LIU Yonggang, YUAN Yaochu, LIU Cho-Teng, CHEN Hong. Measurement of the current and spectral analysis on the continental shelf in the East China Sea[J]. Acta Oceanologica Sinica, 2004, (2): 201-212.
Citation:
LIU Yonggang, YUAN Yaochu, LIU Cho-Teng, CHEN Hong. Measurement of the current and spectral analysis on the continental shelf in the East China Sea[J]. Acta Oceanologica Sinica, 2004, (2): 201-212.
LIU Yonggang, YUAN Yaochu, LIU Cho-Teng, CHEN Hong. Measurement of the current and spectral analysis on the continental shelf in the East China Sea[J]. Acta Oceanologica Sinica, 2004, (2): 201-212.
Citation:
LIU Yonggang, YUAN Yaochu, LIU Cho-Teng, CHEN Hong. Measurement of the current and spectral analysis on the continental shelf in the East China Sea[J]. Acta Oceanologica Sinica, 2004, (2): 201-212.
College of Marine Science, University of South Florida, U S A;Second Institute of Oceanography, State Oceanic Administration, Hangzhou 310012, China
2.
Second Institute of Oceanography, State Oceanic Administration, Hangzhou 310012, China;Key Laboratory of Ocean Dynamic Processes and Satellite Oceanography of State Oceanic Administration, Hangzhou 310012, China
3.
Institute of Oceanography, Taiwan University, Taipei, China
4.
Second Institute of Oceanography, State Oceanic Administration, Hangzhou 310012, China
Direct measurements of current velocity and water temperature were undertaken at the mooring Sta. M (125°29.38'N, 31°49.70'E) on the continental shelf area in the East China Sea in June 1999 by R/V Xiangyanghong 14. The relationship between various time series of oceanic fluctuations is calculated by spectral analysis. The major results are as follows:(1) an average (u,v) of (6.9,-3.0 cm/s) at the 30 m depth is obtained during the 9-day observation, and that at the 45 m depth is (3.7,-1.1 cm/s), i. e., the mean flows are southeastward at both the 30 and 45 m depths;the currents become stronger gradually during the observation period; this may be mainly attributed to the transition of the tidal currents from neap to spring; (2)semidiurnal fluctuation is the most dominant in the current fluctuations, and rotates mainly clockwise; in the next place, there is also diurnal fluctuation;the local inertial period is close to the period of diurnal fluctuation, and an inertial motion is clockwise; thus, local inertial motion combines with diurnal fluctuation, and makes the spectral peaks in clockwise components much higher than those in counterclockwise ones;except for the fluctuations of above main periods, there is also the peak at 3 d period for counterclockwise components in the upper and lower layers; (3) the calculation of cross spectra between two time series of current velocities at the 30 and 45 m depths shows that both the current fluctuations at the 30 and 45 m depths are much alike, i.e.,they are synchro; this shows that the flow field here is rather vertically homogeneous; (4)power spectra of temperature time series at both the 30 and 45 m depths show that the semidiurnal peak is the most predominant, and the second highest peak is the diurnal period; besides spectral peaks at above periods, there are also obvious spectral peaks at 6.8 h and 2 d; (5)plots of temperature time series at 16,30,35,45 and 50 m depths show that the temporal variations of temperature at these depths are synchro, which are like those in the velocity field; temperature records also show a gradual rise in temperature, which are also like those in the velocity field.