Search

Your search keyword '"Miklius A"' showing total 39 results
Start Over Author "Miklius A" Topic volcano
39 results on '"Miklius A"'

1. Periodic dike intrusions at Kı-lauea volcano, Hawai’i

Author

Asta Miklius and E. K. Montgomery-Brown

Subjects
Dike, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Volcano, Geology, 010502 geochemistry & geophysics, 01 natural sciences, Seismology, 0105 earth and related environmental sciences
Abstract

Forecasting heightened magmatic activity is key to assessing and mitigating global volcanic hazards, including eruptions from lateral rift zones at basaltic volcanoes. At Kı-lauea volcano, Hawai’i (United States), planar dikes intrude its east rift zone (ERZ) and repeatedly affect the same segments. Here we show that Kı-lauea’s upper and middle ERZ dikes in the last four decades intruded at regular intervals of ∼8 or ∼14 yr. Segments with shorter recurrence intervals are adjacent to faster-moving parts of the flank, and ∼1–5 MPa of tension accumulates from flank spreading in the time between dike events. Intrusion frequency was neither advanced nor delayed during magma supply variations, supporting the role of long-term flank motion on the timing of dike intrusions. Although fewer historical dikes have occurred near the 2018 CE eruption site in the lower ERZ and the adjacent slowly sliding lower eastern flank, similar tension accumulated between the 1955 and 2018 eruptions. Regular dike intrusion recurrence intervals indicate the importance of including both extrusive and (commonly neglected) intrusive activity in eruption hazard analyses.

Published
2020

2. Monitoring Network Changes during the 2018 Kīlauea Volcano Eruption

Author

Lopaka Lee, Kevan Kamibayashi, B. Shiro, Carolyn Parcheta, Matthew R. Patrick, Michael H. Zoeller, Patricia A. Nadeau, Ingrid A. Johanson, and Asta Miklius

Subjects
geography, Geophysics, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Volcano, 010502 geochemistry & geophysics, 01 natural sciences, Geology, Seismology, 0105 earth and related environmental sciences
Abstract

In the summer of 2018, Kīlauea Volcano underwent one of its most significant eruptions in the past few hundred years. The volcano’s summit and East Rift Zone magma system partially drained, resulting in a series of occasionally explosive partial caldera collapses, and widespread lava flows in the lower East Rift Zone. The Hawaiian Volcano Observatory (HVO) operates a robust permanent monitoring network of about 250 stations, recording a variety of real-time data streams: seismic (short-period, broadband, strong-motion), infrasound, Global Navigation Satellite Systems (GNSS), tilt, camera, laser rangefinder, and gas geochemistry. During the eruption, HVO staff quickly established 35 new temporary monitoring stations, to better constrain evolving volcanic hazards. The partial collapses of the caldera threatened to disrupt important telemetry links in the HVO monitoring network, and a major effort was undertaken in the midst of the eruption crisis to reroute radio telemetry and maintain continuity of data flow. In the process, a new data center was established in Hilo, to mitigate a long-standing potential single point of failure at the HVO facility. Over the course of the eruption from May through August, lava, ashfall, wildfire, and cliff collapse destroyed or disabled 36 stations. Thousands of earthquakes damaged the main HVO facility at Uēkahuna Bluff, causing staff to evacuate the building and relocate observatory operations in the midst of the eruption response, adding more complexity to the response effort. Throughout these events, the HVO team maintained the monitoring network, provided timely information to the public and emergency managers, and collected valuable scientific data to better understand Kīlauea Volcano.

Published
2020

3. The 2018 rift eruption and summit collapse of Kīlauea Volcano

Author

G. Fisher, Kyle R. Anderson, C. J. Moniz, R. L. Lee, Matthew K. Burgess, M. Cappos, Bruce F. Houghton, W. Tollett, Asta Miklius, Loren Antolik, J. L. Ball, S. Fuke, J. Bard, Carolyn Parcheta, Christina A. Neal, Donald A. Swanson, Matthew R. Patrick, K. Mulliken, Frank A. Trusdell, K. Calles, J. L. Babb, P. Dotray, Patricia A. Nadeau, Jefferson C. Chang, Liliana G. DeSmither, James P. Kauahikaua, Tamar Elias, Laura E. Clor, Paul Lundgren, Michael P. Poland, Hannah R. Dietterich, David E. Damby, A. K. Diefenbach, R. Hazlett, A. H. Lerner, Peter F. Cervelli, P. Fukunaga, C. A. Gansecki, W. Million, Michelle L. Coombs, Ingrid A. Johanson, Cynthia Werner, Christoph Kern, Tim R. Orr, Gregory P. Waite, Michael H. Zoeller, Kevan Kamibayashi, Paul G. Okubo, Peter J. Kelly, B. Shiro, S. Conway, S. R. Brantley, E. K. Montgomery-Brown, Weston A. Thelen, S. Pekalib, and E. F. Younger

Subjects
geography, Multidisciplinary, Summit, geography.geographical_feature_category, Rift, 010504 meteorology & atmospheric sciences, Lava, 010502 geochemistry & geophysics, 01 natural sciences, Volcano, Magma, medicine, Caldera, medicine.symptom, Rift zone, Geology, Seismology, Collapse (medical), 0105 earth and related environmental sciences
Abstract

Connecting caldera collapse The Kīlauea Volcano on the island of Hawai‘i erupted for 3 months in 2018. Neal et al. present a summary of the eruption sequence along with a variety of geophysical observations collected by the Hawaiian Volcano Observatory. The cyclic inflation, deflation, and eventual collapse of the summit was tied to lava eruption from lower East Rift Zone fissures. A total volume of 0.8 cubic kilometers of magma erupted, roughly the equivalent of 320,000 swimming pools, which matched the change in volume at the summit. Science , this issue p. 367

Published
2019

4. Magma reservoir failure and the onset of caldera collapse at Kīlauea Volcano in 2018

Author

Ingrid A. Johanson, Michael P. Poland, Matthew R. Patrick, E. K. Montgomery-Brown, Kyle R. Anderson, Asta Miklius, Paul Segall, and Mengyang Gu

Subjects
Basalt, geography, Multidisciplinary, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Lava, Window (geology), 010502 geochemistry & geophysics, 01 natural sciences, Volcano, Magma, medicine, Pressure decrease, Caldera, medicine.symptom, Petrology, Collapse (medical), Geology, 0105 earth and related environmental sciences
Abstract

Caldera collapse and flank eruption Real-time monitoring of volcanic eruptions involving caldera-forming events are rare (see the Perspective by Sigmundsson). Anderson et al. used several types of geophysical observations to track the caldera-forming collapse at the top of Kīlauea Volcano, Hawai'i, during the 2018 eruption. Gansecki et al. used near–real-time lava composition analysis to determine when magma shifted from highly viscous, slow-moving lava to low-viscosity, fast-moving lava. Patrick et al. used a range of geophysical tools to connect processes at the summit to lava rates coming out of far-away fissures. Together, the three studies improve caldera-collapse models and may help improve real-time hazard responses. Science , this issue p. eaaz0147 , p. eaay9070 ; p. eaaz1822 ; see also p. 1200

Published
2019

5. The 2014–2015 Pāhoa lava flow crisis at Kīlauea Volcano, Hawai’i: Disaster avoided and lessons learned

Author

Willam Tollett, Tamar Elias, Matthew K. Burgess, James P. Kauahikaua, William Million, Cyril J. Moniz, Janet L. Babb, Paul G. Okubo, Matthew R. Patrick, Asta Miklius, Ingrid A. Johanson, Christina A. Neal, A.J. Sutton, Pauline Fukunaga, Michael P. Poland, Frank A. Trusdell, Loren Antolik, Lopaka Lee, Weston A. Thelen, Marian Kagimoto, Steven Fuke, T. Jane Takahashi, Tim R. Orr, Steven R. Brantley, Kevan Kamibayashi, and Kyle R. Anderson

Subjects
geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Volcano, Lava, Earth science, Geology, 010502 geochemistry & geophysics, 01 natural sciences, Seismology, 0105 earth and related environmental sciences
Published
2016

6. Volcanic Unrest at Mauna Loa, Earth’s Largest Active Volcano

Author

Christina A. Neal, Asta Miklius, and Weston A. Thelen

Subjects
010506 paleontology, geography, geography.geographical_feature_category, Volcano, Earth science, General Earth and Planetary Sciences, Earth (chemistry), 010502 geochemistry & geophysics, 01 natural sciences, Volcanic unrest, Geology, 0105 earth and related environmental sciences
Abstract

Mauna Loa is stirring—is a major eruption imminent? Comparisons with previous eruptions paint a complicated picture.

Published
2017

8. Evolution of dike opening during the March 2011 Kamoamoa fissure eruption, Kīlauea Volcano, Hawai'i

Author

Eric J. Fielding, Zhen Liu, Scott Hensley, Susan Owen, Sang-Ho Yun, Asta Miklius, Michael P. Poland, Tim R. Orr, Walter Szeliga, Paul Lundgren, and Akiko Tanaka

Subjects
Décollement, Dike, geography, geography.geographical_feature_category, Hawaiian eruption, Geophysics, Impact crater, Volcano, Space and Planetary Science, Geochemistry and Petrology, Interferometric synthetic aperture radar, Magma, Earth and Planetary Sciences (miscellaneous), Rift zone, Geology, Seismology
Abstract

[1] The 5–9 March 2011 Kamoamoa fissure eruption along the east rift zone of Kīlauea Volcano, Hawai`i, followed months of pronounced inflation at Kīlauea summit. We examine dike opening during and after the eruption using a comprehensive interferometric synthetic aperture radar (InSAR) data set in combination with continuous GPS data. We solve for distributed dike displacements using a whole Kīlauea model with dilating rift zones and possibly a deep decollement. Modeled surface dike opening increased from nearly 1.5 m to over 2.8 m from the first day to the end of the eruption, in agreement with field observations of surface fracturing. Surface dike opening ceased following the eruption, but subsurface opening in the dike continued into May 2011. Dike volumes increased from 15, to 16, to 21 million cubic meters (MCM) after the first day, eruption end, and 2 months following, respectively. Dike shape is distinctive, with a main limb plunging from the surface to 2–3 km depth in the up-rift direction toward Kīlauea's summit, and a lesser projection extending in the down-rift direction toward Pu`u `Ō`ō at 2 km depth. Volume losses beneath Kīlauea summit (1.7 MCM) and Pu`u `Ō`ō (5.6 MCM) crater, relative to dike plus erupted volume (18.3 MCM), yield a dike to source volume ratio of 2.5 that is in the range expected for compressible magma without requiring additional sources. Inflation of Kīlauea's summit in the months before the March 2011 eruption suggests that the Kamoamoa eruption resulted from overpressure of the volcano's magmatic system.

Published
2013

9. The 2014 annual report for the Hawaiian Volcano Observatory

Author

Cynthia Werner, Matthew K. Burgess, Asta Miklius, Tamar Elias, Christoph Kern, James P. Kauahikaua, Loren Antolik, Jeff Sutton, Weston A. Thelen, Kyle R. Anderson, Tim R. Orr, Matthew R. Patrick, and Michael P. Poland

Subjects
geography, geography.geographical_feature_category, Oceanography, 010504 meteorology & atmospheric sciences, Volcano, Observatory, Climatology, Volcano warning schemes of the United States, Annual report, 010502 geochemistry & geophysics, 01 natural sciences, Geology, 0105 earth and related environmental sciences
Published
2016

10. Coupling at Mauna Loa and Kīlauea by stress transfer in an asthenospheric melt layer

Author

Cecily J. Wolfe, Michael P. Poland, Benjamin A. Brooks, Helge M. Gonnermann, Asta Miklius, and James Foster

Subjects
geography, geography.geographical_feature_category, Hawaiian eruption, Geophysics, Volcanology, Stress (mechanics), Pore water pressure, Volcano, General Earth and Planetary Sciences, Coupling (piping), Rift zone, Structural geology, Petrology, Geology
Abstract

Over the past decade, Kīlauea and Mauna Loa—adjacent volcanoes in Hawai‘i—have inflated and deflated in tandem, yet their shallow volcanic plumbing systems are separate. Numerical modelling of the volcanoes shows that dynamic stress transfer by asthenospheric pore pressure is a viable mechanism for volcano coupling in Hawai‘i.

Published
2012

11. A mantle-driven surge in magma supply to Kīlauea Volcano during 2003–2007

Author

A. Jeff Sutton, Michael P. Poland, Asta Miklius, and Carl R. Thornber

Subjects
geography, geography.geographical_feature_category, Volcano, Lava, General Earth and Planetary Sciences, Gas emissions, Volcanology, Surge, Induced seismicity, Petrology, Structural geology, Geology, Mantle (geology)
Abstract

The supply of magma to Kīlauea Volcano, Hawai‘i, was thought to have been steady over the past decades. Measurements of deformation, gas emissions, seismicity and lava composition and temperatures show that instead magma supply from the mantle doubled in 2003–2007, implying that hotspots can provide varying amounts of magma over just a few years.

Published
2012

12. Mapping Three-Dimensional Surface Deformation by Combining Multiple-Aperture Interferometry and Conventional Interferometry: Application to the June 2007 Eruption of Kilauea Volcano, Hawaii

Author

Hyung-Sup Jung, Zhong Lu, Asta Miklius, Michael P. Poland, and Joong-Sun Won

Subjects
Synthetic aperture radar, geography, geography.geographical_feature_category, Aperture, Deformation (meteorology), Geotechnical Engineering and Engineering Geology, Geodesy, law.invention, Interferometry, Volcano, law, Interferometric synthetic aperture radar, Electrical and Electronic Engineering, Radar, Rift zone, Seismology, Geology
Abstract

Surface deformation caused by an intrusion and small eruption during June 17-19, 2007, along the East Rift Zone of Kilauea Volcano, Hawaii, was three-dimensionally reconstructed from radar interferograms acquired by the Advanced Land Observing Satellite (ALOS) phased-array type L-band synthetic aperture radar (SAR) (PALSAR) instrument. To retrieve the 3-D surface deformation, a method that combines multiple-aperture interferometry (MAI) and conventional interferometric SAR (InSAR) techniques was applied to one ascending and one descending ALOS PALSAR interferometric pair. The maximum displacements as a result of the intrusion and eruption are about 0.8, 2, and 0.7 m in the east, north, and up components, respectively. The radar-measured 3-D surface deformation agrees with GPS data from 24 sites on the volcano, and the root-mean-square errors in the east, north, and up components of the displacement are 1.6, 3.6, and 2.1 cm, respectively. Since a horizontal deformation of more than 1 m was dominantly in the north-northwest-south-southeast direction, a significant improvement of the north-south component measurement was achieved by the inclusion of MAI measurements that can reach a standard deviation of 3.6 cm. A 3-D deformation reconstruction through the combination of conventional InSAR and MAI will allow for better modeling, and hence, a more comprehensive understanding, of the source geometry associated with volcanic, seismic, and other processes that are manifested by surface deformation.

Published
2011

15. Earthquakes triggered by silent slip events on Kīlauea volcano, Hawaii

Author

David R. Shelly, Peter F. Cervelli, Paul Segall, Emily K. Desmarais, and Asta Miklius

Subjects
Remotely triggered earthquakes, geography, Multidisciplinary, geography.geographical_feature_category, Subduction, Volcano, Slow earthquake, Slip (materials science), Episodic tremor and slip, Induced seismicity, Earthquake swarm, Geology, Seismology
Abstract

Slow-slip events, or 'silent earthquakes', have recently been discovered in a number of subduction zones including the Nankai trough in Japan, Cascadia, and Guerrero in Mexico, but the depths of these events have been difficult to determine from surface deformation measurements. Although it is assumed that these silent earthquakes are located along the plate megathrust, this has not been proved. Slow slip in some subduction zones is associated with non-volcanic tremor, but tremor is difficult to locate and may be distributed over a broad depth range. Except for some events on the San Andreas fault, slow-slip events have not yet been associated with high-frequency earthquakes, which are easily located. Here we report on swarms of high-frequency earthquakes that accompany otherwise silent slips on Kīlauea volcano, Hawaii. For the most energetic event, in January 2005, the slow slip began before the increase in seismicity. The temporal evolution of earthquakes is well explained by increased stressing caused by slow slip, implying that the earthquakes are triggered. The earthquakes, located at depths of 7-8 km, constrain the slow slip to be at comparable depths, because they must fall in zones of positive Coulomb stress change. Triggered earthquakes accompanying slow-slip events elsewhere might go undetected if background seismicity rates are low. Detection of such events would help constrain the depth of slow slip, and could lead to a method for quantifying the increased hazard during slow-slip events, because triggered events have the potential to grow into destructive earthquakes.

Published
2006

17. Constraints on dike propagation from continuous GPS measurements

Author

Paul Segall, Asta Miklius, Peter F. Cervelli, Susan M. Owen, and M. Lisowski

Subjects
Atmospheric Science, geography, Dike, geography.geographical_feature_category, Ecology, Lava, Paleontology, Soil Science, Forestry, Magma chamber, Volcanism, Aquatic Science, Oceanography, Geophysics, Volcano, Space and Planetary Science, Geochemistry and Petrology, Seismic tomography, Magma, Earth and Planetary Sciences (miscellaneous), Rift zone, Seismology, Geology, Earth-Surface Processes, Water Science and Technology
Abstract

The January 1997 East Rift Zone eruption on Kilauea volcano, Hawaii, occurred within a network of continuous Global Positioning System (GPS) receivers. The GPS measurements reveal the temporal history of deformation during dike intrusion, beginning ∼8 hours prior to the onset of the eruption. The dike volume as a function of time, estimated from the GPS data using elastic Green's functions for a homogeneous half-space, shows that only two thirds of the final dike volume accumulated prior to the eruption and the rate of volume change decreased with time. These observations are inconsistent with simple models of dike propagation, which predict accelerating dike volume up to the time of the eruption and little or no change thereafter. Deflationary tilt changes at Kilauea summit mirror the inferred dike volume history, suggesting that the rate of dike propagation is limited by flow of magma into the dike. A simple, lumped parameter model of a coupled dike magma chamber system shows that the tendency for a dike to end in an eruption (rather than intrusion) is favored by high initial dike pressures, compressional stress states, large, compressible magma reservoirs, and highly conductive conduits linking the dike and source reservoirs. Comparison of model predictions to the observed dike volume history, the ratio of erupted to intruded magma, and the deflationary history of the summit magma chamber suggest that most of the magma supplied to the growing dike came from sources near to the eruption through highly conductive conduits. Interpretation is complicated by the presence of multiple source reservoirs, magma vesiculation and cooling, as well as spatial variations in dike-normal stress. Reinflation of the summit magma chamber following the eruption was measured by GPS and accompanied a rise in the level of the Pu'u O'o lava lake. For a spheroidal chamber these data imply a summit magma chamber volume of ∼20 km3, consistent with recent estimates from seismic tomography. Continuous deformation measurements can be used to image the spatiotemporal evolution of propagating dikes and to reveal quantitative information about the volcanic plumbing systems.

Published
2001

18. January 30, 1997 eruptive event on Kilauea Volcano, Hawaii, as monitored by continuous GPS

Author

Asta Miklius, Paul Segall, James Foster, Susan Owen, M. H. Murray, Michael Bevis, and Michael Lisowski

Subjects
geography, Rift, geography.geographical_feature_category, Lateral eruption, business.industry, Lava, Hawaiian eruption, Geophysics, Effusive eruption, Volcano, Global Positioning System, General Earth and Planetary Sciences, Rift zone, business, Geology, Seismology
Abstract

A continuous Global Positioning System (GPS) network on Kilauea Volcano captured the most recent fissure eruption in Kilauea's East Rift Zone (ERZ) in unprecedented spatial and temporal detail. The short eruption drained the lava pond at Pueu Oeo, leading to a two month long pause in its on-going eruption. Models of the GPS data indicate that the intrusion's bottom edge extended to only 2.4 km. Continuous GPS data reveal rift opening 8 hours prior to the eruption. Absence of precursory summit inflation rules out magma storage overpressurization as the eruption's cause. We infer that stresses in the shallow rift created by the continued deep rift dilation and slip on the south flank decollement caused the rift intrusion.

Published
2000

19. Rapid deformation of Kilauea Volcano: Global Positioning System measurements between 1990 and 1996

Author

Asta Miklius, Susan M. Owen, Michael Lisowski, Maurice K. Sako, Paul Segall, and Roger P. Denlinger

Subjects
Atmospheric Science, geography, Rift, geography.geographical_feature_category, Ecology, Paleontology, Soil Science, Forestry, Slip (materials science), Aquatic Science, Induced seismicity, Oceanography, Geophysics, Volcano, Space and Planetary Science, Geochemistry and Petrology, Epicenter, Earth and Planetary Sciences (miscellaneous), Caldera, Submarine pipeline, Rift zone, Geology, Seismology, Earth-Surface Processes, Water Science and Technology
Abstract

Campaign Global Positioning System (GPS) measurements from 1990 to 1996 are used to calculate surface displacement rates on Kilauea Volcano, Hawaii. The GPS data show that the south flank of the volcano, which has generated several large earthquakes in the past 3 decades, is displacing at up to ;8 cm/yr to the south-southeast. The summit and rift zones are subsiding, with maximum subsidence rates of ;8 cm/yr observed a few kilometers south of the summit caldera. Elastic dislocation modeling of the GPS data suggests that the active sources of deformation include deep rift opening along the upper east and east rift zone, fault slip along a subhorizontal fault near the base of the volcano, and deflation near the summit caldera. A nonlinear optimization algorithm was used to explore the parameter space and to find the best fitting source geometry. There is a broad range of model geometries that fit the data reasonably well. However, certain models can be ruled out, including those that have shallow rift opening or shallow fault slip. Some offshore, aseismic slip on a fault plane that dips between 258 north- northwest and 88 south-southeast is required. Best fitting slip and rift opening rates are 23-28 cm/yr, although rates as low as 10 cm/yr are permitted by the data.

Published
2000

20. High Magma Storage Rates Before the 1983 Eruption of Kilauea, Hawaii

Author

James H. Dieterich, Valérie Cayol, Asta Miklius, and Arnold T. Okamura

Subjects
geography, Dike, Multidisciplinary, Lateral eruption, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Magma chamber, Fault (geology), 010502 geochemistry & geophysics, 01 natural sciences, Phreatic eruption, Volcano, Magma, Rift zone, Seismology, Geology, 0105 earth and related environmental sciences
Abstract

After a magnitude 7.2 earthquake in 1975 and before the start of the ongoing eruption in 1983, deformation of Kilauea volcano was the most rapid ever recorded. Three-dimensional numerical modeling shows that this deformation is consistent with the dilation of a dike within Kilauea's rift zones coupled with creep over a narrow area of a low-angle fault beneath the south flank. Magma supply is estimated to be 0.18 cubic kilometers per year, twice that of previous estimates. The 1983 eruption may be a direct consequence of the high rates of magma storage within the rift zone that followed the 1975 earthquake.

Published
2000

21. Volcanic spreading at Kilauea, 1976-1996

Author

Asta Miklius, Paul T. Delaney, Michael Lisowski, Arnold T. Okamura, Maurice K. Sako, Roger P. Denlinger, and Paul G. Okubo

Subjects
Atmospheric Science, Dike, Flank, Soil Science, Aquatic Science, Oceanography, Paleontology, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Earth-Surface Processes, Water Science and Technology, geography, Rift, geography.geographical_feature_category, Ecology, Forestry, Geophysics, Volcano, Space and Planetary Science, Magma, Subaerial, Rift zone, Accretion (geology), Seismology, Geology
Abstract

The rift system traversing about 80 km of the subaerial surface of Kilauea volcano has extended continuously since the M 7.2 flank earthquake of November 1975. Widening across the summit has amounted to more than 250 cm, decelerating after 1975 from about 25 to 4 cm yr−1 since 1983. Concurrently, the summit has subsided more than 200 cm, even as the adjacent south flank has risen more than 50 cm. The axes of the upper zones, about 10 km from the summit, subsided before 1983 at average rates of 9 and 4 cm yr−1, respectively, and at rates of 4 and 3 cm yr−1 since. The middle southwest rift zone is also subsiding and, at the other end of Kilauea's subaerial rift system, subsidence along the lower east rift zone has averaged 1–2 cm yr−1. Deformation of Kilauea's south flank has been continuous, although subject as well to displacements caused by major rift zone seismic swarms. Whereas horizontal strains across the subaerial south flank seem to have been generally compressive after 1975, they have been extensional since about 1980 or 1981, interrupted only by the east rift zone dike intrusion of 1983. Because the magnitudes of these contractions and extensions are much less than the extension across the rift system, the subaerial south flank is apparently sliding seaward on its basal decollement more than it is accumulating horizontal strains within the overlying volcanic pile. Kilauea suffers from gravitational spreading made even more unstable by accumulation of magma along the rift system at depths in excess of about 4–5 km in the presence hot rock incapable of withstanding deviatoric stresses. This seismicly quiescent zone decouples the south flank from the rest of Hawaii's volcanic edifice; the rift zones at lesser depths exhibit a more brittle and, therefore, sporadic extensional behavior. Judging from the modern extension record of the summit, which both predates the M 7.2 earthquake of 1975 and has outlived its 10-year period of aftershocks, Kilauea will continue to spread along its rift system as its south flank slips seaward to accommodate the accretion of magma and its relatively dense olivine-rich differentiate.

Published
1998

22. Spatiotemporal evolution of dike opening and décollement slip at Kīlauea Volcano, Hawai'i

Author

Asta Miklius, E. K. Montgomery-Brown, Kristine M. Larson, Michael P. Poland, Paul Segall, and D. K. Sinnett

Subjects
Atmospheric Science, geography, Dike, Flank, geography.geographical_feature_category, Rift, Ecology, Paleontology, Soil Science, Tiltmeter, Forestry, Slip (materials science), Aquatic Science, Induced seismicity, Oceanography, Geophysics, Volcano, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Rift zone, Geology, Seismology, Earth-Surface Processes, Water Science and Technology
Abstract

[1] Rapid changes in ground tilt and GPS positions on Kīlauea Volcano, Hawai'i, are interpreted as resulting from a shallow, two-segment dike intrusion into the east rift zone that began at 1217 UTC (0217 HST) on 17 June 2007 and lasted almost 3 days. As a result of the intrusion, a very small volume of basalt (about 1500 m3) erupted on 19 June. Northward tilt at a coastal tiltmeter, subsidence of south flank GPS sites, southeastward displacements at southwestern flank GPS sites, and a swarm of flank earthquakes suggest that a slow slip event occurred on the decollement beneath Kīlauea's south flank concurrent with the rift intrusion. We use 4 min GPS positions that include estimates of time-dependent tropospheric gradients and ground tilt data to study the spatial and temporal relationships between the two inferred shallow, steeply dipping dike segments extending from the surface to about 2 km depth and decollement slip at 8 km depth. We invert for the temporal evolution of distributed dike opening and decollement slip in independent inversions at each time step using a nonnegative least squares algorithm. On the basis of these inversions, the intrusion occurred in two stages that correspond spatially and temporally with concentrated rift zone seismicity. The dike opening began on the western of the two segments before jumping to the eastern segment, where the majority of opening accumulated. Dike opening preceded the start of decollement slip at an 84% confidence level; the latter is indicated by the onset of northward tilt of a coastal tiltmeter. Displacements at southwest flank GPS sites began about 18 h later and are interpreted as resulting from slow slip on the southwestern flank. Additional constraints on the evolution of the intrusion and decollement slip come from inversion of an Envisat interferogram that spans the intrusion until 0822 UTC on 18 June 2007, combined with GPS and tilt data. This inversion shows that up to 0822 UTC on 18 June, decollement slip is only required in a limited region offshore of Ka'ena Point. A similar inversion of the complete event, which includes GPS and tilt data up to 21 June and a second Envisat interferogram spanning the complete intrusion until 21 June, shows decollement slip spread westward across the south flank. This may suggest westward migration of the decollement slip as the event progressed.

Published
2011

23. Motion of Kilauea Volcano during sustained eruption from the Puu Oo and Kupaianaha Vents, 1983-1991

Author

Paul T. Delaney, Asta Miklius, Thóra Árnadóttir, Arnold T. Okamura, and Maurice K. Sako

Subjects
Atmospheric Science, geography, Dike, Flank, geography.geographical_feature_category, Summit, Rift, Ecology, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Earthquake swarm, Geophysics, Volcano, Space and Planetary Science, Geochemistry and Petrology, Epicenter, Earth and Planetary Sciences (miscellaneous), Rift zone, Seismology, Geology, Earth-Surface Processes, Water Science and Technology
Abstract

Kilauea erupted almost continuously from January 1983 through 1991. Although the summit began subsiding during the rift zone dike intrusion that initiated this eruption, remarkably steady ground surface motions began in late 1983 after a magnitude 6.6 earthquake beneath the slopes of nearby Mauna Loa volcano and continued until the onset of brief upper east rift zone earthquake swarms in late 1990. During these 7 years the summit and upper rift zones subsided up to 10–11 and 4–8 cm yr−1, respectively, and summit baselines contracted up to 6 cm yr−1. Baselines directed northward from the summit to stations on Mauna Loa extended at rates up to 7 cm yr−1, and a baseline from south of the summit to Mauna Loa extended 4 cm yr−1. Much of this extension is inconsistent with deformation caused solely by summit magma reservoir collapse and more likely reflects rifting as the south flank of the volcano moved seaward from the summit and rift zones. Farther from the summit, baselines crossing the south flank extended up to 2 cm yr−1, and a south flank tide gauge rose 2 cm yr−1; the lower east rift zone, 40–50 km from the summit, subsided about 2 cm yr−1. Motion on Kilauea, then, is broadly consistent with slip along low-angle south flank faults, generating subsidence that is focused at the summit and along the rift system behind the faulting and uplift along the coastal south flank ahead of it. Dislocation models that combine these elements show that much of Kilauea's edifice migrated seaward, producing ground surface motions along the south flank of up to about 6 cm yr−1. The magnitude 6.1 earthquake of 1989 punctuated these motions along the eastern south flank, producing more than 25 cm of seaward displacement and, 15 km east of the epicenter, up to 24 cm of subsidence south of the lower east rift zone. Unlike the magnitude 7.2 south flank earthquake of 1975, the 1989 event was preceded neither by summit magma reservoir inflation nor by rift zone dike intrusions and accompanying compression of the south flank. Deformation was probably caused by the weight of the volcanic overburden and by ongoing dilation and slip within the rift system.

Published
1993

24. Geodetic evidence for en echelon dike emplacement and concurrent slow slip during the June 2007 intrusion and eruption at Kīlauea volcano, Hawaii

Author

Michael P. Poland, Asta Miklius, Howard A. Zebker, E. K. Montgomery-Brown, D. K. Sinnett, Paul Segall, and Tim R. Orr

Subjects
Atmospheric Science, geography, Dike, geography.geographical_feature_category, Rift, Ecology, Paleontology, Soil Science, Tiltmeter, Forestry, Slip (materials science), Aquatic Science, Oceanography, Geophysics, Volcano, Space and Planetary Science, Geochemistry and Petrology, Interferometric synthetic aperture radar, Earth and Planetary Sciences (miscellaneous), Echelon formation, Rift zone, Geology, Seismology, Earth-Surface Processes, Water Science and Technology
Abstract

[1] A series of complex events at Kīlauea Volcano, Hawaii, 17 June to 19 June 2007, began with an intrusion in the upper east rift zone (ERZ) and culminated with a small eruption (1500 m3). Surface deformation due to the intrusion was recorded in unprecedented detail by Global Positioning System (GPS) and tilt networks as well as interferometric synthetic aperture radar (InSAR) data acquired by the ENVISAT and ALOS satellites. A joint nonlinear inversion of GPS, tilt, and InSAR data yields a deflationary source beneath the summit caldera and an ENE-striking uniform-opening dislocation with ∼2 m opening, a dip of ∼80° to the south, and extending from the surface to ∼2 km depth. This simple model reasonably fits the overall pattern of deformation but significantly misfits data near the western end of an inferred dike-like source. Three more complex dike models are tested that allow for distributed opening including (1) a dike that follows the surface trace of the active rift zone, (2) a dike that follows the symmetry axis of InSAR deformation, and (3) two en echelon dike segments beneath mapped surface cracks and newly formed steaming areas. The en echelon dike model best fits near-field GPS and tilt data. Maximum opening of 2.4 m occurred on the eastern segment beneath the eruptive vent. Although this model represents the best fit to the ERZ data, it still fails to explain data from a coastal tiltmeter and GPS sites on Kīlauea's southwestern flank. The southwest flank GPS sites and the coastal tiltmeter exhibit deformation consistent with observations of previous slow slip events beneath Kīlauea's south flank, but inconsistent with observations of previous intrusions. Slow slip events at Kīlauea and elsewhere are thought to occur in a transition zone between locked and stably sliding zones of a fault. An inversion including slip on a basal decollement improves fit to these data and suggests a maximum of ∼15 cm of seaward fault motion, comparable to previous slow-slip events.

Published
2010

25. Volcano monitoring using GPS: Developing data analysis strategies based on the June 2007 Kīlauea Volcano intrusion and eruption

Author

Michael P. Poland, Kristine M. Larson, and Asta Miklius

Subjects
Atmospheric Science, Instrumentation, Soil Science, Tiltmeter, Aquatic Science, Oceanography, Displacement (vector), Intrusion, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Atmospheric refraction, Earth-Surface Processes, Water Science and Technology, geography, geography.geographical_feature_category, Ecology, business.industry, Paleontology, Forestry, Geophysics, Volcano, Space and Planetary Science, Global Positioning System, business, Multipath propagation, Geology, Seismology
Abstract

[1] The global positioning system (GPS) is one of the most common techniques, and the current state of the art, used to monitor volcano deformation. In addition to slow (several centimeters per year) displacement rates, GPS can be used to study eruptions and intrusions that result in much larger (tens of centimeters over hours-days) displacements. It is challenging to resolve precise positions using GPS at subdaily time intervals because of error sources such as multipath and atmospheric refraction. In this paper, the impact of errors due to multipath and atmospheric refraction at subdaily periods is examined using data from the GPS network on Kīlauea Volcano, Hawai'i. Methods for filtering position estimates to enhance precision are both simulated and tested on data collected during the June 2007 intrusion and eruption. Comparisons with tiltmeter records show that GPS instruments can precisely recover the timing of the activity.

Published
2010

26. Kilauea slow slip events: Identification, source inversions, and relation to seismicity

Author

Asta Miklius, E. K. Montgomery-Brown, and Paul Segall

Subjects
Atmospheric Science, geography, geography.geographical_feature_category, Ecology, Paleontology, Soil Science, Forestry, Slip (materials science), Aquatic Science, Induced seismicity, Fault (geology), Oceanography, Displacement (vector), Geophysics, Volcano, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Episodic tremor and slip, Microearthquake, Geology, Aftershock, Seismology, Earth-Surface Processes, Water Science and Technology
Abstract

[1] Several slow slip events beneath the south flank ofKilauea Volcano, Hawaii, have been inferred from transient displacements in daily GPS positions. To search for smaller events that may be close to the noise level in the GPS time series, we compare displacement fields on Kilauea's south flank with displacement patterns in previously identified slow slip events. Matching displacement patterns are found for several new candidate events, although displacements are much smaller than previously identified events. One of the candidates, 29 May 2000, is coincident with a microearthquake swarm, as are all of the previously identified slow slip events. The microearthquakes follow the onset of slow slip, implying that they are triggered by stress changes during slip. The new slow slip event brings the total number of events on Kilauea, between 1997 and 2007, to eight, the smallest having M w = 5.3, and the largest having M w = 6.0. While the recurrence time between the four largest events is 2.11 ± 0.01 years, the repeat time for all eight events is 0.9 ± 0.6 years. We invert for the fault geometry and distribution of slip during the slow slip events. The optimal source depths of 5 km, assuming uniform slip dislocations in an elastic half-space, are considerably shallower than the accompanying swarm earthquakes (6.5-8.5 km), which would place the earthquakes in a zone of decreased Coulomb stress. Inversions including the effects of topography and layered elastic structure in the forward models favor depths comparable to microearthquake depths, such that the earthquakes are located in a region of increased Coulomb stress. We also invert for time-dependent fault slip directly from the 30 s GPS phase observations, constraining the source to the optimal uniform slip geometry. On the basis of these inversions, the larger events last between 1.5-2.2 days. The data are unable to resolve migration of slip along the fault. The temporal pattern of accompanying microearthquakes is consistent with the fault slip history assuming a seismicity rate theory based on rate and state-friction, making the swarm earthquakes coshocks and aftershocks of the slow slip events.

Published
2009

28. Deep Magma Body Beneath the Summit and Rift Zones of Kilauea Volcano, Hawaii

Author

Arnold T. Okamura, Maurice K. Sako, Richard S. Fiske, Paul T. Delaney, and Asta Miklius

Subjects
geography, Dike, Multidisciplinary, geography.geographical_feature_category, Lateral eruption, Summit, Volcano, Magma, Magma chamber, Fault (geology), Rift zone, Seismology, Geology
Abstract

A magnitude 7.2 earthquake in 1975 caused the south flank of Kilauea Volcano, Hawaii, to move seaward in response to slippage along a deep fault. Since then, a large part of the volcano's edifice has been adjusting to this perturbation. The summit of Kilauea extended at a rate of 0.26 meter per year until 1983, the south flank uplifted more than 0.5 meter, and the axes of both the volcano's rift zones extended and subsided; the summit continues to subside. These ground-surface motions have been remarkably steady and much more widespread than those caused by either recurrent inflation and deflation of the summit magma chamber or the episodic propagation of dikes into the rift zones. Kilauea's magmatic system is, therefore, probably deeper and more extensive than previously thought; the summit and both rift zones may be underlain by a thick, near vertical dike-like magma system at a depth of 3 to 9 kilometers.

Published
1990

29. Sudden aseismic fault slip on the south flank of Kilauea volcano

Author

Michael Lisowski, Asta Miklius, Peter F. Cervelli, Kaj M. Johnson, and Paul Segall

Subjects
Flank, geography, Multidisciplinary, geography.geographical_feature_category, Volcano, Natural hazard, Geodetic datum, Thrust fault, Moment magnitude scale, Slip (materials science), Oceanic basin, Seismology, Geology
Abstract

One of the greatest hazards associated with oceanic volcanoes is not volcanic in nature, but lies with the potential for catastrophic flank failure. Such flank failure can result in devastating tsunamis and threaten not only the immediate vicinity, but coastal cities along the entire rim of an ocean basin. Kilauea volcano on the island of Hawaii, USA, is a potential source of such flank failures and has therefore been monitored by a network of continuously recording geodetic instruments, including global positioning system (GPS) receivers, tilt meters and strain meters. Here we report that, in early November 2000, this network recorded transient southeastward displacements, which we interpret as an episode of aseismic fault slip. The duration of the event was about 36 hours, it had an equivalent moment magnitude of 5.7 and a maximum slip velocity of about 6[?]cm per day. Inversion of the GPS data reveals a shallow-dipping thrust fault at a depth of 4.5[?]km that we interpret as the down-dip extension of the Hilina Pali--Holei Pali normal fault system. This demonstrates that continuously recording geodetic networks can detect accelerating slip, potentially leading to warnings of volcanic flank collapse.

Published
2002

30. New Episodes of Volcanism at Kilauea Volcano, Hawaii

Author

Carl R. Thornber, Asta Miklius, Michael P. Poland, David C. Wilson, Tim R. Orr, and Jeff Sutton

Subjects
geography, Rift, geography.geographical_feature_category, Volcano, Magma, Geochemistry, General Earth and Planetary Sciences, Volcanism, Rift zone, Seismology, Geology
Abstract

Mid-2007 was a time of intense activity at Kilauea Volcano, Hawaii (see Figure 1). In June, the long-lived Pu'u 'Ō'ō—Kupaianaha eruption, a dual-vent system along the east rift zone (ERZ) that has been erupting since 1983 [Heliker et al., 2003], paused due to the outbreak of a new vent farther up the rift (see Figure 2). The Pu'u 'Ō'ō vent collapsed following that activity, and the resulting reorganization of the magma plumbing system led to the formation of a second new eruptive vent 2 kilometers downrift of Pu'u 'Ō'ō. These events were well documented by geological, geophysical, and geochemical monitoring. This article summarizes results from these monitoring efforts and interprets the changes that have occurred at Kilauea since June 2007.

Published
2008

31. Recent inflation and flank movement of Mauna Loa Volcano

Author

Roger P. Denlinger, Asta Miklius, John J. Dvorak, Arnold T. Okamura, Maurice K. Sakol, Paul T. Delaney, and Michael Lisowski

Subjects
Inflation, geography, Flank, geography.geographical_feature_category, Volcano, Movement (music), media_common.quotation_subject, Geology, Seismology, media_common
Published
1995

33. Slow Slip Event at Kilauea Volcano

Author

Clifford Thurbe, Michael P. Poland, James Foster, Ellen M. Syracuse, Benjamin A. Brooks, Cecily J. Wolfe, Asta Miklius, Paul Segall, Paul G. Okubo, E. K. Montgomery-Brown, and J. David Wilson

Subjects
geography, Flank, geography.geographical_feature_category, Volcano, Slow earthquake, General Earth and Planetary Sciences, Slip (materials science), Geology, Seismology
Abstract

Early in the morning of 1 February 2010 (UTC; early afternoon 31 January 2010 local time), continuous Global Positioning System (GPS) and tilt instruments detected a slow slip event (SSE) on the south flank of Kilauea volcano, Hawaii. The SSE lasted at least 36 hours and resulted in a maximum of about 3 centimeters of seaward displacement. About 10 hours after the start of the slip, a flurry of small earthquakes began (Figure 1) in an area of the south flank recognized as having been seismically active during past SSEs [Wolfe et al., 2007], suggesting that the February earthquakes were triggered by stress associated with slip [Segall et al., 2006].

Published
2010

35. Erratum: Earthquakes triggered by silent slip events on Kīlauea volcano, Hawaii

Author

Asta Miklius, Emily K. Desmarais, David R. Shelly, Paul Segall, and Peter F. Cervelli

Subjects
geography, Multidisciplinary, geography.geographical_feature_category, Volcano, Slip (materials science), Seismology, Geology
Abstract

Nature 442, 71–74 (2006) There was a plotting error in Fig. 1 that inadvertently displays earthquakes for the incorrect time interval. The location of earthquakes during the two-day-long slow-slip event of January 2005 are shown here in the corrected Fig. 1. Because the incorrect locations were alsoused in the Coulomb stress-change (CSC) calculation, the error could potentially have biased our interpretation of the depth of the slow-slip event, although in fact it did not.

Published
2006

36. Sensor web enables rapid response to volcanic activity

Author

Daniel Tran, Jeffrey B. Johnson, Steven R. Schaffer, Matt Welsh, Ashley Davies, Philip R. Kyle, Rob Sherwood, Asta Miklius, Steve Chien, and Robert Wright

Subjects
geography, geography.geographical_feature_category, Spacecraft, Volcano, business.industry, Remote sensing (archaeology), General Earth and Planetary Sciences, Environmental science, business, Jet propulsion, Rapid response, Sensor web, Remote sensing
Abstract

Rapid response to the onset of volcanic activity allows for the early assessment of hazard and risk [Tilling, 1989]. Data from remote volcanoes and volcanoes in countries with poor communication infrastructure can only be obtained via remote sensing [Harris et al., 2000]. By linking notifications of activity from ground-based and spacebased systems, these volcanoes can be monitored when they erupt. Over the last 18 months, NASA's Jet Propulsion Laboratory (JPL) has implemented a Volcano Sensor Web (VSW) in which data from ground-based and space-based sensors that detect current volcanic activity are used to automatically trigger the NASA Earth Observing 1 (EO-1) spacecraft to make highspatial-resolution observations of these volcanoes.

Published
2006

37. Interaction between Kilauea and Mauna Loa

Author

Peter F. Cervelli and Asta Miklius

Subjects
geography, Multidisciplinary, geography.geographical_feature_category, Impact crater, Volcano, Lava, Magma, Inflation deflation, Volcanology, Seismology
Abstract

Last year witnessed an unexpected communication between this pair of volcanoes. After almost a decade of very slow rates of deformation, Mauna Loa in Hawaii, the largest volcano on Earth, began inflating in May 2002; at the same time, a high-volume effusive episode began at its neighbour Kilauea. We have found a correlation between these events at a very short timescale, detected by continuous deformation monitoring. This remarkable observation suggests that there is a crustal-level interaction between the magma systems of Mauna Loa and Kilauea, reviving a century-old controversy over the relationship between these two volcanoes on the basis of differences in their lava chemistry and in their patterns of eruptive behaviour1,2,3,4,5.

Published
2003

38. The 12 September 1999 Upper East Rift Zone dike intrusion at Kilauea Volcano, Hawaii

Author

Charles Meertens, Paul Segall, Peter F. Cervelli, Susan Owen, Harold Garbeil, Asta Miklius, Falk Amelung, and M. Lisowski

Subjects
Atmospheric Science, Dike, geography, Rift, geography.geographical_feature_category, Ecology, Paleontology, Soil Science, Tiltmeter, Forestry, Magma chamber, Aquatic Science, Oceanography, Earthquake swarm, Geophysics, Volcano, Space and Planetary Science, Geochemistry and Petrology, Interferometric synthetic aperture radar, Earth and Planetary Sciences (miscellaneous), Rift zone, Geology, Seismology, Earth-Surface Processes, Water Science and Technology
Abstract

[1] Deformation associated with an earthquake swarm on 12 September 1999 in the Upper East Rift Zone of Kilauea Volcano was recorded by continuous GPS receivers and by borehole tiltmeters. Analyses of campaign GPS, leveling data, and interferometric synthetic aperture radar (InSAR) data from the ERS-2 satellite also reveal significant deformation from the swarm. We interpret the swarm as resulting from a dike intrusion and model the deformation field using a constant pressure dike source. Nonlinear inversion was used to find the model that best fits the data. The optimal dike is located beneath and slightly to the west of Mauna Ulu, dips steeply toward the south, and strikes nearly east-west. It is approximately 3 by 2 km across and was driven by a pressure of ∼15 MPa. The total volume of the dike was 3.3 × 106 m3. Tilt data indicate a west to east propagation direction. Lack of premonitory inflation of Kilauea's summit suggests a passive intrusion; that is, the immediate cause of the intrusion was probably tensile failure in the shallow crust of the Upper East Rift Zone brought about by persistent deep rifting and by continued seaward sliding of Kilauea's south flank.

Published
2002

39. Erratum: corrigenda: Sudden aseismic fault slip on the south flank of Kilauea volcano

Author

Paul Segall, Michael Lisowski, Kaj M. Johnson, Peter F. Cervelli, and Asta Miklius

Subjects
geography, Flank, Multidisciplinary, geography.geographical_feature_category, Volcano, Rain gauge, Water table, Aseismic creep, Fault slip, Seismology, Geology
Abstract

Nature 415, 1014–1018 (2002). This Letter contains two errors. First, the units of pressure for the total surface load are incorrectly given as MPa instead of bars (1 bar = 0.1 MPa). Second, in the second paragraph on page 1016, ΔH was incorrectly defined as “the change in water table height” instead of “the amount of rainfall as measured by a rain gauge”.

Published
2002

Catalog

Books, media, physical & digital resources
See catalog results