage signals that indicates differences between the pre- and post-slip dynamics. [ABSTRACT FROM AUTHOR]

Published

2014

2. Enlightening force chains: a review of photoelasticimetry in granular matter.

Author

Abed Zadeh, Aghil, Barés, Jonathan, Brzinski, Theodore A., Daniels, Karen E., Dijksman, Joshua, Docquier, Nicolas, Everitt, Henry O., Kollmer, Jonathan E., Lantsoght, Olivier, Wang, Dong, Workamp, Marcel, Zhao, Yiqiu, and Zheng, Hu

Subjects

PHOTOELASTICITY, MUSEUM exhibits, OUTREACH programs, PHYSICS research, PUBLIC sphere, GRANULAR materials

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 (Abed-Zadeh et al. in Photoelastic methods wiki https://git-xen.lmgc.univ-montp2.fr/PhotoElasticity/Main/wikis/home, 2019). [ABSTRACT FROM AUTHOR]

Published

2019

3. Dynamics of oblique impact in a quasi two-dimensional granular medium.

Author

Bester, Cacey Stevens, Cox, Noah, Zheng, Hu, and Behringer, Robert P.

Abstract

When a solid projectile impacts a granular target, it experiences a drag force and abruptly comes to rest as its momentum transfers to the grains. An empirical drag force law successfully describes the force experienced by the projectile, and the corresponding grain-scale mechanisms have been deciphered for normal impacts. However, there is little work exploring non-normal impacts. Accordingly, we extend studies to explore oblique impact, in which a significant horizontal component of the drag force is present. In our experiments, a projectile impacts a quasi-two-dimensional bed of bidisperse photoelastic grains. We use high-speed imaging to measure high-resolution position data of the projectile trajectory and simultaneously visualize particle-scale force propagation in the granular medium. When the impact angle becomes important, the spatial structure of the stress response reveals relatively weak force chain propagation in the horizontal direction. Based on these observations, we describe the decrease of the inertial drag force with impact angle. [ABSTRACT FROM AUTHOR]

Published

2020