Liquefaction structures induced by the M5.7 earthquake on May 28, 2018 in Songyuan, Jilin Province, NE China and research implication

Zhu Fu Shao; Jian Hua Zhong; John Howell; Bing Hao; Xi Wu Luan; Ze Xuan Liu; Wei Min Ran; Yun Feng Zhang; Hong Qi Yuan; Jing Jing Liu; Liang Tian Ni; Guan Xian Song; Jin Lin Liu; Wen Xin Zhang; Bing Zhao

doi:10.1186/s42501-019-0053-3

Liquefaction structures induced by the M5.7 earthquake on May 28, 2018 in Songyuan, Jilin Province, NE China and research implication

Zhu Fu Shao^* (Corresponding Author), Jian Hua Zhong, John Howell, Bing Hao, Xi Wu Luan, Ze Xuan Liu, Wei Min Ran, Yun Feng Zhang, Hong Qi Yuan, Jing Jing Liu, Liang Tian Ni, Guan Xian Song, Jin Lin Liu, Wen Xin Zhang, Bing Zhao

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

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Abstract

An earthquake of magnitude M5.7 occurred in Yamutu village, Songyuan City, Jilin Province, NE China (45°16′12″N/124°42′35″E) on May 28, 2018, with a focal depth of 13 km. The epicenter is located at the intersection of the Fuyu/Songyuan-Zhaodong Fault, Second Songhua River Fault and Fuyu North Fault which lies northwest of Tancheng-Lujiang Fault (Tan-Lu Fault). The earthquake-induced widespread liquefaction structures and ground surface fissures within 3 km from the epicenter, caused serious disasters to the local surroundings. The visible liquefied structures include sand volcanoes, liquefied sand mounds, sand dikes and sand sills. Sand volcanoes can be divided into sand volcano with a crater, sand volcano without a crater and water volcano (no sand). Other soft-sediment deformation structures (SSDS) induced by the earthquake include deformation lamination, load and flame structures, deformation folds, dish structures, convolute bedding and water-escape structures. The formation process of the sand volcanoes comprises three stages: (1) building up excess pore-fluid pressure in the liquefied layer, (2) cracking of the low-permeable overlying layer, and (3) mixture of sand-water venting out of the ground surface. During the upward movement, the liquefied sand is injected into the low-permeable layer to form sand veins, sand sills and various types of deformation structures. Vertical distribution of seismic liquefaction structure can be divided into four zones: the thoroughly liquefied zone, the lower liquefied zone with SSDS, the upper liquefied zone with SSDS, and the ground surface liquefied zone. The liquefaction occurred at a burial depth of 2–5 m, and the thickness of liquefied sand is 2 m. NE-SW (35°–215°) trending compressive stress is possibly the seismogenic trigger of the Songyuan M5.7 earthquake that caused the fault (Fuyu/Songyuan-Zhaodong Fault) to reactivate. The study of the Songyuan seismic liquefaction structures gives insight into the prediction of modern earthquakes and disaster-prone areas. Meanwhile it provides abundant basic material for studying earthquake-induced SSDS in both ancient and modern sediments. The research is obviously of great significance to reveal that the northern Tan-Lu Fault has entered a stage of active seismic activity since the twenty-first century.

Original language	English
Article number	3
Number of pages	19
Journal	Journal of Palaeogeography
Volume	9
DOIs	https://doi.org/10.1186/s42501-019-0053-3
Publication status	Published - 4 Feb 2020

Bibliographical note

Acknowledgements
Many thanks to Yang Wang, Wei Chen and Dong-Hao Peng from Jilin Oilfield
for their help in the field investigation. We thank Dr. Lv Wang from Monash
University and Dr. Gail Maxwell from the University of Aberdeen for their
valuable advice on sedimentology, and we also thank Dr. Gui-Dong Ping and
Dr. Zhao-Han Xie for the discussion we had about the regional tectonic
stress field. We are grateful to Professor Zeng-Zhao Feng, editors and two
anonymous reviewers for their editorial work and many constructive comments and suggestions that greatly improved this manuscript.

Funding
This study is supported by the “Natural Science Foundation of Heilongjiang
Province (No. JJ2016ZR0573)”, “Youth Foundation of Northeast Petroleum
University (No. NEPUBS201503)”, “Northeast Petroleum University Scientific
Research Start-up Fund”, “Shandong Provincial Key Laboratory of Depositional Mineralization and Mineral Foundation (No. DMSMZO17009)”, and
“Natural Science Foundation of Shandong Province (No. ZR2016DB15)”.

Authors’ contributions
ZFS applied for the funding, performed the research, analyzed the data,
compiled a few figures and wrote the manuscript. JHZ designed the work,
took part in the field trip and interpreted the data. JH interpreted part of the
data and revised the manuscript. BH took part in the field trip, collected data
and compiled Fig. 5. XWL interpreted part of the data and revised the
manuscript. ZXL collected papers and completed some figures. WMR
collected some data and compiled Fig. 2. YFZ, HQY, and JLL interpreted
some of the data. LTN and GXS took part in fieldwork and collected data.
JJL, WXZ and BZ interpreted some data and compiled some figures. All
authors approved the final manuscript.

Availability of data and materials
All data generated or analyzed during this study are included in this
published article. Additional data related to this paper can be requested
from the corresponding author.

Keywords

Earthquake
Liquefaction structure
Sand volcano
Soft-sediment deformation structures
Songyuan
SOFT-SEDIMENT-DEFORMATION
SEISMITES
LACUSTRINE DEPOSITS
FEATURES
SANDSTONE INTRUSIONS
SAND VOLCANOS
BASIN
MUD VOLCANO
LATE MIOCENE
FLUIDIZATION

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Cite this

Shao, Z. F., Zhong, J. H., Howell, J., Hao, B., Luan, X. W., Liu, Z. X., Ran, W. M., Zhang, Y. F., Yuan, H. Q., Liu, J. J., Ni, L. T., Song, G. X., Liu, J. L., Zhang, W. X., & Zhao, B. (2020). Liquefaction structures induced by the M5.7 earthquake on May 28, 2018 in Songyuan, Jilin Province, NE China and research implication. Journal of Palaeogeography, 9, Article 3. https://doi.org/10.1186/s42501-019-0053-3

@article{4e890899d5eb4a2688caf561e54479c5,

title = "Liquefaction structures induced by the M5.7 earthquake on May 28, 2018 in Songyuan, Jilin Province, NE China and research implication",

abstract = "An earthquake of magnitude M5.7 occurred in Yamutu village, Songyuan City, Jilin Province, NE China (45°16′12″N/124°42′35″E) on May 28, 2018, with a focal depth of 13 km. The epicenter is located at the intersection of the Fuyu/Songyuan-Zhaodong Fault, Second Songhua River Fault and Fuyu North Fault which lies northwest of Tancheng-Lujiang Fault (Tan-Lu Fault). The earthquake-induced widespread liquefaction structures and ground surface fissures within 3 km from the epicenter, caused serious disasters to the local surroundings. The visible liquefied structures include sand volcanoes, liquefied sand mounds, sand dikes and sand sills. Sand volcanoes can be divided into sand volcano with a crater, sand volcano without a crater and water volcano (no sand). Other soft-sediment deformation structures (SSDS) induced by the earthquake include deformation lamination, load and flame structures, deformation folds, dish structures, convolute bedding and water-escape structures. The formation process of the sand volcanoes comprises three stages: (1) building up excess pore-fluid pressure in the liquefied layer, (2) cracking of the low-permeable overlying layer, and (3) mixture of sand-water venting out of the ground surface. During the upward movement, the liquefied sand is injected into the low-permeable layer to form sand veins, sand sills and various types of deformation structures. Vertical distribution of seismic liquefaction structure can be divided into four zones: the thoroughly liquefied zone, the lower liquefied zone with SSDS, the upper liquefied zone with SSDS, and the ground surface liquefied zone. The liquefaction occurred at a burial depth of 2–5 m, and the thickness of liquefied sand is 2 m. NE-SW (35°–215°) trending compressive stress is possibly the seismogenic trigger of the Songyuan M5.7 earthquake that caused the fault (Fuyu/Songyuan-Zhaodong Fault) to reactivate. The study of the Songyuan seismic liquefaction structures gives insight into the prediction of modern earthquakes and disaster-prone areas. Meanwhile it provides abundant basic material for studying earthquake-induced SSDS in both ancient and modern sediments. The research is obviously of great significance to reveal that the northern Tan-Lu Fault has entered a stage of active seismic activity since the twenty-first century.",

keywords = "Earthquake, Liquefaction structure, Sand volcano, Soft-sediment deformation structures, Songyuan, SOFT-SEDIMENT-DEFORMATION, SEISMITES, LACUSTRINE DEPOSITS, FEATURES, SANDSTONE INTRUSIONS, SAND VOLCANOS, BASIN, MUD VOLCANO, LATE MIOCENE, FLUIDIZATION",

author = "Shao, {Zhu Fu} and Zhong, {Jian Hua} and John Howell and Bing Hao and Luan, {Xi Wu} and Liu, {Ze Xuan} and Ran, {Wei Min} and Zhang, {Yun Feng} and Yuan, {Hong Qi} and Liu, {Jing Jing} and Ni, {Liang Tian} and Song, {Guan Xian} and Liu, {Jin Lin} and Zhang, {Wen Xin} and Bing Zhao",

note = "Acknowledgements Many thanks to Yang Wang, Wei Chen and Dong-Hao Peng from Jilin Oilfield for their help in the field investigation. We thank Dr. Lv Wang from Monash University and Dr. Gail Maxwell from the University of Aberdeen for their valuable advice on sedimentology, and we also thank Dr. Gui-Dong Ping and Dr. Zhao-Han Xie for the discussion we had about the regional tectonic stress field. We are grateful to Professor Zeng-Zhao Feng, editors and two anonymous reviewers for their editorial work and many constructive comments and suggestions that greatly improved this manuscript. Funding This study is supported by the “Natural Science Foundation of Heilongjiang Province (No. JJ2016ZR0573)”, “Youth Foundation of Northeast Petroleum University (No. NEPUBS201503)”, “Northeast Petroleum University Scientific Research Start-up Fund”, “Shandong Provincial Key Laboratory of Depositional Mineralization and Mineral Foundation (No. DMSMZO17009)”, and “Natural Science Foundation of Shandong Province (No. ZR2016DB15)”. Authors{\textquoteright} contributions ZFS applied for the funding, performed the research, analyzed the data, compiled a few figures and wrote the manuscript. JHZ designed the work, took part in the field trip and interpreted the data. JH interpreted part of the data and revised the manuscript. BH took part in the field trip, collected data and compiled Fig. 5. XWL interpreted part of the data and revised the manuscript. ZXL collected papers and completed some figures. WMR collected some data and compiled Fig. 2. YFZ, HQY, and JLL interpreted some of the data. LTN and GXS took part in fieldwork and collected data. JJL, WXZ and BZ interpreted some data and compiled some figures. All authors approved the final manuscript. Availability of data and materials All data generated or analyzed during this study are included in this published article. Additional data related to this paper can be requested from the corresponding author.",

year = "2020",

month = feb,

day = "4",

doi = "10.1186/s42501-019-0053-3",

language = "English",

volume = "9",

journal = "Journal of Palaeogeography",

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TY - JOUR

T1 - Liquefaction structures induced by the M5.7 earthquake on May 28, 2018 in Songyuan, Jilin Province, NE China and research implication

AU - Shao, Zhu Fu

AU - Zhong, Jian Hua

AU - Howell, John

AU - Hao, Bing

AU - Luan, Xi Wu

AU - Liu, Ze Xuan

AU - Ran, Wei Min

AU - Zhang, Yun Feng

AU - Yuan, Hong Qi

AU - Liu, Jing Jing

AU - Ni, Liang Tian

AU - Song, Guan Xian

AU - Liu, Jin Lin

AU - Zhang, Wen Xin

AU - Zhao, Bing

N1 - Acknowledgements Many thanks to Yang Wang, Wei Chen and Dong-Hao Peng from Jilin Oilfield for their help in the field investigation. We thank Dr. Lv Wang from Monash University and Dr. Gail Maxwell from the University of Aberdeen for their valuable advice on sedimentology, and we also thank Dr. Gui-Dong Ping and Dr. Zhao-Han Xie for the discussion we had about the regional tectonic stress field. We are grateful to Professor Zeng-Zhao Feng, editors and two anonymous reviewers for their editorial work and many constructive comments and suggestions that greatly improved this manuscript. Funding This study is supported by the “Natural Science Foundation of Heilongjiang Province (No. JJ2016ZR0573)”, “Youth Foundation of Northeast Petroleum University (No. NEPUBS201503)”, “Northeast Petroleum University Scientific Research Start-up Fund”, “Shandong Provincial Key Laboratory of Depositional Mineralization and Mineral Foundation (No. DMSMZO17009)”, and “Natural Science Foundation of Shandong Province (No. ZR2016DB15)”. Authors’ contributions ZFS applied for the funding, performed the research, analyzed the data, compiled a few figures and wrote the manuscript. JHZ designed the work, took part in the field trip and interpreted the data. JH interpreted part of the data and revised the manuscript. BH took part in the field trip, collected data and compiled Fig. 5. XWL interpreted part of the data and revised the manuscript. ZXL collected papers and completed some figures. WMR collected some data and compiled Fig. 2. YFZ, HQY, and JLL interpreted some of the data. LTN and GXS took part in fieldwork and collected data. JJL, WXZ and BZ interpreted some data and compiled some figures. All authors approved the final manuscript. Availability of data and materials All data generated or analyzed during this study are included in this published article. Additional data related to this paper can be requested from the corresponding author.

PY - 2020/2/4

Y1 - 2020/2/4

N2 - An earthquake of magnitude M5.7 occurred in Yamutu village, Songyuan City, Jilin Province, NE China (45°16′12″N/124°42′35″E) on May 28, 2018, with a focal depth of 13 km. The epicenter is located at the intersection of the Fuyu/Songyuan-Zhaodong Fault, Second Songhua River Fault and Fuyu North Fault which lies northwest of Tancheng-Lujiang Fault (Tan-Lu Fault). The earthquake-induced widespread liquefaction structures and ground surface fissures within 3 km from the epicenter, caused serious disasters to the local surroundings. The visible liquefied structures include sand volcanoes, liquefied sand mounds, sand dikes and sand sills. Sand volcanoes can be divided into sand volcano with a crater, sand volcano without a crater and water volcano (no sand). Other soft-sediment deformation structures (SSDS) induced by the earthquake include deformation lamination, load and flame structures, deformation folds, dish structures, convolute bedding and water-escape structures. The formation process of the sand volcanoes comprises three stages: (1) building up excess pore-fluid pressure in the liquefied layer, (2) cracking of the low-permeable overlying layer, and (3) mixture of sand-water venting out of the ground surface. During the upward movement, the liquefied sand is injected into the low-permeable layer to form sand veins, sand sills and various types of deformation structures. Vertical distribution of seismic liquefaction structure can be divided into four zones: the thoroughly liquefied zone, the lower liquefied zone with SSDS, the upper liquefied zone with SSDS, and the ground surface liquefied zone. The liquefaction occurred at a burial depth of 2–5 m, and the thickness of liquefied sand is 2 m. NE-SW (35°–215°) trending compressive stress is possibly the seismogenic trigger of the Songyuan M5.7 earthquake that caused the fault (Fuyu/Songyuan-Zhaodong Fault) to reactivate. The study of the Songyuan seismic liquefaction structures gives insight into the prediction of modern earthquakes and disaster-prone areas. Meanwhile it provides abundant basic material for studying earthquake-induced SSDS in both ancient and modern sediments. The research is obviously of great significance to reveal that the northern Tan-Lu Fault has entered a stage of active seismic activity since the twenty-first century.

AB - An earthquake of magnitude M5.7 occurred in Yamutu village, Songyuan City, Jilin Province, NE China (45°16′12″N/124°42′35″E) on May 28, 2018, with a focal depth of 13 km. The epicenter is located at the intersection of the Fuyu/Songyuan-Zhaodong Fault, Second Songhua River Fault and Fuyu North Fault which lies northwest of Tancheng-Lujiang Fault (Tan-Lu Fault). The earthquake-induced widespread liquefaction structures and ground surface fissures within 3 km from the epicenter, caused serious disasters to the local surroundings. The visible liquefied structures include sand volcanoes, liquefied sand mounds, sand dikes and sand sills. Sand volcanoes can be divided into sand volcano with a crater, sand volcano without a crater and water volcano (no sand). Other soft-sediment deformation structures (SSDS) induced by the earthquake include deformation lamination, load and flame structures, deformation folds, dish structures, convolute bedding and water-escape structures. The formation process of the sand volcanoes comprises three stages: (1) building up excess pore-fluid pressure in the liquefied layer, (2) cracking of the low-permeable overlying layer, and (3) mixture of sand-water venting out of the ground surface. During the upward movement, the liquefied sand is injected into the low-permeable layer to form sand veins, sand sills and various types of deformation structures. Vertical distribution of seismic liquefaction structure can be divided into four zones: the thoroughly liquefied zone, the lower liquefied zone with SSDS, the upper liquefied zone with SSDS, and the ground surface liquefied zone. The liquefaction occurred at a burial depth of 2–5 m, and the thickness of liquefied sand is 2 m. NE-SW (35°–215°) trending compressive stress is possibly the seismogenic trigger of the Songyuan M5.7 earthquake that caused the fault (Fuyu/Songyuan-Zhaodong Fault) to reactivate. The study of the Songyuan seismic liquefaction structures gives insight into the prediction of modern earthquakes and disaster-prone areas. Meanwhile it provides abundant basic material for studying earthquake-induced SSDS in both ancient and modern sediments. The research is obviously of great significance to reveal that the northern Tan-Lu Fault has entered a stage of active seismic activity since the twenty-first century.

KW - Earthquake

KW - Liquefaction structure

KW - Sand volcano

KW - Soft-sediment deformation structures

KW - Songyuan

KW - SOFT-SEDIMENT-DEFORMATION

KW - SEISMITES

KW - LACUSTRINE DEPOSITS

KW - FEATURES

KW - SANDSTONE INTRUSIONS

KW - SAND VOLCANOS

KW - BASIN

KW - MUD VOLCANO

KW - LATE MIOCENE

KW - FLUIDIZATION

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U2 - 10.1186/s42501-019-0053-3

DO - 10.1186/s42501-019-0053-3

M3 - Article

AN - SCOPUS:85078927798

SN - 2095-3836

VL - 9

JO - Journal of Palaeogeography

JF - Journal of Palaeogeography

M1 - 3

ER -

Liquefaction structures induced by the M5.7 earthquake on May 28, 2018 in Songyuan, Jilin Province, NE China and research implication

Abstract

Bibliographical note

Keywords

UN SDGs

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