Skip Nav Destination
Close Modal
![]()
![]()
![]()
![]()
![]()
![]()
![]()
![]()
![]()
![Lusi mud volcano, east Java (Latitude: −7.528495°, Longitude: 112.711232°). (a) November, 2006. Histogram of frequencies of azimuthal direction for two-point azimuth technique for active vents in 2006. (b) 30 September 2009. Histogram of frequencies of azimuthal direction for two-point azimuth technique for active vents in 2009. (c) January 2010. Histogram of frequencies of azimuthal direction for two-point azimuth technique for active vents in 2010. Blue dashed line shows trace of Kendensari River. The blue triangles represent ‘bubbles' that are or were currently active at that time. Red dashed lines indicate faults described by Istadi et al. (2009). Images courtesy of CRISP.]()
![Schematic diagram of the mode of formation of Lusi mud volcano and how its vent systems have evolved through time. (a) May 2006 with its initial NE–SW vent alignment. (b) January 2010 with the initiation of caldera collapse with vents aligning along reactivated east–west-trending anticline crestal faulting. (c) Predicted future development including elongate caldera collapse structure with vents aligning along caldera ring faults.]()
![(a) Stratigraphic column for the LUSI mud volcano. (b) Schematic diagram of conceptual model.]()
![]()
![]()
![]()
![Examples of the some of the social impacts of mobile shales. (a) Local people praying to the Lusi mud volcano (East Java, Indonesia) for the end of the mud flow (known as Sidoarjo mud flow or Lumpur Lapindo in the local Indonesian language). Photograph by Mark Tingay, taken in May 2007 (one year after the disaster started). (b) Group of tourists visiting Xin Yung Nu Hu mud volcano in southwest Taiwan. The guide has started the fire in the mud pool due to the methane emissions from the mud vent. Inset: Tourist sign advertising the site of the Hsiao Gun Shui mud volcano in southwest Taiwan. The Chinese characters read (left to right): mud, fire, and mountain, which is mud volcano.]()
![(a) Major structural elements of eastern Azerbaijan after Jackson et al. (2002), showing the location of the mud volcanoes in this study (localities marked with blue stars; see inset for global location). (b) Major structural elements of the east Java Basin, after Geological Survey of Indonesia (1963), showing the location of Lusi mud volcano (marked with a star) and main faults marked in red (see inset for global location).]()
![(a) Previously published velocity data for BJP-1, check-shot velocity data, raw field-processed sonic log data, and the final carefully processed and corrected compressional sonic velocity data presented herein. (b) BJP-1 casing points, formations, and lithologies. (c) Caliper log data from BJP-1. (d) BJP-1 measured S-wave slowness (DTS) and consistent estimates of shallow DTS made using four different methods. Previously published sonic velocity data (Lapindo and Schlumberger, 2006; Istadi et al., 2009, 2012; Lupi et al., 2013, 2014) contain numerous errors and artifacts for the entire length of the BJP-1 wellbore. Errors include inclusion of casing velocities, high- and low-velocity acquisition artifacts caused by borehole rugosity and breakout, and artifacts generated by improper, rapid, or unchecked processing. All previously published velocity models are spurious and unreliable and should not be used for any studies on the Lusi mud volcano.]()
![BJP-1 lithology, formations, casing points, and available petrophysical data, as well as available petrophysical data from the Wunut Field and Porong-1 well, all located within 7 km of the Lusi mud volcano (original data sourced from Kusumastuti et al., 2000, 2002; Lapindo and Schlumberger, 2006; Mazzini et al., 2007; Istadi et al., 2009, 2012; Sawolo et al., 2009; Tanikawa et al., 2010; Lupi et al., 2014). All depths are in meters true vertical depth relative to the rotary table. Petrophysical data have been carefully processed, checked, and corrected for significant errors caused by the poor logging conditions (see the caliper log). Density data have been estimated for some sections from P-wave velocity data, as per the Gardner et al. (1974) relationship, and they provide a good match to measured data from BJP-1 and offset wells. Shallow S-wave sonic slowness data have been estimated using the Castagna et al. (1985) method, Lee (2010) method, and by fuzzy logic and genetic algorithm methods (Rajabi et al., 2010), and they provide a reliable match to measured S-wave data. Porosity estimates from sonic, density, and corrected neutron porosity log data all yield consistent results and suggest that the shales have relatively constant porosities (35%–45%) with depth, and the volcanic sequences have very low porosities (2%–10%).]()
![]()
![]()
![]()
![]()
![]()
![]()
![]()
![]()
![]()
![]()
![]()
![]()
![]()
![]()
![]()
![]()
![]()
![]()
![]()
![]()
![]()
1-20 OF 40 RESULTS FOR
Lusi mud volcano
Results shown limited to content with bounding coordinates.
Follow your search
Access your saved searches in your account
Would you like to receive an alert when new items match your search?
1
Book Chapter
Understanding the trigger for the LUSI mud volcano eruption from ground deformation signatures Available to Purchase
Series: Geological Society, London, Special Publications
Publisher: Geological Society of London
Published: 01 January 2017
EISBN: 9781862399709
... Abstract The LUSI mud volcano in the sub-district of Porong, Sidoarjo, East Java, Indonesia started to erupt on 29 May 2006. An almost continuous eruption of a mixture of mud, water and gas has occurred around this area since this date. The eruption triggered vertical and horizontal ground...
Journal Article
Initial pore pressures under the Lusi mud volcano, Indonesia Available to Purchase
Journal: Interpretation
Publisher: Society of Exploration Geophysicists
Published: 15 December 2014
Interpretation (2015) 3 (1): SE33–SE49.
...Mark Tingay Abstract The Lusi mud volcano of East Java, Indonesia, remains one of the most unusual geologic disasters of modern times. Since its sudden birth in 2006, Lusi has erupted continuously, expelling more than 90 million cubic meters of mud that has displaced approximately 40,000 people...
FIGURES
| View All (5)
Journal Article
Probabilistic longevity estimate for the LUSI mud volcano, East Java Available to Purchase
Journal: Journal of the Geological Society
Publisher: Geological Society of London
Published: 01 March 2011
Journal of the Geological Society (2011) 168 (2): 517–523.
...Richard J. Davies; Simon A. Mathias; Richard E. Swarbrick; Mark J. Tingay Abstract: A new method for estimating the duration of a mud volcano eruption is applied to the LUSI mud volcano in East Java. The estimate is based upon carbonates at depths in the range 2500–3500 m being the water source...
FIGURES
| View All (7)
Journal Article
Structural controls on mud volcano vent distributions: examples from Azerbaijan and Lusi, east Java Available to Purchase
Journal: Journal of the Geological Society
Publisher: Geological Society of London
Published: 01 July 2011
Journal of the Geological Society (2011) 168 (4): 1013–1030.
...Katie S. Roberts; Richard J. Davies; Simon A. Stewart; Mark Tingay Abstract: Structural mapping, nearest neighbour and two-point azimuth statistical analysis of mud volcano vent distributions from nine examples in Azerbaijan and the Lusi mud volcano in east Java are described. Distributions are non...
FIGURES
| View All (12)
Image
Lusi mud volcano, east Java (Latitude: −7.528495°, Longitude: 112.711232°).... Available to Purchase
in Structural controls on mud volcano vent distributions: examples from Azerbaijan and Lusi, east Java
> Journal of the Geological Society
Published: 01 July 2011
Fig. 9. Lusi mud volcano, east Java (Latitude: −7.528495°, Longitude: 112.711232°). ( a ) November, 2006. Histogram of frequencies of azimuthal direction for two-point azimuth technique for active vents in 2006. ( b ) 30 September 2009. Histogram of frequencies of azimuthal direction for two
Image
Schematic diagram of the mode of formation of Lusi mud volcano and how its ... Available to Purchase
in Structural controls on mud volcano vent distributions: examples from Azerbaijan and Lusi, east Java
> Journal of the Geological Society
Published: 01 July 2011
Fig. 12. Schematic diagram of the mode of formation of Lusi mud volcano and how its vent systems have evolved through time. ( a ) May 2006 with its initial NE–SW vent alignment. ( b ) January 2010 with the initiation of caldera collapse with vents aligning along reactivated east–west-trending
Image
( a ) Stratigraphic column for the LUSI mud volcano. ( b ) Schematic diagra... Available to Purchase
in Probabilistic longevity estimate for the LUSI mud volcano, East Java
> Journal of the Geological Society
Published: 01 March 2011
Fig. 3. ( a ) Stratigraphic column for the LUSI mud volcano. ( b ) Schematic diagram of conceptual model.
Journal Article
Triggering of the Lusi mud eruption: Earthquake versus drilling initiation Available to Purchase
Journal: Geology
Publisher: Geological Society of America
Published: 01 August 2008
Geology (2008) 36 (8): 639–642.
...Mark Tingay; Oliver Heidbach; Richard Davies; Richard Swarbrick Abstract The Lusi mud volcano in East Java has erupted unabated for almost 2 yr, flooding an area of 7 km 2 and displacing more than 25,000 people. Despite its disastrous impact, the mechanism for triggering the Lusi eruption remains...
FIGURES
Image
Examples of the some of the social impacts of mobile shales. (a) Local peop... Available to Purchase
in Introduction to the special section: Mobile shales — Historical perspective, seismic expression, and open questions
> Interpretation
Published: 06 November 2024
Figure 7. Examples of the some of the social impacts of mobile shales. (a) Local people praying to the Lusi mud volcano (East Java, Indonesia) for the end of the mud flow (known as Sidoarjo mud flow or Lumpur Lapindo in the local Indonesian language). Photograph by Mark Tingay, taken in May 2007
Image
( a ) Major structural elements of eastern Azerbaijan after Jackson et al... Available to Purchase
in Structural controls on mud volcano vent distributions: examples from Azerbaijan and Lusi, east Java
> Journal of the Geological Society
Published: 01 July 2011
Survey of Indonesia (1963 ), showing the location of Lusi mud volcano (marked with a star) and main faults marked in red (see inset for global location).
Image
(a) Previously published velocity data for BJP-1, check-shot velocity data,... Available to Purchase
Published: 15 December 2014
and unreliable and should not be used for any studies on the Lusi mud volcano.
Journal Article
Introduction to special section: Abnormal pore pressure Available to Purchase
Journal: Interpretation
Publisher: Society of Exploration Geophysicists
Published: 12 February 2015
Interpretation (2015) 3 (1): SEi.
... presents the first corrected data set of petrophysical and pore pressures for the Lusi mud volcano in Indonesia, highlighting that high magnitude overpressures are observed from shallow (350 m) depths. The results of this study provide key new evidence indicating that this disaster was triggered...
Image
BJP-1 lithology, formations, casing points, and available petrophysical dat... Available to Purchase
Published: 15 December 2014
Figure 1. BJP-1 lithology, formations, casing points, and available petrophysical data, as well as available petrophysical data from the Wunut Field and Porong-1 well, all located within 7 km of the Lusi mud volcano (original data sourced from Kusumastuti et al., 2000 , 2002 ; Lapindo
Journal Article
Introduction to the special section: Mobile shales — Historical perspective, seismic expression, and open questions Available to Purchase
Journal: Interpretation
Publisher: Society of Exploration Geophysicists
Published: 06 November 2024
Interpretation (2024) 12 (4): SFi–SFxxxi.
...Figure 7. Examples of the some of the social impacts of mobile shales. (a) Local people praying to the Lusi mud volcano (East Java, Indonesia) for the end of the mud flow (known as Sidoarjo mud flow or Lumpur Lapindo in the local Indonesian language). Photograph by Mark Tingay, taken in May 2007...
FIGURES
| View All (8)
Journal Article
Crater formation during the onset of mud volcanism Available to Purchase
Journal: Geology
Publisher: Geological Society of America
Published: 20 January 2023
Geology (2023) 51 (3): 252–256.
..., producing gas flares ( Mazzini et al., 2021 ). Mud volcanoes have wide significance for society ( Tingay et al., 2015 ), both as geohazards in their own right (e.g., the Lusi [Indonesia] eruption, during which a mud flow displaced >30,000 people; Mazzini et al., 2007 ; Davies et al., 2008...
FIGURES
Journal Article
Recurring Emergence of the Mud Islands on Shelf of the Arabian Sea along the Makran Coast of Pakistan – Historical Perspective Using Remote Sensing Techniques Available to Purchase
Publisher: Geological Society of India
Published: 01 August 2017
Jour. Geol. Soc. India (2017) 90 (2): 201–208.
... , K.W. (2008) The Wister mud pot lineament: Southeastwardextension or abandoned strand of the San Andreas fault? Bull. Seismol. Soc. Amer ., v. 98 , pp. 1720 – 1729 . Manga , M. (2007) Did an earthquake trigger the May 2006 eruption of the Lusi Mud Volcano? EoS, Trans. Ameri...
FIGURES
| View All (6)
Journal Article
Engineering geomorphological reconnaissance of the December 2018 Waimata Valley mud volcano eruption, Gisborne, New Zealand Available to Purchase
Publisher: Geological Society of London
Published: 01 July 2022
Quarterly Journal of Engineering Geology and Hydrogeology (2022) 55 (4): qjegh2021-149.
.... and Svensen , H. 2009 . Strike-slip faulting as a trigger mechanism for overpressure release through piercement structures. Implications for the Lusi mud volcano, Indonesia . Marine and Petroleum Geology , 26 , 1751 – 1765 , https://doi.org/10.1016/j.marpetgeo.2009.03.001 Meehan , C.L...
FIGURES
| View All (8)
Journal Article
World's largest extrusive body of sand? Available to Purchase
Journal: Geology
Publisher: Geological Society of America
Published: 01 May 2012
Geology (2012) 40 (5): 467–470.
.... Implications for the Lusi mud volcano, Indonesia : Marine and Petroleum Geology , v. 26 , p. 1751 – 1765 , doi:10.1016/j.marpetgeo.2009.03.001 . Mondol N.H. Bjørlykke K. Jahren J. , 2008 , Experimental compaction of clays: Relationship between permeability and petrophysical properties...
FIGURES
| View All (4)
Journal Article
Sector collapse of mud volcanoes, Azerbaijan Available to Purchase
Journal: Journal of the Geological Society
Publisher: Geological Society of London
Published: 01 January 2011
Journal of the Geological Society (2011) 168 (1): 49–60.
... 10.1029/2001JB000657 Manga M. Did an earthquake trigger the May 2006 eruption of the Lusi Mud Volcano? EOS Transactions, American Geophysical Union 2007 88 10.1029/2007EO180009 Manga M. Brumm M. Rudolph M. L. Earthquake triggering of mud volcanoes Marine and Petroleum...
FIGURES
| View All (12)
Journal Article
Myth busting: Was Pulau Tiga really first created by a mud volcano eruption in 1897? Available to Purchase
Journal: Interpretation
Publisher: Society of Exploration Geophysicists
Published: 07 August 2024
Interpretation (2024) 12 (4): SF1–SF16.
.... J. Mathias S. Swarbrick R. E. Tingay M. , 2011 , Probabilistic longevity estimate for the LUSI mud volcano, East Java : Journal of the Geological Society, London , 168 , 517 – 523 , doi: http://dx.doi.org/10.1144/0016-76492010-129 . Davies R. J. Swarbrick R. E...
FIGURES
| View All (7)
1
