9781003363873_10.1201_9781003363873-1.pdf

The 100-year record of daily sea-surface temperature (SST) acquired at the Hopkins Marine Station (HMS) in Pacific Grove, California, is one of the longest oceanographic records in existence. It is exceeded in length by the record at Scripps Pier by only 3 years. The history of the record at HMS, th...

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Έκδοση: Taylor & Francis 2023
id oapen-20.500.12657-76826
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spelling oapen-20.500.12657-768262023-10-17T02:09:47Z Chapter One Hundred Years of Daily Sea-Surface Temperature from the Hopkins Marine Station in Pacific Grove, California Breaker, Laurence C. Miller, Luke P. Daily Sea-Surface Temperature Hopkins Marine Station Monterey Bay 100-Year Record Physical Oceanography Marine Biology North Pacific Marine Heat Wave Coastal Laurence C. Breaker and San Diego State University bic Book Industry Communication::R Earth sciences, geography, environment, planning::RN The environment::RNC Applied ecology bic Book Industry Communication::W Lifestyle, sport & leisure::WN Natural history::WNW The Earth: natural history general bic Book Industry Communication::R Earth sciences, geography, environment, planning::RB Earth sciences::RBK Hydrology & the hydrosphere::RBKC Oceanography (seas) bic Book Industry Communication::T Technology, engineering, agriculture::TQ Environmental science, engineering & technology bic Book Industry Communication::R Earth sciences, geography, environment, planning::RN The environment::RNP Pollution & threats to the environment::RNPG Climate change bic Book Industry Communication::P Mathematics & science::PS Biology, life sciences::PSP Hydrobiology::PSPM Marine biology bic Book Industry Communication::P Mathematics & science::PS Biology, life sciences::PSA Life sciences: general issues::PSAF Ecological science, the Biosphere bic Book Industry Communication::P Mathematics & science::PS Biology, life sciences::PSA Life sciences: general issues::PSAJ Evolution bic Book Industry Communication::P Mathematics & science::PS Biology, life sciences The 100-year record of daily sea-surface temperature (SST) acquired at the Hopkins Marine Station (HMS) in Pacific Grove, California, is one of the longest oceanographic records in existence. It is exceeded in length by the record at Scripps Pier by only 3 years. The history of the record at HMS, the methods used to gather the data, the problems that were encountered, and finally, the scientific significance of this record are presented. Reconstructing a complete version of the 100-year time series record was not straightforward. Two major gaps had to be filled using data from another site, and variation in the time of day for sample collection was addressed to better standardise the SST values presented. The observations were first examined for their oceanographic content based on the relevant timescales involved that ranged from daily to the record length, i.e., centennial. The major sources of variability included the El Niño phenomenon, the Pacific Decadal Oscillation, and the Marine Heat Wave (MHW) that began in 2014. The impact of the MHW cannot be overstated, and it was well represented in the data from the HMS. The use of the historical temperature record for studies of long-term changes in species and communities in the biological literature is highlighted. Finally, a set of conclusions is presented highlighting the important contributions of the SST dataset that are only possible through dedicated long-term environmental monitoring programmes such as the one reported here. 2023-10-16T09:44:15Z 2023-10-16T09:44:15Z 2023 chapter ONIX_20231016_9781032426969_2 9781032426969 9781032548456 9781003363873 https://library.oapen.org/handle/20.500.12657/76826 eng application/pdf Attribution-NonCommercial-NoDerivatives 4.0 International 9781003363873_10.1201_9781003363873-1.pdf Taylor & Francis Oceanography and Marine Biology CRC Press 10.1201/9781003363873-2 10.1201/9781003363873-2 7b3c7b10-5b1e-40b3-860e-c6dd5197f0bb a56f7fb8-e1e2-4255-8dc7-83834c7e9de5 0e915551-049d-4cfb-b0e6-0fcdd721bd3c 9781032426969 9781032548456 9781003363873 CRC Press 32 Boca Raton, Abingdon [...] San Diego State University SDSU open access
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language English
description The 100-year record of daily sea-surface temperature (SST) acquired at the Hopkins Marine Station (HMS) in Pacific Grove, California, is one of the longest oceanographic records in existence. It is exceeded in length by the record at Scripps Pier by only 3 years. The history of the record at HMS, the methods used to gather the data, the problems that were encountered, and finally, the scientific significance of this record are presented. Reconstructing a complete version of the 100-year time series record was not straightforward. Two major gaps had to be filled using data from another site, and variation in the time of day for sample collection was addressed to better standardise the SST values presented. The observations were first examined for their oceanographic content based on the relevant timescales involved that ranged from daily to the record length, i.e., centennial. The major sources of variability included the El Niño phenomenon, the Pacific Decadal Oscillation, and the Marine Heat Wave (MHW) that began in 2014. The impact of the MHW cannot be overstated, and it was well represented in the data from the HMS. The use of the historical temperature record for studies of long-term changes in species and communities in the biological literature is highlighted. Finally, a set of conclusions is presented highlighting the important contributions of the SST dataset that are only possible through dedicated long-term environmental monitoring programmes such as the one reported here.
title 9781003363873_10.1201_9781003363873-1.pdf
spellingShingle 9781003363873_10.1201_9781003363873-1.pdf
title_short 9781003363873_10.1201_9781003363873-1.pdf
title_full 9781003363873_10.1201_9781003363873-1.pdf
title_fullStr 9781003363873_10.1201_9781003363873-1.pdf
title_full_unstemmed 9781003363873_10.1201_9781003363873-1.pdf
title_sort 9781003363873_10.1201_9781003363873-1.pdf
publisher Taylor & Francis
publishDate 2023
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