A historical review of gravimetric observations in Norway

The first gravity determinations in Norway were made by Edward Sabine in 1823 with a pendulum instrument by Henry Kater. Seventy years later a Sterneck pendulum was acquired by the Norwegian Commission for the International Arc Measurements. It improved the precision and eventually reduced the bias...

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Bibliographic Details
Published in:History of Geo- and Space Sciences
Main Author: Pettersen, Bjørn Ragnvald
Format: Text
Language:English
Published: 2018
Subjects:
Arctic
Arctic Ocean
Kater
Norway
Sterneck
Svalbard
Climate change
Fennoscandia
Hammerfest
Online Access:https://doi.org/10.5194/hgss-7-79-2016
https://hgss.copernicus.org/articles/7/79/2016/
id ftcopernicus:oai:publications.copernicus.org:hgss53972
record_format openpolar
spelling ftcopernicus:oai:publications.copernicus.org:hgss53972 2023-05-15T15:19:05+02:00 A historical review of gravimetric observations in Norway Pettersen, Bjørn Ragnvald 2018-01-15 application/pdf https://doi.org/10.5194/hgss-7-79-2016 https://hgss.copernicus.org/articles/7/79/2016/ eng eng doi:10.5194/hgss-7-79-2016 https://hgss.copernicus.org/articles/7/79/2016/ eISSN: 2190-5029 Text 2018 ftcopernicus https://doi.org/10.5194/hgss-7-79-2016 2020-07-20T16:23:56Z The first gravity determinations in Norway were made by Edward Sabine in 1823 with a pendulum instrument by Henry Kater. Seventy years later a Sterneck pendulum was acquired by the Norwegian Commission for the International Arc Measurements. It improved the precision and eventually reduced the bias of the absolute calibration from 85 to 15 mGal. The last pendulum observations in Norway were made in 1955 with an instrument from Cambridge University. At a precision of ±1 mGal, the purpose was to calibrate a section of the gravity line from Rome, Italy, to Hammerfest, Norway. Relative spring gravimeters were introduced in Norway in 1946 and were used to densify and expand the national gravity network. These data were used to produce regional geoids for Norway and adjacent ocean areas. Improved instrument precision allowed them to connect Norwegian and foreign fundamental stations as well. Extensive geophysical prospecting was made, as in other countries. The introduction of absolute gravimeters based on free-fall methods, especially after 2004, improved the calibration by 3 orders of magnitude and immediately revealed the secular changes of the gravity field in Norway. This was later confirmed by satellite gravimetry, which provides homogeneous data sets for global and regional gravity models. The first-ever determinations of gravity at sea were made by pendulum observations onboard the Norwegian polar vessel Fram during frozen-in conditions in the Arctic Ocean in 1893–1896. Simultaneously, an indirect method was developed at the University of Oslo for deducing gravity at sea with a hypsometer. The precision of both methods was greatly superseded by relative spring gravimeters 50 years later. They were employed extensively both at sea and on land. When GPS allowed precise positioning, relative gravimeters were mounted in airplanes to cover large areas of ocean faster than before. Gravimetry is currently being applied to study geodynamical phenomena relevant to climate change. The viscoelastic postglacial land uplift of Fennoscandia has been detected by terrestrial gravity time series as well as by satellite gravimetry. Corrections for local effects of snow load, hydrology, and ocean loading at coastal stations have been improved. The elastic adjustment of present-day melting of glaciers at Svalbard and in mainland Norway has been detected. Gravimetry is extensively employed at offshore oil facilities to monitor the subsidence of the ocean floor during oil and gas extraction. Text Arctic Arctic Ocean Climate change Fennoscandia Hammerfest Svalbard Copernicus Publications: E-Journals Arctic Arctic Ocean Kater ENVELOPE(-59.833,-59.833,-63.817,-63.817) Norway Sterneck ENVELOPE(-61.017,-61.017,-64.183,-64.183) Svalbard History of Geo- and Space Sciences 7 2 79 89
institution Open Polar
collection Copernicus Publications: E-Journals
op_collection_id ftcopernicus
language English
description The first gravity determinations in Norway were made by Edward Sabine in 1823 with a pendulum instrument by Henry Kater. Seventy years later a Sterneck pendulum was acquired by the Norwegian Commission for the International Arc Measurements. It improved the precision and eventually reduced the bias of the absolute calibration from 85 to 15 mGal. The last pendulum observations in Norway were made in 1955 with an instrument from Cambridge University. At a precision of ±1 mGal, the purpose was to calibrate a section of the gravity line from Rome, Italy, to Hammerfest, Norway. Relative spring gravimeters were introduced in Norway in 1946 and were used to densify and expand the national gravity network. These data were used to produce regional geoids for Norway and adjacent ocean areas. Improved instrument precision allowed them to connect Norwegian and foreign fundamental stations as well. Extensive geophysical prospecting was made, as in other countries. The introduction of absolute gravimeters based on free-fall methods, especially after 2004, improved the calibration by 3 orders of magnitude and immediately revealed the secular changes of the gravity field in Norway. This was later confirmed by satellite gravimetry, which provides homogeneous data sets for global and regional gravity models. The first-ever determinations of gravity at sea were made by pendulum observations onboard the Norwegian polar vessel Fram during frozen-in conditions in the Arctic Ocean in 1893–1896. Simultaneously, an indirect method was developed at the University of Oslo for deducing gravity at sea with a hypsometer. The precision of both methods was greatly superseded by relative spring gravimeters 50 years later. They were employed extensively both at sea and on land. When GPS allowed precise positioning, relative gravimeters were mounted in airplanes to cover large areas of ocean faster than before. Gravimetry is currently being applied to study geodynamical phenomena relevant to climate change. The viscoelastic postglacial land uplift of Fennoscandia has been detected by terrestrial gravity time series as well as by satellite gravimetry. Corrections for local effects of snow load, hydrology, and ocean loading at coastal stations have been improved. The elastic adjustment of present-day melting of glaciers at Svalbard and in mainland Norway has been detected. Gravimetry is extensively employed at offshore oil facilities to monitor the subsidence of the ocean floor during oil and gas extraction.
format Text
author Pettersen, Bjørn Ragnvald
spellingShingle Pettersen, Bjørn Ragnvald
A historical review of gravimetric observations in Norway
author_facet Pettersen, Bjørn Ragnvald
author_sort Pettersen, Bjørn Ragnvald
title A historical review of gravimetric observations in Norway
title_short A historical review of gravimetric observations in Norway
title_full A historical review of gravimetric observations in Norway
title_fullStr A historical review of gravimetric observations in Norway
title_full_unstemmed A historical review of gravimetric observations in Norway
title_sort historical review of gravimetric observations in norway
publishDate 2018
url https://doi.org/10.5194/hgss-7-79-2016
https://hgss.copernicus.org/articles/7/79/2016/
long_lat ENVELOPE(-59.833,-59.833,-63.817,-63.817)
ENVELOPE(-61.017,-61.017,-64.183,-64.183)
geographic Arctic
Arctic Ocean
Kater
Norway
Sterneck
Svalbard
geographic_facet Arctic
Arctic Ocean
Kater
Norway
Sterneck
Svalbard
genre Arctic
Arctic Ocean
Climate change
Fennoscandia
Hammerfest
Svalbard
genre_facet Arctic
Arctic Ocean
Climate change
Fennoscandia
Hammerfest
Svalbard
op_source eISSN: 2190-5029
op_relation doi:10.5194/hgss-7-79-2016
https://hgss.copernicus.org/articles/7/79/2016/
op_doi https://doi.org/10.5194/hgss-7-79-2016
container_title History of Geo- and Space Sciences
container_volume 7
container_issue 2
container_start_page 79
op_container_end_page 89
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