I.Y. Borg scite author profile

In order to make a quantitative study of a purely cataclastic deformation, jacketed cylindrical specimens of dry St. Peter quartz sand of different grain sizes have been deformed under uniform confining pressure and differential load. Results presented illustrate the influence of the deformation on porosity, pore size, grain size, grain fracturing and orientation, and strength. The present experiments, conducted under deliberately restricted conditions, are intended as a first step toward an adequate understanding of the complicated problem of sandstone deformation.Undeformed St. Peter sand grains are unfractured to slightly fractured; contain planes of liquid and gas inclusions which exhibit a decided preference for the prism zone; exhibit a predominance of grains with no undulatory extinction as well as grains which are slightly, moderately, and highly undulatory; contain very few grains showing "deformation" lamellae; have an intercept ratio of 1:1.3:1.7, and a high intercept sphericity (0.77 to 0.79); and appear to have grain shapes controlled by r{1011}, z{0111}, and the prisms. The undeformed sand aggregates exhibit an apparent elongation so that the long axes of the grains tend to lie parallel to the circular section. In addition, the aggregates show a tendency for the optic axes of the grains to form a girdle parallel to the circular section.Fracturing is the most conspicuous feature of the deformed sands. The fracture pattern of specimens deformed under uniform pressure is random. Fracture-orientation patterns reflect the symmetry of the deformation under differential loading conditions. In compressed specimens the fractures tend to lie at small angles to the direction of loading and are probably shear fractures. In extended specimens the late-formed fractures tend to lie normal to the axis of extension and are most probably tensile fractures.Apparent elongation and optic-axis orientations for compressed samples are much like those of undeformed sands. In extension, however, the apparent elongations of the grains undergo a progressive rotation through 90° from their initial positions. This is accompanied by a similar shift in optic-axis orientations and therefore indicates that bodily rotation of grains does occur.There is no evidence that the experimental deformation has produced any "deformation" lamellae or that the over-all undulatory extinction index has been changed. The percentage of moderately and highly undulatory grains decreases, however, indicating that these grains are particularly susceptible to fracturing.For sands of uniform grain size the coarsest sand (250-300 microns) exhibits the greatest compressibility (uniform confining pressure), which correlates with the facts that this sand also exhibits the greatest reduction in porosity, median pore size, median grain size, and the lowest percentage of unbroken grains. The coarsest sand is the strongest in triaxial tests (differential loading). On the other hand, the finest sand (105-125 microns) is the least compressible; it exhibits the leas...

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

I.Y. Borg

Experimental deformation of crystalline rocks

Radioactivity Trapped in Melt Produced by a Nuclear Explosion

Calculated X-ray Powder Patterns for Silicate Minerals

Chapter 6: Experimental Deformation of St. Peter Sand: A Study of Cataclastic Flow

Contact Info

Product

Resources

About