Mechanical compaction mechanisms in the input sediments of the Sumatra subduction complex – insights from microstructural analysis of cores from IODP Expedition 362
<p>The input sediments of the North Sumatra subduction zone margin, drilled during IODP Expedition 362, exhibit remarkable uniformity in composition and grain size over the entire thickness of the rapidly deposited Nicobar Fan succession (seafloor to 1500 m b.s.f.), providing a unique opportun...
Main Authors: | , , , , |
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Format: | Article |
Language: | English |
Published: |
Copernicus Publications
2022-10-01
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Series: | Solid Earth |
Online Access: | https://se.copernicus.org/articles/13/1513/2022/se-13-1513-2022.pdf |
Summary: | <p>The input sediments of the North Sumatra subduction zone margin, drilled
during IODP Expedition 362, exhibit remarkable uniformity in composition and
grain size over the entire thickness of the rapidly deposited Nicobar Fan
succession (seafloor to 1500 m b.s.f.), providing a unique opportunity to study
the micromechanisms of compaction. Samples were prepared from dried core
samples (from Sites U1480 and U1481) by both Ar-ion cross-section polishing
and broad ion beam cutting and imaged with a field-emission scanning
electron microscope (SEM). The shallowest samples (seafloor to 28 m b.s.f.)
display a sharp reduction in porosity from 80 % to 52 % due to collapse
of large clay-domain surrounding matrix pores associated with rotation and realignment
of clay platelets parallel to the bedding plane. The deeper succession
(28 to 1500 m b.s.f.) exhibits less rapid reduction in porosity from 52 %
to 30 % by the progressive collapse of silt-adjacent larger pores through
bending as well as subsequent sliding and/or fracturing of clay particles. In addition,
there is a correlated loss of porosity in the pores too small to be resolved
by SEM.</p>
<p>Clastic particles show no evidence of deformation or fracturing with
increasing compaction. In the phyllosilicates, there is no evidence for
pressure solution or recrystallization: thus, compaction proceeds by
micromechanical processes. An increase in effective stress up to 18 MPa
(<span class="inline-formula">∼</span> 1500 m b.s.f.) causes the development of a weakly aligned
phyllosilicate fabric mainly defined by illite clay particles and mica
grains, while the roundness of inter-particle pores decreases as the pores
become more elongated. We propose that bending of the phyllosilicates by
inter-particle slip may be the rate-controlling mechanism.</p>
<p>Pore size distributions show that all pores within the compactional force
chain deform, irrespective of size, with increasing compactional strain.
This arises because the force chain driving pore collapse is localized
primarily within the volumetrically dominant and weaker clay-rich domains;
pores associated with packing around isolated silt particles enter into the
force chain asynchronously and do not contribute preferentially to pore loss
over the depth range studied.</p> |
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ISSN: | 1869-9510 1869-9529 |