A new instrument for high-resolution in situ assessment of Young’s modulus in shallow cohesive sediments

A new instrument for high-resolution in situ assessment of Young’s modulus in shallow cohesive sediments

This paper describes a new, miniature, instrumented flat dilatometer (mIDMT) designed to assess variations in nearly continuous compressive stress–strain behaviour with depth in shallow cohesive sediments. The instrument was tested both in situ in the Bay of Fundy, Nova Scotia, Canada, and in cored...

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Bibliographic Details
Published in:Geo-marine letters Vol. 32; no. 4; pp. 349 - 357
Main Authors: Barry, Mark A., Johnson, Bruce D., Boudreau, Bernard P.
Format: Journal Article
Language:English
Published: Berlin/Heidelberg Springer-Verlag 01-08-2012
Springer Nature B.V
Subjects:
Cohesive sediments
Earth and Environmental Science
Earth Sciences
Geology
Geomorphology
Geophysics
Marine
Porosity
Scientific apparatus & instruments
Sedimentation & deposition
Stress-strain curves
Technical Paper
Tidal flats
ANW, Canada, Fundy Bay, Minas Basin
ANW, Canada, Fundy Bay
ANW, Canada, Nova Scotia
INE, USA, Washington, Willapa Bay
Linear Elastic Fracture Mechanic
Foam Rubber
Bubble Growth
Rubber Membrane
Tidal Flat Sediment
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Summary:This paper describes a new, miniature, instrumented flat dilatometer (mIDMT) designed to assess variations in nearly continuous compressive stress–strain behaviour with depth in shallow cohesive sediments. The instrument was tested both in situ in the Bay of Fundy, Nova Scotia, Canada, and in cored samples from Willapa Bay, Washington, USA. Comparisons between probe and laboratory uniaxial assessments for other elastic materials—gelatine and foam rubber specifically—show strong agreement over the range of strains induced in the experiments. Observed values of Young’s modulus ( E ) for the gelatine and ethylene-vinyl acetate foam ranged from 6–343 kPa. Sediment stress–strain curves were distinctly linear for the overconsolidated fine-grained sediments of the Minas Basin, and values of E were found to increase with depth from near zero to 500–1,300 kPa at 20 cm depth. At the Willapa site, the sandy tidal flat sediments also behave elastically but E tended to increase more strongly with depth than for sediments from the Minas Basin. Young’s modulus was inversely correlated to porosity at all sites tested, and linearly related to shear strength in the Minas Basin. The newly designed instrument has much finer resolution than for other, similar methods of determining E in situ, and it provides data at a resolution sufficient to assess small-scale processes such as gas bubble growth and infaunal locomotion, for which elastic constants are needed for modelling and prediction.
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ISSN:0276-0460
1432-1157
DOI:10.1007/s00367-012-0277-z