Heave, settlement and fracture of chalk during physical modelling experiments with temperature cycling above and below 0°C

To elucidate the early stages of heave, settlement and fracture of intact frost-susceptible rock by temperature cycling above and below 0°C, two physical modelling experiments were performed on 10 rectangular blocks 450 mm high of fine-grained, soft limestone. One experiment simulated 21 cycles of b...

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Published in:Geomorphology
Main Authors: Murton, Julian, Ozouf, Jean-Claude, Peterson, Rorik
Format: Article in Journal/Newspaper
Language:English
Published: Elsevier 2016
Subjects:
Ice
permafrost
Online Access:http://sro.sussex.ac.uk/id/eprint/61957/
http://sro.sussex.ac.uk/id/eprint/61957/1/Heave,%20settlement%20and%20fracture%20of%20chalk.%20Accepted%20copy%20pre-proof%20%28archive%29.pdf
https://doi.org/10.1016/j.geomorph.2016.07.016
id ftunivsussex:oai:sro.sussex.ac.uk:61957
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spelling ftunivsussex:oai:sro.sussex.ac.uk:61957 2023-07-30T04:04:04+02:00 Heave, settlement and fracture of chalk during physical modelling experiments with temperature cycling above and below 0°C Murton, Julian Ozouf, Jean-Claude Peterson, Rorik 2016-10-01 application/pdf http://sro.sussex.ac.uk/id/eprint/61957/ http://sro.sussex.ac.uk/id/eprint/61957/1/Heave,%20settlement%20and%20fracture%20of%20chalk.%20Accepted%20copy%20pre-proof%20%28archive%29.pdf https://doi.org/10.1016/j.geomorph.2016.07.016 en eng Elsevier http://sro.sussex.ac.uk/id/eprint/61957/1/Heave,%20settlement%20and%20fracture%20of%20chalk.%20Accepted%20copy%20pre-proof%20%28archive%29.pdf Murton, Julian, Ozouf, Jean-Claude and Peterson, Rorik (2016) Heave, settlement and fracture of chalk during physical modelling experiments with temperature cycling above and below 0°C. Geomorphology, 270. pp. 71-87. ISSN 0169-555X cc_by_nc_4 Article PeerReviewed 2016 ftunivsussex https://doi.org/10.1016/j.geomorph.2016.07.016 2023-07-11T20:33:09Z To elucidate the early stages of heave, settlement and fracture of intact frost-susceptible rock by temperature cycling above and below 0°C, two physical modelling experiments were performed on 10 rectangular blocks 450 mm high of fine-grained, soft limestone. One experiment simulated 21 cycles of bidirectional freezing (upward and downward) of an active layer above permafrost, and the other simulated 26 cycles of unidirectional freezing (downward) of a seasonally frozen bedrock in a non-permafrost region. Heave and settlement of the top of the blocks were monitored in relation to rock temperature and unfrozen water content, which ranged from almost dry to almost saturated. In the bidirectional freezing experiment, heave of the wettest block initially occurred abruptly at the onset of freezing periods and gradually during thawing periods (summer heave). After the crossing of a threshold marked by the appearance of a macrocrack in the upper layer of permafrost, summer heave increased by an order of magnitude as segregated ice accumulated incrementally in macrocracks, interrupted episodically by abrupt settlement that coincided with unusually high air temperatures. In the unidirectional freezing experiment, the wet blocks heaved during freezing periods and settled during thawing periods, whereas the driest blocks showed the opposite behaviour. The two wettest blocks settled progressively during the first 15 freeze-thaw cycles, before starting to heave progressively as macrocracks developed. Four processes, operating singly or in combination in the blocks account for their heave and settlement: (1) thermal expansion and contraction caused heave and settlement when little or no water-ice phase change was involved; (2) volumetric expansion of water freezing in situ caused short bursts of heave of the outer millimetres of wet rock; (3) ice segregation deeper in the blocks caused sustained heave during thawing and freezing periods; and (4) freeze-thaw cycling caused consolidation and settlement of wet blocks prior to ... Article in Journal/Newspaper Ice permafrost University of Sussex: Sussex Research Online Geomorphology 270 71 87
institution Open Polar
collection University of Sussex: Sussex Research Online
op_collection_id ftunivsussex
language English
description To elucidate the early stages of heave, settlement and fracture of intact frost-susceptible rock by temperature cycling above and below 0°C, two physical modelling experiments were performed on 10 rectangular blocks 450 mm high of fine-grained, soft limestone. One experiment simulated 21 cycles of bidirectional freezing (upward and downward) of an active layer above permafrost, and the other simulated 26 cycles of unidirectional freezing (downward) of a seasonally frozen bedrock in a non-permafrost region. Heave and settlement of the top of the blocks were monitored in relation to rock temperature and unfrozen water content, which ranged from almost dry to almost saturated. In the bidirectional freezing experiment, heave of the wettest block initially occurred abruptly at the onset of freezing periods and gradually during thawing periods (summer heave). After the crossing of a threshold marked by the appearance of a macrocrack in the upper layer of permafrost, summer heave increased by an order of magnitude as segregated ice accumulated incrementally in macrocracks, interrupted episodically by abrupt settlement that coincided with unusually high air temperatures. In the unidirectional freezing experiment, the wet blocks heaved during freezing periods and settled during thawing periods, whereas the driest blocks showed the opposite behaviour. The two wettest blocks settled progressively during the first 15 freeze-thaw cycles, before starting to heave progressively as macrocracks developed. Four processes, operating singly or in combination in the blocks account for their heave and settlement: (1) thermal expansion and contraction caused heave and settlement when little or no water-ice phase change was involved; (2) volumetric expansion of water freezing in situ caused short bursts of heave of the outer millimetres of wet rock; (3) ice segregation deeper in the blocks caused sustained heave during thawing and freezing periods; and (4) freeze-thaw cycling caused consolidation and settlement of wet blocks prior to ...
format Article in Journal/Newspaper
author Murton, Julian
Ozouf, Jean-Claude
Peterson, Rorik
spellingShingle Murton, Julian
Ozouf, Jean-Claude
Peterson, Rorik
Heave, settlement and fracture of chalk during physical modelling experiments with temperature cycling above and below 0°C
author_facet Murton, Julian
Ozouf, Jean-Claude
Peterson, Rorik
author_sort Murton, Julian
title Heave, settlement and fracture of chalk during physical modelling experiments with temperature cycling above and below 0°C
title_short Heave, settlement and fracture of chalk during physical modelling experiments with temperature cycling above and below 0°C
title_full Heave, settlement and fracture of chalk during physical modelling experiments with temperature cycling above and below 0°C
title_fullStr Heave, settlement and fracture of chalk during physical modelling experiments with temperature cycling above and below 0°C
title_full_unstemmed Heave, settlement and fracture of chalk during physical modelling experiments with temperature cycling above and below 0°C
title_sort heave, settlement and fracture of chalk during physical modelling experiments with temperature cycling above and below 0°c
publisher Elsevier
publishDate 2016
url http://sro.sussex.ac.uk/id/eprint/61957/
http://sro.sussex.ac.uk/id/eprint/61957/1/Heave,%20settlement%20and%20fracture%20of%20chalk.%20Accepted%20copy%20pre-proof%20%28archive%29.pdf
https://doi.org/10.1016/j.geomorph.2016.07.016
genre Ice
permafrost
genre_facet Ice
permafrost
op_relation http://sro.sussex.ac.uk/id/eprint/61957/1/Heave,%20settlement%20and%20fracture%20of%20chalk.%20Accepted%20copy%20pre-proof%20%28archive%29.pdf
Murton, Julian, Ozouf, Jean-Claude and Peterson, Rorik (2016) Heave, settlement and fracture of chalk during physical modelling experiments with temperature cycling above and below 0°C. Geomorphology, 270. pp. 71-87. ISSN 0169-555X
op_rights cc_by_nc_4
op_doi https://doi.org/10.1016/j.geomorph.2016.07.016
container_title Geomorphology
container_volume 270
container_start_page 71
op_container_end_page 87
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