37 research outputs found
Detection of the 2010 Chilean Tsunami Using Satellite Altimetry
Tsunamis are difficult to detect and measure in the open ocean because the wave amplitude is much smaller than it is closer to shore. An effective early warning system, however, must be able to observe an impending tsunami threat far away from the shore in order to provide the necessary lead-time for coastal inhabitants to find safety. Given the expansiveness of the ocean, sensors capable of detecting the tsunami must also have very broad areal coverage. The 2004 Sumatra-Andaman tsunami was definitively detected in the open ocean from both sea surface height and sea surface roughness measurements provided by satellite altimeters. This tsunami, however, was exceptionally strong and questions remain about the ability to use such measurements for the detection of weaker tsunamis. Here we study the 2010 Chilean tsunami and demonstrate the ability to detect the tsunami in the open ocean. Specifically, we analyze the utility of filtering in extracting the tsunami signal from sea surface height measurements, and, through the use of statistical analyses of satellite altimeter observations, we demonstrate that the 2010 Chilean tsunami induced distinct and detectable changes in sea surface roughness. While satellite altimeters do not provide the temporal and spatial coverage necessary to form the basis of an effective early warning system, tsunami-induced changes in sea surface roughness can be detected using orbiting microwave radars and radiometers, which have a broad surface coverage across the satellite ground track
A new phase in the production of quality-controlled sea level data
Sea level is an essential climate variable (ECV) that has a direct effect on many people through inundations of coastal areas, and it is also a clear indicator of climate changes due to external forcing factors and internal climate variability. Regional patterns of sea level change inform us on ocean circulation variations in response to natural climate modes such as El Niño and the Pacific Decadal Oscillation, and anthropogenic forcing. Comparing numerical climate models to a consistent set of observations enables us to assess the performance of these models and help us to understand and predict these phenomena, and thereby alleviate some of the environmental conditions associated with them. All such studies rely on the existence of long-term consistent high-accuracy datasets of sea level. The Climate Change Initiative (CCI) of the European Space Agency was established in 2010 to provide improved time series of some ECVs, including sea level, with the purpose of providing such data openly to all to enable the widest possible utilisation of such data. Now in its second phase, the Sea Level CCI project (SL_cci) merges data from nine different altimeter missions in a clear, consistent and well-documented manner, selecting the most appropriate satellite orbits and geophysical corrections in order to further reduce the error budget. This paper summarises the corrections required, the provenance of corrections and the evaluation of options that have been adopted for the recently released v2.0 dataset (https://doi.org/10.5270/esa-sea_level_cci-1993_2015-v_2.0-201612). This information enables scientists and other users to clearly understand which corrections have been applied and their effects on the sea level dataset. The overall result of these changes is that the rate of rise of global mean sea level (GMSL) still equates to âŒâ3.2âŻmmâŻyrâ1 during 1992â2015, but there is now greater confidence in this result as the errors associated with several of the corrections have been reduced. Compared with v1.1 of the SL_cci dataset, the new rate of change is 0.2âŻmmâŻyrâ1 less during 1993 to 2001 and 0.2âŻmmâŻyrâ1 higher during 2002 to 2014. Application of new correction models brought a reduction of altimeter crossover variances for most corrections
Observational Requirements for Long-Term Monitoring of the Global Mean Sea Level and Its Components Over the Altimetry Era
Present-day global mean sea level rise is caused by ocean thermal expansion, ice mass loss from glaciers and ice sheets, as well as changes in terrestrial water storage. For that reason, sea level is one of the best indicators of climate change as it integrates the response of several components of the climate system to internal and external forcing factors. Monitoring the global mean sea level allows detecting changes (e.g., in trend or acceleration) in one or more components. Besides, assessing closure of the sea level budget allows us to check whether observed sea level change is indeed explained by the sum of changes affecting each component. If not, this would reflect errors in some of the components or missing contributions not accounted for in the budget. Since the launch of TOPEX/Poseidon in 1992, a precise 27-year continuous record of sea level change is available. It has allowed major advances in our understanding of how the Earth is responding to climate change. The last two decades are also marked by the launch of the GRACE satellite gravity mission and the development of the Argo network of profiling floats. GRACE space gravimetry allows the monitoring of mass redistributions inside the Earth system, in particular land ice mass variations as well as changes in terrestrial water storage and in ocean mass, while Argo floats allow monitoring sea water thermal expansion due to the warming of the oceans. Together, satellite altimetry, space gravity, and Argo measurements provide unprecedented insight into the magnitude, spatial variability, and causes of present-day sea level change. With this observational network, we are now in a position to address many outstanding questions that are important to planning for future sea level rise. Here, we detail the network for observing sea level and its components, underscore the importance of these observations, and emphasize the need to maintain current systems, improve their sensors, and supplement the observational network where gaps in our knowledge remain
Copernicus Marine Service Ocean State Report
This is the final version. Available from Taylor & Francis via the DOI in this record
Copernicus Marine Service ocean state report, issue 4
This is the final version. Available from Taylor & Francis via the DOI in this record.âŻFCT/MCTE
Analyses of altimetry errors using Argo and GRACE data
This study presents the evaluation of the
performances of satellite altimeter missions by comparing the altimeter sea
surface heights with in situ dynamic heights derived from vertical
temperature and salinity profiles measured by Argo floats. The two objectives
of this approach are the detection of altimeter drift and the estimation of
the impact of new altimeter standards that requires an independent reference.
This external assessment method contributes to altimeter calibrationâvalidation analyses
that cover a wide range of activities. Among them, several examples are given
to illustrate the usefulness of this approach, separating the analyses of the
long-term evolution of the mean sea level and its variability, at global and
regional scales and results obtained via relative and absolute comparisons.
The latter requires the use of the ocean mass contribution to the sea level
derived from Gravity Recovery and Climate Experiment (GRACE) measurements. Our analyses cover the estimation of the
global mean sea level trend, the validation of multi-missions altimeter
products as well as the assessment of orbit solutions.<br><br>Even if this approach contributes to the altimeter quality assessment, the
differences between two versions of altimeter standards are getting smaller
and smaller and it is thus more difficult to detect their impact. It is
therefore essential to characterize the errors of the method, which is
illustrated with the results of sensitivity analyses to different
parameters. This includes the format of the altimeter data, the method of
collocation, the temporal reference period and the processing of the ocean
mass solutions from GRACE. We also assess the impact of the temporal and
spatial sampling of Argo floats, the choice of the reference depth of the
in situ profiles and the importance of the deep steric contribution. These
analyses provide an estimation of the robustness of the method and the
characterization of associated errors. The results also allow us to draw
some recommendations to the Argo community regarding the maintenance of the
in situ network
Evaluation of wet troposphere path delays from atmospheric reanalyses and radiometers and their impact on the altimeter sea level
The assessment of long-term errors in altimeter sea level measurements is
essential for studies related to the mean sea level (MSL) evolution. One of
the main contributors to the long-term sea level uncertainties is the
correction of the altimeter range from the wet troposphere path delay, which
is provided by onboard microwave radiometers for the main altimeter missions.
The wet troposphere correction (WTC) derived from the operational European
Centre for Medium-Range Weather Forecast (ECMWF) atmospheric model is usually
used as a reference for comparison with the radiometer WTC. However, due to
several improvements in the processing, this model is not homogenous over the
altimetry period (from 1993 onwards), preventing the detection of errors in
the radiometer WTC, especially in the first altimetry decade. In this study,
we determine the quality of WTC provided by the operational ECMWF atmospheric
model in comparison with the fields derived from the ERA-Interim (ECMWF) and
the National Centers for Environmental Predictions/National Center for
Atmospheric Research (NCEP/NCAR) reanalyses. Separating our analyses on
several temporal and spatial scales, we demonstrate that ERA-Interim provides
the best modeled WTC for the altimeter sea level at climate scales. This
allows us to better evaluate the radiometer WTC errors, especially for the
first altimetry decade (1993â2002), and thus to improve the altimeter MSL
error budget. This work also demonstrates the relevance of the interactions
between the "altimetry" and "atmosphere" communities, since the expertise
of each is of benefit to the other
Coastal sea level anomalies and associated trends from Jason satellite altimetry over 2002-2018 [Data paper]
Climate-related sea level changes in the world coastal zones result from the superposition of the global mean rise due to ocean warming and land ice melt, regional changes caused by non-uniform ocean thermal expansion and salinity changes, and by the solid Earth response to current water mass redistribution and associated gravity change, plus small-scale coastal processes (e.g., shelf currents, wind & waves changes, fresh water input from rivers, etc.). So far, satellite altimetry has provided global gridded sea level time series up to 10-15km to the coast only, preventing estimation of sea level changes very close to the coast. Here we present a 16-year-long (June 2002 to May 2018), high-resolution (20-Hz), along-track sea level dataset at monthly interval, together with associated sea level trends, at 429 coastal sites in six regions (Northeast Atlantic, Mediterranean Sea, Western Africa, North Indian Ocean, Southeast Asia and Australia). This new coastal sea level product is based on complete reprocessing of raw radar altimetry waveforms from the Jason-1, Jason-2 and Jason-3 missions