Earth System Dynamics: The Determination and Interpretation of the Global Angular Momentum Budget using the Earth Observing System

The objective of this investigation has been to examine the mass and momentum exchange between the atmosphere, oceans, solid Earth, hydrosphere, and cryosphere. The investigation has focused on changes in the Earth's gravity field, its rotation rate, atmospheric and oceanic circulation, global...

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Language:unknown
Published: 2003
Subjects:
Meteorology and Climatology
Ice Sheet
Online Access:http://hdl.handle.net/2060/20040046879
id ftnasantrs:oai:casi.ntrs.nasa.gov:20040046879
record_format openpolar
spelling ftnasantrs:oai:casi.ntrs.nasa.gov:20040046879 2023-05-15T16:41:38+02:00 Earth System Dynamics: The Determination and Interpretation of the Global Angular Momentum Budget using the Earth Observing System Unclassified, Unlimited, Publicly available [2003] application/pdf http://hdl.handle.net/2060/20040046879 unknown Document ID: 20040046879 http://hdl.handle.net/2060/20040046879 No Copyright CASI Meteorology and Climatology 2003 ftnasantrs 2019-07-21T07:43:16Z The objective of this investigation has been to examine the mass and momentum exchange between the atmosphere, oceans, solid Earth, hydrosphere, and cryosphere. The investigation has focused on changes in the Earth's gravity field, its rotation rate, atmospheric and oceanic circulation, global sea level change, ice sheet change, and global ground water circulation observed by contemporary sensors and models. The primary component of the mass exchange is water. The geodetic observables provided by these satellite sensors are used to study the transport of water mass in the hydrological cycle from one component of the Earth to another, and they are also used to evaluate the accuracy of models. As such, the investigation is concerned with the overall global water cycle. This report provides a description of scientific, educational and programmatic activities conducted during the period July 1, 1999 through June 30,2000. Research has continued into measurements of time-varying gravity and its relationship to Earth rotation. Variability of angular momentum and the related excitation of polar motion and Earth rotation have been examined for the atmosphere and oceans at time-scales of weeks to several years. To assess the performance of hydrologic models, we have compared geodetic signals derived from them with those observed by satellites. One key component is the interannual mass variability of the oceans obtained by direct observations from altimetry after removing steric signals. Further studies have been conducted on the steric model to quantify its accuracy at global and basin-scales. The results suggest a significant loss of water mass from the Oceans to the land on time-scales longer than 1-year. These signals are not reproduced in any of the models, which have poorly determined interannual fresh water fluxes. Output from a coupled atmosphere-ocean model testing long-term climate change hypotheses has been compared to simulated errors from the Gravity Recovery and Climate Experiment (GRACE) mission. Results indicate that GRACE will be able to observe seasonal signals at half-wavelengths ranging from 1000 to 10000 km, and may be able to observe secular trends at half- wavelengths of greater than 2000-3000 km for soil moisture and snow depth if they are as large as some of the climate experiments predict. Other/Unknown Material Ice Sheet NASA Technical Reports Server (NTRS)
institution Open Polar
collection NASA Technical Reports Server (NTRS)
op_collection_id ftnasantrs
language unknown
topic Meteorology and Climatology
spellingShingle Meteorology and Climatology
Earth System Dynamics: The Determination and Interpretation of the Global Angular Momentum Budget using the Earth Observing System
topic_facet Meteorology and Climatology
description The objective of this investigation has been to examine the mass and momentum exchange between the atmosphere, oceans, solid Earth, hydrosphere, and cryosphere. The investigation has focused on changes in the Earth's gravity field, its rotation rate, atmospheric and oceanic circulation, global sea level change, ice sheet change, and global ground water circulation observed by contemporary sensors and models. The primary component of the mass exchange is water. The geodetic observables provided by these satellite sensors are used to study the transport of water mass in the hydrological cycle from one component of the Earth to another, and they are also used to evaluate the accuracy of models. As such, the investigation is concerned with the overall global water cycle. This report provides a description of scientific, educational and programmatic activities conducted during the period July 1, 1999 through June 30,2000. Research has continued into measurements of time-varying gravity and its relationship to Earth rotation. Variability of angular momentum and the related excitation of polar motion and Earth rotation have been examined for the atmosphere and oceans at time-scales of weeks to several years. To assess the performance of hydrologic models, we have compared geodetic signals derived from them with those observed by satellites. One key component is the interannual mass variability of the oceans obtained by direct observations from altimetry after removing steric signals. Further studies have been conducted on the steric model to quantify its accuracy at global and basin-scales. The results suggest a significant loss of water mass from the Oceans to the land on time-scales longer than 1-year. These signals are not reproduced in any of the models, which have poorly determined interannual fresh water fluxes. Output from a coupled atmosphere-ocean model testing long-term climate change hypotheses has been compared to simulated errors from the Gravity Recovery and Climate Experiment (GRACE) mission. Results indicate that GRACE will be able to observe seasonal signals at half-wavelengths ranging from 1000 to 10000 km, and may be able to observe secular trends at half- wavelengths of greater than 2000-3000 km for soil moisture and snow depth if they are as large as some of the climate experiments predict.
title Earth System Dynamics: The Determination and Interpretation of the Global Angular Momentum Budget using the Earth Observing System
title_short Earth System Dynamics: The Determination and Interpretation of the Global Angular Momentum Budget using the Earth Observing System
title_full Earth System Dynamics: The Determination and Interpretation of the Global Angular Momentum Budget using the Earth Observing System
title_fullStr Earth System Dynamics: The Determination and Interpretation of the Global Angular Momentum Budget using the Earth Observing System
title_full_unstemmed Earth System Dynamics: The Determination and Interpretation of the Global Angular Momentum Budget using the Earth Observing System
title_sort earth system dynamics: the determination and interpretation of the global angular momentum budget using the earth observing system
publishDate 2003
url http://hdl.handle.net/2060/20040046879
op_coverage Unclassified, Unlimited, Publicly available
genre Ice Sheet
genre_facet Ice Sheet
op_source CASI
op_relation Document ID: 20040046879
http://hdl.handle.net/2060/20040046879
op_rights No Copyright
_version_ 1766032082800214016

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