Mindanao Current Explained

The Mindanao Current (MC) is a southward current in the western Pacific Ocean that transports mass and freshwater between ocean basins. It is a low-latitude western boundary current that follows the eastern coast of the Philippine island group and its namesake, Mindanao. The MC forms from the North Equatorial Current (NEC) that flows from east to west between 10-20°N. As it travels west, the NEC reaches its western limit: the coast of the Philippines.[1] Once it encounters shallower waters near land, it “splits” into two branches: one moves northward and becomes the Kuroshio current and one moves southward and becomes the Mindanao Current.[2] The process of splitting is called a bifurcation.

The Mindanao Current flows towards the equator and is most intense near the surface, reaching maximum speeds of

1.3

ms-1

.[3] It can be observed until depths of

1000

m

near the Philippine coast and extends until

350

km

offshore. The MC transports climatic signals and in doing so, influences the regional climate and the El Niño-Southern Oscillation (ENSO). Overall, the Mindanao Current is critical in the circulation within the whole Pacific basin. However, in comparison with other boundary currents in the North Pacific, the Mindanao Current has received limited attention and therefore little is known about it.[4]

Physical Properties

The Mindanao Current is a low-latitude western boundary current located in the North Pacific and formed at the Philippine Sea by the bifurcation of the NEC. The jet transports approximately

13-39

Sv (where

1

Sv=106m3s-1

) to the equator. It flows alongside the contours of the Philippine coast, approximately following the mean dynamic bathymetry based on underwater glider observations. The MC feeds the equatorial currents, including the North Equatorial Countercurrent and the Indonesian Throughflow which transports water from the Pacific to the Indian Ocean. Thus, the Mindanao Current serves a role in the global overturning circulation. It often interacts with the nearby Mindanao Eddy which is a semi-permanent cyclonic recirculation to the east. Beneath the Mindanao Current is an even less studied undercurrent, the Mindanao Undercurrent (MUC), which is deeper than

400

m

and lies offshore of the MC. Both the MC and its undercurrent are pathways for the exchange of water in the tropical Pacific.

Identified by its salinity signature, the MC waters from the surface to

200

m

depth are North Pacific Tropical Water (NPTW) while the layer at

300-500

m

depth is North Pacific Intermediate water (NPIW). The NPTW is characterized by a salinity maximum of

35

psu

or Practical Salinity Units which is relatively high. As the water mass is advected southward by the MC, it evolves: the salinity maximum decays by

0.1

psu

along the Philippine coast. Once it reaches a latitude of 6°N, it becomes indiscernible. In contrast, the waters of the MUC transport Antarctic Intermediate Water which originates from the south Pacific. It is characterized by a salinity greater than

34.5

psu

and usually contains more oxygen than the NPIW.

The MC originates from the southern branch of the NEC bifurcation. Its northern branch becomes the Kuroshio current which begins as a weak and variable current that strengthens at the Luzon Strait. The Kuroshio must travel a larger distance to gain speed than the Mindanao Current which is strong closer to the bifurcation location. It is fed by the southern portion of the NEC.

The NEC is a wide current, spanning approximately 10-20°N. Towards 10°N, it is relatively shallow while towards 20°N, it deepens significantly (in the order of

100

m

). As a consequence, the bifurcation location is northward with increasing depth, i.e., at the shallowest layer (

0-100

m

), the bifurcation occurs at ~12°N; at

100-300

m

, it occurs at ~13°N; at depths of

300-600

m

, it occurs at ~ 15°N. Thus, the origin of the Mindanao Current is more northern with depth.

Observations from December 2010 to August 2014 show that the surface MC (specifically

50-150

m

depth) varies from season to season. It is stronger during boreal or Northern Hemisphere spring and weaker during fall. From

150-400

m

, it is stronger in spring and fall and weaker in summer and winter. Seasonal variations in the MC are controlled by large-scale upper ocean circulation. The variations are often explained by local wind forcing of the western Pacific, both by local winds and winds in the Pacific’s interior which cause westward propagating Rossby waves.[5]

Predicted effects of climate change

Under the influence of climate change, models predict that western boundary currents will be affected in different ways. For the Mindanao Current in particular, numerous simulations have agreed that the current will decrease in strength. It is projected to decrease by a magnitude of

2.3-5.6

Sv

along with the Indonesian Throughflow which it supplies. Although the total transport will probably weaken, most of the weakening is subsurface and it will intensify above 100 m south of 7°S, which suggests that the MC will be shallower.[6] [7]

Relationship with the El Niño-Southern Oscillation

Climate affects the circulation of the western Pacific and on the yearly timescale, ENSO is a major driver. The MC is stronger in the developing stages of the El Niño and weaker during the decaying stage, although with a lot of uncertainty. These variations are probably due to the wind, but the specific mechanism varies with latitude. Profiles of the water column show that the surface salinity is highest during the 2010/11 El Niño and freshest at the end of the 2010/11 La Niña.[8]

Research initiatives focused on the current

The Mindanao Current is difficult to observe and model because of the strength of the current, the extreme topography of the region, and complicating factors such as wind stress fluctuations and eddies. The most extensive observations of the Mindanao Current were performed during the following research programs:

See also

External links

Notes and References

  1. Qiu . Bo . Lukas . Roger . Seasonal and interannual variability of the North Equatorial Current, the Mindanao Current, and the Kuroshio along the Pacific western boundary . Journal of Geophysical Research: Oceans . May 15, 1996 . 101 . C5 . 12315–12330 . 10.1029/95JC03204. 1996JGR...10112315Q .
  2. Schönau . Martha C. . Rudnick . Daniel L. . Cerovecki . Ivana . Gopalakrishnan . Ganesh . Cornuelle . Bruce D. . McClean . Julie L. . Qiu . Bo . The Mindanao Current: Mean structure and connectivity . Oceanography . December 2015 . 28 (4) . Special issue: A new look at the low-latitude western Pacific . 34–45 . 10.5670/oceanog.2015.79 . 24861926 . free .
  3. Ren . Qiuping . Li . Yuanlong . Wang . Fan . Duan . Jing . Hu . Shijian . Wang . Fujun . Variability of the Mindanao Current induced by El Niño events . Journal of Physical Oceanography . Jun 17, 2020 . 50 . 6 . 1753–1772 . 10.1175/JPO-D-19-0150.1. free .
  4. Rudnick . Daniel L. . Jan . Sen . Lee . Craig M. . A new look at circulation in the western North Pacific . Oceanography . 2015 . 28 . 4 . 16–23 . 10.5670/oceanog.2015.77. free .
  5. Ren . Qiuping . Li . Yuanlong . Wang . Fan . Song . Lina . Liu . Chuanyu . Zhai . Fangguo . Seasonality of the Mindanao Current/Undercurrent System . Journal of Geophysical Research: Oceans . January 25, 2018 . 123 . 2 . 1105–1122 . 10.1002/2017JC013474. 2018JGRC..123.1105R . free .
  6. Sen Gupta . Alex . Stellema . Annette . Pontes . Gabriel M. . Taschetto . Andréa S. . Andréa Sardinha Taschetto . Vergés . Adriana . Rossi . Vincent . 2021 . Future changes to the upper ocean Western Boundary Currents across two generations of climate models . Scientific Reports . 11 . 1 . 9538 . 2021NatSR..11.9538S . 10.1038/s41598-021-88934-w . 8099859 . 33953259.
  7. Stellema . Annette . Sen Gupta . Alex . Taschetto . Andréa S. . Feng . Ming . Pacific Equatorial Undercurrent: Mean state, sources, and future changes across models . Frontiers in Climate . 8 August 2022 . 4 . 10.3389/fclim.2022.933091 . free .
  8. Schönau . Martha C. . Rudnick . Daniel L. . Mindanao Current and Undercurrent: Thermohaline Structure and Transport from Repeat Glider Observations . Journal of Physical Oceanography . 2017 . 47 . 8 . 2055-2075 . 10.1175/JPO-D-16-0274.1. 2017JPO....47.2055S . free .
  9. Lindstrom . Eric . Lukas . Roger . Fine . Rana . Firing . Eric . Godfrey . Stuart . Meyers . Gary . Tsuchiya . Mizuki . The Western Equatorial Pacific Ocean Circulation Study . Nature . December 10, 1987 . 330 . 6148 . 533–537 . 10.1038/330533a0. 1987Natur.330..533L . 36887578 .
  10. McPhaden . Michael J. . Busalacchi . Antonio J. . Cheney . Robert . Donguy . Jean-René . Gage . Kenneth S. . Halpern . David . Ji . Ming . Julian . Paul . Meyers . Gary . Mitchum . Gary T. . Niiler . Pearn P. . Picaut . Joel . Reynolds . Richard W. . Smith . Neville . Takeuchi . Kensuke . The Tropical Ocean-Global Atmosphere observing system: A decade of progress . Journal of Geophysical Research . June 29, 1998 . 103 . C7 . 14169–14240 . 10.1029/97JC02906. 1998JGR...10314169M . free .
  11. Ganachaud . A. . Cravatte . S. . Melet . A. . Schiller . A. . Holbrook . N.J. . Sloyan . B.M. . Widlansky . M.J. . Bowen . M. . Verron . J. . Wiles . P. . Ridgway . K. . Sutton . P. . Sprintall . J. . Steinberg . C. . Brassington . G. . Cai . W. . Davis . R. . Gasparin . F. . Gourdeau . L. . Hasegawa . T. . Kessler . W. . Maes . C. . Takahashi . K. . Richards . K.J. . Send . U. . The Southwest Pacific Ocean circulation and climate experiment (SPICE) . Journal of Geophysical Research: Oceans . November 19, 2014 . 119 . 11 . 7660–7686 . 10.1002/2013JC009678. 2014JGRC..119.7660G . free . 20.500.12816/2932 . free .
  12. News: Rudnick . Daniel L. . Centurioni . Luca . Cornuelle . Bruce . McClean . Julie . Origins of the Kuroshio and Mindanao Current . Annual Report . Defense Technical Information Center . September 30, 2014.