6 research outputs found
Integration of micro-gravity and geodetic data to constrain shallow system mass changes at Krafla Volcano, N Iceland
New and previously published micro-gravity data are combined with InSAR data, precise levelling and GPS measurements to produce a model for the processes operating at Krafla volcano, 20 years after its most recent eruption. The data have been divided into two periods: from 1990 to 1995 and from 1996 to 2003 and show that the rate of deflation at Krafla is decaying exponentially. The net micro-gravity change at the centre of the caldera is shown, using the measured Free Air Gradient, to be -85 μGal for the first and -100 μGal for the second period. After consideration of the effects of water extraction by the geothermal power station within the caldera, the net gravity decreases are -73 ± 17 μGal for the first and -65 ± 17 μGal for the second period. These decreases are interpreted in terms of magma drainage. Following a Mogi point source model we calculate the mass decrease to be ~2 x 1010 kg/yr reflecting a drainage rate of ~0.23 m3/s, similar to the ~0.13 m3/s drainage rate previously found at Askja volcano, N-Iceland. Based on the evidence for deeper magma reservoirs and the similarity between the two volcanic systems, we suggest a pressure-link between Askja and Krafla at deeper levels (at the lower crust or the crust-mantle boundary). After the Krafla fires, co-rifting pressure decrease of a deep source at Krafla stimulated the subsequent inflow of magma, eventually affecting conditions along the plate boundary in N-Iceland, as far away as Askja. We anticipate that the pressure of the deeper reservoir at Krafla will reach a critical value and eventually magma will rise from there to the shallow magma chamber, possibly initiating a new rifting episode. We have demonstrated that by examining micro-gravity and geodetic data, our knowledge of active volcanic systems can be significantly improved
Review of works combining GNSS and insar in Europe
The Global Navigation Satellite System (GNSS) and Synthetic Aperture Radar Interferometry (InSAR) can be combined to achieve different goals, owing to their main principles. Both enable the collection of information about ground deformation due to the differences of two consequent acquisitions. Their variable applications, even if strictly related to ground deformation and water vapor determination, have encouraged the scientific community to combine GNSS and InSAR data and their derivable products. In this work, more than 190 scientific contributions were collected spanning the whole European continent. The spatial and temporal distribution of such studies, as well as the distinction in different fields of application, were analyzed. Research in Italy, as the most represented nation, with 47 scientific contributions, has been dedicated to the spatial and temporal distribution of its studied phenomena. The state-of-the-art of the various applications of these two combined techniques can improve the knowledge of the scientific community and help in the further development of new approaches or additional applications in different fields. The demonstrated usefulness and versability of the combination of GNSS and InSAR remote sensing techniques for different purposes, as well as the availability of free data, EUREF and GMS (Ground Motion Service), and the possibility of overcoming some limitations of these techniques through their combination suggest an increasingly widespread approach
Temporal fluctuations in the motion of Arctic ice masses from satellite radar interferometry
This thesis considers the use of Interferometric Synthetic Aperture Radar (InSAR) for
surveying temporal fluctuations in the velocity of glaciers in the Arctic region. The aim
of this thesis is to gain a broader understanding of the manner in which the flow of both
land- and marine-terminating glaciers varies over time, and to asses the ability of
InSAR to resolve flow changes over timescales which provide useful information about
the physical processes that control them. InSAR makes use of the electromagnetic phase
difference between successive SAR images to produce interference patterns
(interferograms) which contain information on the topography and motion of the Earth's
surface in the direction of the radar line-of-sight. We apply established InSAR
techniques (Goldstein et al., 1993) to (i) the 925 km2 LangjÖkull Ice Cap (LIC) in
Iceland, which terminates on land (ii) the 8 500 km2 Flade Isblink Icecap (FIIC) in
Northeast Greenland which has both land- and marine-terminating glaciers and (iii) to a
7 000 km2 land-terminating sector of the Western Greenland Ice Sheet (GrIS). It is
found that these three regions exhibit velocity variations over contrasting timescales. At
the LIC, we use an existing ice surface elevation model and dual-look SAR data
acquired by the European Remote Sensing (ERS) satellite to estimate ice velocity
(Joughin et al., 1998) during late-February in 1994. A comparison with direct velocity
measurements determined by global positioning system (GPS) sensors during the
summer of 2001 shows agreement (r2 = 0.86), suggesting that the LIC exhibits moderate
seasonal and inter-annual variations in ice flow. At the FIIC, we difference pairs of
interferograms (Kwok and Fahnestock, 1996) formed using ERS SAR data acquired
between 15th August 1995 and 3rd February 1996 to estimate ice velocity on four
separate days. We observe that the flow of 5 of the 8 outlet glaciers varies in latesummer
compared with winter, although flow speeds vary by up to 20 % over a 10 day
period in August 1995. At the GrIS, we use InSAR (Joughin et al., 1996) and ERS SAR
data to reveal a detailed pattern of seasonal velocity variations, with ice speeds in latesummer
up to three times greater than wintertime rates. We show that the degree of
seasonal speedup is spatially variable and correlated with modeled runoff, suggesting
that seasonal velocity changes are controlled by the routing of water melted at the ice
sheet surface.
The overall conclusion of this work is that the technique of InSAR can provide useful information on fluctuations in ice speed across a range of timescales. Although some ice
masses exhibit little or no temporal flow variability, others show marked inter-annual,
seasonal and even daily variations in speed. We observe variations in seasonality in ice
flow over distances of ~ 10 km and over time periods of ~10 days during late-summer.
With the aid of ancillary meteorological data, we are able to establish that rates of flow
in western Greenland are strongly moderated by the degree of surface melting, which
varies seasonally and secularly. Although the sampling of our data is insufficiently
frequent and spans too brief a period for us to derive a general relationship between
climate and seasonality of flow, we show that production of meltwater at the ice surface
and its delivery to the ice bed play an important role in the modulation of horizontal
flow speeds. We suggest that a similarly detailed investigation of other ice masses is
required to reduce the uncertainty in predictions of the future Arctic land-ice
contribution to sea level in a warming world