Decadal variability in the Kuroshio and Oyashio Extension frontal regions in an eddy-resolving OGCM

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Decadal variability in the Kuroshio and Oyashio Extension frontal regions in an eddy-resolving OGCM Masami Nonaka 1, Hisashi Nakamura 1,2, Youichi Tanimoto 1,3, Takashi Kagimoto 1, and Hideharu Sasaki 4 1. Frontier Research Center for Global Change, JAMSTEC 2. Graduate school of Science, the University of Tokyo 3. Graduate school of Environmental Earth Science, Hokkaido Univ. 4. The Earth Simulator Center, JAMSTEC

Introduction How do these oceanic frontal regions vary in association with the decadal SSTAs? Kuroshio-Oyashio JFM mean SST. 1984-88 mean (contours) and Can we [1984-88]-[1968-72] consider them (shades) as one unified front? Extension(KOE) Possible importance of region ocean-to-atmosphere is one of the centers feedback of in action the KOE of Pacific region for Decadal the Pacific Variability Decadal Variability has been debated. In these previous studies, the KOE region is How are the SSTA in considered the as one unified frontal region. But, KOE region caused? there are at least two distinct frontal regions. Then, in this study, we examine oceanic variations While SSTAs in are the forced KOE Monthly by region atmospheric mean to see SST ocean s in variability January roles 2003 in in the the large parts of the North midlatitude Pacific, air-sea in the KOE interaction. region, it has been AMSR-E suggested that If oceanic SSTAs can dynamics be induced induce by SSTAs ocean as dynamics: in the eastern 1. Enhanced equatorial Kuroshio Pacific, current the (Latif ocean-to-atmosphere & Barnett 1994) feedback, 2. Vertical movement may be possible. of thermocline (Schneider & Miller 2001) 3. Meridional migration of the KOE fronts (Seager et al. 2001) 4. Enhanced Oyashio current (Sekine 1989)

Questions: In the KOE region, there are at least two prominent fronts, the Kuroshio Extension front and the subarctic (Oyashio Extension) front. How each of these fronts changes in associated with the large scale decadal SSTAs in the North Pacific? Are variations of these frontal regions coherent? Can we consider these fronts as an unified oceanic front as in the previous studies? Analyze output of an eddy-resolving OGCM that can represent the two fronts separately.

Model: OFES (The Ocean model For the Earth Simulator) Based on MOM3 (GFDL/NOAA), significantly modified on the parallelization procedures. Solve primitive equations in spherical coordinate. Boussinesq and hydrostatic approximations are adopted. Bi-harmonic horizontal mixing & the KPP vertical mixing scheme Near-global model basin: 75S-75N, 0-360E. 0.1 degree horizontal resolution, 54 vertical levels (max 6065m) Surface heat fluxes are given by the bulk formula. Fresh water flux & SSS restoring to monthly climatology. NCEP reanalysis fields are used for wind stress and all atmospheric fields for the fluxes. After 50-year spin-up integration by monthly climatology fields, a hindcast integration for 1950-2005 with daily mean fields.

The two fronts in the KOE region Monthly mean SST in Jan. 2003 AMSR-E OFES Two strong SST fronts, the Kuroshio Extension (KE) front and the subarctic (Oyashio Extension) front, are represented separately in the OFES simulation as in the satellite observation. we can see an individual variability of the each front in the KOE region.

Meridional temperature gradients in climatology JFM 145-160E mean latitude-depth sections of T climatology OFES (1950-2003 mean) Observation: WOA2001 0 300 600 25N 35N 45N Stronger meridional temperature gradient is found in the surface (subsurface) layer in the subarctic (KE) front. This structure is also found in the observed field.

Decadal variability in the KOE region 5-year running mean temperature in the KOE region (140-170E, 35-40N mean). Surface and subsurface decadal temperature variabilities in the KOE region are represented well. There is some negative trend in the OFES. Examine decadal variability as [1984-88]-[1968-72]. 1.0 0.0-1.0 OFES FRS-COADS White (1995) 1950 1960 1970 1980 1990 2000 OFES SST, 120m, 200m, 300m, 400m White (1995) temperature SST, 120m, 200m, 300m, 400m

Decadal SSTAs JFM mean SST in 1984-88 (contour) and decadal SST difference [1984-88 mean] [1968-72 mean] (color). Large scale distributions are well represented. 50N 40N FRS- COADS OFES 30N 120E 180 120W SSTAs in the OFES are most prominent along the SST fronts, especially along the subarctic front, suggesting importance of meridional migration of the fronts.

50N 40N Changes in SST gradient Much stronger SST gradient in the subarctic front than the KE front. 30N Contour: 1984-88 120E 180 120W Both of the two fronts migrate southward in the cool period. Contour: 1968-72 Shades: 1984-88 Larger SSTAs along the subarctic front. JFM mean SST gradient in 1984-88 (top, shades in bottom) and 1968-72 (bottom). How are subsurface changes?

T, S anomalies on meridional sections 0 Temperature Salinity 00 00 1968-72 T, S anomalies extend vertically associated with meridional migration of the fronts. 1976-80 1984-88 25N 35N 45N Max. of anomaly is found in the surface (subsurf.) layer in the subarctic (KE) frontal region. JFM 145-160E mean latitude-depth sections of T, and S in 1968-72 (top), 1976-80 (middle), and 1984-88 (bottom). Nonaka et al. (2006)

Surface heat flux anomalies Decadal difference in JFM mean upward sea surface heat flux [1984-88 mean] [1968-72 mean]. In the KOE region, cool SSTAs are associated with downward sea surface heat flux anomalies. dumping the cool SSTAs Atmospheric thermal forcing does NOT cause the SSTAs. Cool SSTAs induce downward surface heat flux anomalies.

Temporal developments 43N 36N 2000 1980 1960 140E 180 At the KE front, westward propagating Rossby waves forced by Ekman pumping anomalies induce the changes. Taguchi et al. (2007) further show that At thearesubarctic frontal scale changes associated with large scalefront, changes that induced there seem to by propagation of wind-induced Rossby be also eastward waves. propagating signals, and meet those from the eastern basin around 170E. 140W Longitude-time sections of JFM SSH (color) and Ekman pumping (contour). 5-year running-mean is applied and trends are removed. Nonaka et al. (2006)

Lagged correlation between Oyashio and SST JFM [40-45N, 143-151E] mean northward velocity 3-yr-lead 1-yr-lag simultaneous Lagged correlation (green contours) and regression (shades) of SST and 100-m depth area-mean Oyashio velocity based on Jan.-Mar (black curve of left-top panel). OFES hindcast fields. Solid contours show long-year mean fields. Oyashio enhancement 2-yr-lead 1-yr-lead 2-yr-lag 3-yr-lag Cooling off northern Japan Cooling propagates/extends eastward along the subarctic front

Temporal developments 43N 36N 2000 1980 1960 At the KE front, westward propagating Rossby waves forced by Ekman pumping anomalies induce the changes. At the subarctic front, there seem to be also eastward propagating signals, and meet those from the eastern basinappear aroundearlier 170E. Signals at the subarctic front. 140E 180 140W Are the variations coherent in Longitude-time sections of JFM SSH (color) and Ekman pumping two are frontal regions? (contour). 5-year running-mean is appliedthese and trends removed.

Are changes in the two frontal regions synchronizing? Correlations (JMA-SST) Simultaneous correlation of decadal JFM-mean SSTA with area-mean SSTA in the subarctic frontal region based on an observational data, JMA-SST. Mean SST The SST variations in the SAF region do not highly correlate with those in the KE frontal region. Their variations need to be considered separately. Kuroshio Extension front

Summary Decadal SSTAs are well represented in the OFES, and they have cores along the SST fronts, especially along the subarctic front. Decadal SSTAs in the KOE region are mainly induced by meridional migration of the fronts. T/S anomalies extend vertically and vertical maximum is found in the surface (subsurface) layer in the subarctic (KE) frontal region. Cool SSTAs are associated with downward SHF anomalies, suggesting ocean-to-atmosphere feedback. Westward propagating Rossby waves are found at the fronts. KE frontal region: Rossby wave propagation and associated frontal scale variations induce the decadal variations (c.f. Taguchi et al. 2007, JC). At the subarctic front, eastward propagations are also found. advection of the signals by eastward current may be important Variability in the two fronts are not highly correlate. Higher resolution GCMs are necessary to represent them separately.

Changes in SSH gradient 50N 40N 30N Contour: 1984-88 120E 180 120W Contour: 1968-72 Shades: 1984-88 Much stronger SST gradient in the KE front than the subarctic front. Both of the two fronts migrate southward in the cool period. The KE front is intensified in the cold period. JFM mean SSH gradient in 1984-88 (top, shades in bottom) and 1968-72 (bottom). How the subsurface fields change?

Impact of Ekman advections 50N Influence of changes in Ekman advection on decadal JFM SST difference between 1984-88 and 1968-72 in the OFES. 40N 30N (1968-72) (1984-88) 120E 180 120W Impacts of changes in the Ekman advection induced by wind anomalies on the SSTAs are less than 1.5C, inducing only a part of the SSTAs.

Intensified KE front 0 00 00 OFES Observation: White (1995) Shade: dt/dy Shade: dt/dy 1984-88 1968-72 35N 45N JFM 145-160E mean latitude-depth sections of T in 1984-88 (top), and 1968-72 (middle) in the OFES (left) and observed data (right). Shades are meridional gradient of T. (Bottom) Shades: T difference from 1968-72 to 1984-88 In both the OFES and observations, the KE front is intensified in the cool period (top). Upward displacement of the thermocline to the north of the KE front, and cool anomalies there. While the KE current is also intensified, cool anomalies are found.

Interannual variability in the area-mean Oyashio JFM area mean northward velocity in [40-45N, 143-151E] Vertical mean velocity (STD=0.43 cm/s) 100m depth velocity (STD=1.12 cm/s) [100m]-[vertical_mean] Oyashio is enhanced in winter, consistent with observations Use mean velocity in the large area as an index to exclude influence of eddies. Examine lagged correlations between the 100-m depth Oyashio index and SST field and so on to see influences of the Oyashio variations on the SAF region.

Lagged correlation between isopycnal PV and Oyashio variations simultaneous 3-yr-lead 2-yr-lead 1-yr-lead 1-yr-lag 2-yr-lag 3-yr-lag Lagged correlation (contours) and regression (shades) of PV on σ =27.0 and 100-m depth area-mean Oyashio velocity based on Jan.-Mar. OFES hindcast fields. Top-left panel shows long-year mean PV field on the surface. Low PV waters extend eastward along the subarctic front after Oyashio enhancement. Advection may induce changes in the frontal region. PV= v u 1 ρ (f + ) x y ρ0 z

Lagged correlation between Oyashio and SSH 3-yr-lead 1-yr-lag simultaneous Lagged correlation (dashed contours) and regression (shades) of SST and 100-m depth area-mean Oyashio velocity based on Jan.-Mar. OFES hindcast fields. Solid contours show long-year mean fields. Oyashio enhancement 2-yr-lead 1-yr-lead 2-yr-lag 3-yr-lag Negative anomalies near northern Japan Negative anomalies propagate/extend eastward along the subarctic front SSTAs can be associated with changes in the subsurface ocean.

Surface currents Oyashio, Oyashio Extension, Kuroshio Extension currents are enhanced in 1984-88, cool period Enhanced southward cool water transport may induce cool SSTAs. JFM mean sea surface currents for 1984-88 (top) and for 1968-72 (bottom). Shadings show speeds.

PDO in the OFES OFES COADS Decadal variability is represented well in the OFES hindcast run, at least at the sea surface.

PADO in OFES and observations

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