Received date: 2002-08-23
Revised date: 2003-01-28
Online published: 2003-06-01
The permanent Arctic halocline, one of the particular structures in the upper Arctic ocean, is very important to the maintenance ofthe sea ice and cold surface layer in the Arctic ocean. In the last decade, a large-scale change occurred in the Arctic climatic system, which had never been observed before 1990s. At the same time, the Cold Halocline Layer (CHL) of the Arctic ocean experienced a special evolution with disappearing at the early 1990s and then partially recovering in 1998. In this circumstance, the Arctic halocline became a new focus of the Arctic ocean research. The recent advances in the studies on the Arctic halocline, including the mechanism for its formation and observations of its inter-annual variations, were reviewed in this paper. The unsolved problems in the previous research works and possible advances in the future studies were also commented.
Several theories of the formation for the Arctic halocline had been presented, such as “Advective CHL” and “Convective CHL”. Because the surface salinity in the Eurasia basin had increased, the CHL in the Eurasia basin should be “Convective CHL”. The “Advective CHL” mechanism might be suitable for the halocline in the Canada basin as its characteristics is quite different from that of the CHL in the Eurasia basin. Since 1990s, a series of anomalous variations had been found,such as the retreating of CHL, the warming of the Atlantic layer and the decreasing of the Arctic sea ice. In fact, all these variations are connected closely.The partial recovery of the Arctic halocline implied that the observed variations in the Arctic climatic system could be a kind of periodical oscillation.
Key words: Halocline; Arctic ocean; Inter-annual variation.
Shi Jiuxin, Zhao Jinping . ADVANCES IN STUDIES ON THE ARCTIC HALOCLINE[J]. Advances in Earth Science, 2003 , 18(3) : 351 -357 . DOI: 10.11867/j.issn.1001-8166.2003.03.0351
[1] Aagaard K, Coachman L K. Toward an ice-free Arctic Ocean [J]. EOS, 1975,56: 484-486.
[2] Aaggaard K, Coachman L K, Carmack E. On the halocline of the Arctic Ocean[J]. Deep-Sea Research, 1981,28:529-545.
[3] Morison J, Steele M, Andersen R. Hydrography of the upper Arctic Ocean measured from the nuclear submarine USS Pargo[J]. Deep-Sea Research, 1998, 45: 15-38.
[4] Steele M, Boyd T. Retreat of the cold halocline layer in the Arctic Ocean[J]. Journal of Geophysical Research, 1998, 103(C5): 10 419-10 435.
[5] McLaughlin F A, Carmack E C, Macdonald R W, et al. Physical and geochemical properties across the Atlantic/Pacific water mass front in the southern Canadian basin[J]. Journal of Geophysical Research, 1996, 101(C1):1 183-1 197.
[6] Cavalieri D J, Martin S. The contribution of Alaskan, Siberian and Canadian coastal polynyas to the cold halocline layer of the Arctic Ocean[J]. Journal of Geophysical Research, 1994, 99(C9):18 343-18 362.
[7] Rudels B, Anderson L G, Jones E P. Formation and evolution of the surface mixed layer and halocline of the Arctic Ocean[J]. Journal of Geophysical Research, 1996, 101(C4): 8 807-8 821.
[8] Jones E P, Anderson L G. On the origin of the chemical properties of the Arctic Ocean halocline[J]. Journal of Geophysical Research, 1986, 91(C9): 10 759-10 767.
[9] Martin S, Cavalieri D J. Contributions of the Siberian Shelf polynyas to the Arctic Ocean intermediate and deep water[J]. Journal of Geophysical Research, 1989,94: 12 725-12 738.
[10] Melling H, Lewis E L. Shelf drainage flows in the Beaufort Sea and their effect on the Arctic pycnocline[J]. Deep-Sea Research, 1982, 29: 967-985.
[11] Aagaard K, Swift J H, Carmack E C. Thermohaline circulation in the Arctic Mediterranean Seas[J]. Journal of Geophysical Research, 1985, 90:4 833-4 846.
[12] Weingartner T J, Cavalieri D J, Aagaard K, et al. Circulation, dense water formation, and outflow on the northeast Chukchi shelf[J]. Journal of Geophysical Research, 1998,103(C4): 7 647-7 661.
[13] Melling H. The formation of a halocline shelf front in wintertime in an ice-covered Arctic Sea[J]. Continental Shelf Research, 1993, 13: 1 123-1 147.
[14] Melling H, Moore R M. Modification of halocline source waters during freezing on the Beaufort Sea shelf: Evidence from oxygen isotopes and dissolved nutrients[J]. Continental Shelf Research, 1995, 15:89-114.
[15] Boyd T J, Steele M, Muench R D, et al. Partial recovery of the Arctic Ocean halocline[J]. Geophysical Research Letter, 2002, 29(14):doi:10.1029/2001GL014047.
[16] Rothrock D A, Yu Y, Maykut G A. Thinning of the Arctic Sea-Ice Cover[J]. Geophysical Research Letter, 1999,26:3 469-3 472.
[17] Moore R M, Lowings M G, Tan F C. Geochemical profiles in the central Arctic Ocean: Their relation to freezing and shallow circulation[J]. Journal of Geophysical Research, 1983,88: 2 667-2 674.
[18] Anderson L G, BJork G, Holby O, et al. Water masses and circulation in the Eurasian basin: Results from the Oden 91 expediton[J]. Journal of Geophysical Research, 1994,99: 3 273-3 283.
[19] Swift J H, Jones E P, Aagaard K, et al. Waters of the Makarov and Canada basins[J]. Deep-Sea Research II, 1997,44: 1 503-1 529.
[20] Wilson C, Wallace D W R. Using the nutrient ratio NO/PO as a tracer of continental shelf waters in the central Arctic Ocean[J]. Journal of Geophysical Research, 1990, 95: 22 193-22 208.
[21] Guay C K, Falkner K K. Barium as a tracer of Arctic halocline and river waters[J]. Deep-Sea Research II, 1997 ,44: 1 543-1 569.
[22] Carmack E C, Killworth P D. Formation and interleaving of abyssal water masses off Wilkes Land[J]. Deep-Sea Research, 1978,25: 357-369.
/
| 〈 |
|
〉 |
