Energy Sources Generation and Energy Cascades along the Kuroshio East of Taiwan Island and the East China Sea

Energy Sources Generation and Energy Cascades along the Kuroshio East of Taiwan Island and the East China Sea

There are multi-spatial-scale ocean dynamic processes in the western boundary current region, so the budget of energy source and sink in the Kuroshio Current area can describe the oceanic energy cycle and transformation more accurately. The slope of the one-dimensional spectral energy density varies...

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Main Authors: Ru Wang, Yijun Hou, Ze Liu
Format: Article
Language:English
Published: MDPI AG 2021-06-01
Series:Journal of Marine Science and Engineering
Subjects:
energy source
inverse energy cascade
wind stress
density differences
energy flux
Online Access:https://www.mdpi.com/2077-1312/9/7/692
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spelling doaj-705e0aacf9504162a8dc9b97567af5d52021-07-23T13:48:39ZengMDPI AGJournal of Marine Science and Engineering2077-13122021-06-01969269210.3390/jmse9070692Energy Sources Generation and Energy Cascades along the Kuroshio East of Taiwan Island and the East China SeaRu Wang0Yijun Hou1Ze Liu2Key Laboratory of Ocean Circulation and Waves, Institute of Oceanology, Chinese Academy of Sciences, Qingdao 266071, ChinaKey Laboratory of Ocean Circulation and Waves, Institute of Oceanology, Chinese Academy of Sciences, Qingdao 266071, ChinaKey Laboratory of Ocean Circulation and Waves, Institute of Oceanology, Chinese Academy of Sciences, Qingdao 266071, ChinaThere are multi-spatial-scale ocean dynamic processes in the western boundary current region, so the budget of energy source and sink in the Kuroshio Current area can describe the oceanic energy cycle and transformation more accurately. The slope of the one-dimensional spectral energy density varies between −5/3 and −3 in the wavenumber range of 0.02–0.1 cpkm, indicating an inverse energy cascade in the Kuroshio of Taiwan Island and the East China Sea. According to the steady-state energy evolution, an energy source must be present. The locations of energy sources were identified using the spectral energy transfer calculated by 24 years of Ocean General Circulation Model for the Earth Simulator (OFES) data. At the sea surface, the kinetic energy (KE) sources are mainly within 23.2°–25.6° Nand 28°–29° N at less than 0.02 cpkm and within 23.2°–25° N and 26°–30° N at 0.02–0.1 cpkm. The available potential energy (APE) sources are mainly within 22°–28° N and 28.6°–30° N at less than 0.02 cpkm and within 22.6°–24.6° N, 25.4°–28° N and 29.2°–30° N at 0.02–0.1 cpkm. Beneath the sea surface, the energy sources are mainly above 400 m depth. Wind stress and density differences are primarily responsible for the KE and APE sources, respectively. Once an energy source is formed, to maintain a steady state, energy cascades (mainly inverse cascades by calculating spectral energy flux) will be engendered. By calculating the energy flux at 600 m depth, KE changes from inflow (sink) to outflow (source), and the conversion depth of source and sink is 380 m. However, outflow of the APE behaves as the source.https://www.mdpi.com/2077-1312/9/7/692energy sourceinverse energy cascadewind stressdensity differencesenergy flux
collection DOAJ
language English
format Article
sources DOAJ
author Ru Wang
Yijun Hou
Ze Liu
spellingShingle Ru Wang
Yijun Hou
Ze Liu
Energy Sources Generation and Energy Cascades along the Kuroshio East of Taiwan Island and the East China Sea
Journal of Marine Science and Engineering
energy source
inverse energy cascade
wind stress
density differences
energy flux
author_facet Ru Wang
Yijun Hou
Ze Liu
author_sort Ru Wang
title Energy Sources Generation and Energy Cascades along the Kuroshio East of Taiwan Island and the East China Sea
title_short Energy Sources Generation and Energy Cascades along the Kuroshio East of Taiwan Island and the East China Sea
title_full Energy Sources Generation and Energy Cascades along the Kuroshio East of Taiwan Island and the East China Sea
title_fullStr Energy Sources Generation and Energy Cascades along the Kuroshio East of Taiwan Island and the East China Sea
title_full_unstemmed Energy Sources Generation and Energy Cascades along the Kuroshio East of Taiwan Island and the East China Sea
title_sort energy sources generation and energy cascades along the kuroshio east of taiwan island and the east china sea
publisher MDPI AG
series Journal of Marine Science and Engineering
issn 2077-1312
publishDate 2021-06-01
description There are multi-spatial-scale ocean dynamic processes in the western boundary current region, so the budget of energy source and sink in the Kuroshio Current area can describe the oceanic energy cycle and transformation more accurately. The slope of the one-dimensional spectral energy density varies between −5/3 and −3 in the wavenumber range of 0.02–0.1 cpkm, indicating an inverse energy cascade in the Kuroshio of Taiwan Island and the East China Sea. According to the steady-state energy evolution, an energy source must be present. The locations of energy sources were identified using the spectral energy transfer calculated by 24 years of Ocean General Circulation Model for the Earth Simulator (OFES) data. At the sea surface, the kinetic energy (KE) sources are mainly within 23.2°–25.6° Nand 28°–29° N at less than 0.02 cpkm and within 23.2°–25° N and 26°–30° N at 0.02–0.1 cpkm. The available potential energy (APE) sources are mainly within 22°–28° N and 28.6°–30° N at less than 0.02 cpkm and within 22.6°–24.6° N, 25.4°–28° N and 29.2°–30° N at 0.02–0.1 cpkm. Beneath the sea surface, the energy sources are mainly above 400 m depth. Wind stress and density differences are primarily responsible for the KE and APE sources, respectively. Once an energy source is formed, to maintain a steady state, energy cascades (mainly inverse cascades by calculating spectral energy flux) will be engendered. By calculating the energy flux at 600 m depth, KE changes from inflow (sink) to outflow (source), and the conversion depth of source and sink is 380 m. However, outflow of the APE behaves as the source.
topic energy source
inverse energy cascade
wind stress
density differences
energy flux
url https://www.mdpi.com/2077-1312/9/7/692
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AT zeliu energysourcesgenerationandenergycascadesalongthekuroshioeastoftaiwanislandandtheeastchinasea
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