TY - JOUR
T1 - Desaturation via biogenic gas formation as a ground improvement technique
AU - van Paassen, Leon
AU - Pham, Vinh
AU - Mahabadi Mahabad, Nariman
AU - Hall, Caitlyn
AU - Stallings, Elizabeth
AU - Kavazanjian, Edward
N1 - Funding Information:
This work was supported by the National Science Foundation (NSF) under grant EEC-1449501 The authors are grateful for NSF support. Any opinions or positions expressed in this paper are the opinions and positions of the authors only and do not reflect any opinions or positions of the NSF.
Publisher Copyright:
© 2017 ASCE.
PY - 2018
Y1 - 2018
N2 - Desaturation by biogenic gas formation can significantly affect the hydro-mechanical behaviour of soil. The high compressibility of the gas dampens pore pressure build up during both monotonic and cyclic undrained loading. Stimulating biogenic gas production therefore has potential as a ground improvement method to mitigate the risk of both static liquefaction and earthquake induced liquefaction. However, gas generated below the ground water table at shallow depth may also constitute a hazard for offshore foundations and terrestrial deposits, as a sudden release of trapped gas may cause instability. In order to evaluate the potential use of biogenic gas for geotechnical applications it is essential to be able to predict gas production and assess its effect on the hydro-mechanical behaviour of a soil. A basic theoretical framework to estimate the volume of gas produced by a biogenic process and the related degree of saturation, experimental results on the rate of gas generation, and its impact on soil behavior are presented herein.
AB - Desaturation by biogenic gas formation can significantly affect the hydro-mechanical behaviour of soil. The high compressibility of the gas dampens pore pressure build up during both monotonic and cyclic undrained loading. Stimulating biogenic gas production therefore has potential as a ground improvement method to mitigate the risk of both static liquefaction and earthquake induced liquefaction. However, gas generated below the ground water table at shallow depth may also constitute a hazard for offshore foundations and terrestrial deposits, as a sudden release of trapped gas may cause instability. In order to evaluate the potential use of biogenic gas for geotechnical applications it is essential to be able to predict gas production and assess its effect on the hydro-mechanical behaviour of a soil. A basic theoretical framework to estimate the volume of gas produced by a biogenic process and the related degree of saturation, experimental results on the rate of gas generation, and its impact on soil behavior are presented herein.
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U2 - 10.1061/9780784481677.013
DO - 10.1061/9780784481677.013
M3 - Conference article
AN - SCOPUS:85049737468
SN - 0895-0563
VL - 2017-November
SP - 244
EP - 256
JO - Geotechnical Special Publication
JF - Geotechnical Special Publication
IS - GSP 300
T2 - 2nd Pan-American Conference on Unsaturated Soils: Plenary Papers, PanAm-UNSAT 2017
Y2 - 12 November 2017 through 15 November 2017
ER -