1. Mesoscale eddies and shelf-basin exchange in the western Arctic Ocean
AOMIP Workshop WHOI
Oct. 22, 2009
Mesoscale eddies and shelf-basin exchange
in the western Arctic Ocean
Eiji Watanabe
International Arctic Research Center, Univ. of Alaska Fairbanks

2. Pacific Water Transport
Introduction
Pacific Water Transport
Pacific water is predominant sources of heat, freshwater and nutrients
Mesoscale Eddies
Spall et al. (2008)

3. Our Interest Introduction
When and Where are Beaufort shelfbreak eddies generated ?
What controls generation period and place ?
Are these elements interannually varing ?
Satellite
Model

4. Beaufort Shelfbreak Eddies
Result
Beaufort Shelfbreak Eddies
Numerous eddy-like warm water cores appear along Beaufort shelf break
MODIS 8-day-mean level-3 sea surface temperature [degC]
Sep. 9, 2003
70 km
Sea Ice
Eddy-like warm cores
Alaska
Sep. 6-13, 2003

5. Eddy Pair from Global Imager (GLI)
Result
Eddy Pair from Global Imager (GLI)
GLI Level 1B radiance (460, 545, 660 nm)
Eddy Pair ?
Sea Ice
Beaufort
shelfbreak
Alaska
Coastal
Current
Ocean
Pt. Barrow
Cloud
Land
Jul. 8, 2003

6. Model Description Method
Coupled sea ice-ocean model : COCO (developed at Univ. of Tokyo)
Sea ice part
- momentum equation based on Mellor and Kantha (1989)
- 0-layer thermodynamics (Semtner, 1976) / two thickness category
- EVP rheology (Hunke and Duckowicz, 1997)
Ocean part ：COCO 3.4 (CCSR ocean component model version 3.4)
- free surface general circulation model (OGCM)
- UTOPIA/QUICKEST for trace advection (Leonard et al., 1994)
- turbulent closure scheme (Noh and Kim, 1999)
- Smagorinsky’s biharmonic viscosity (Griffies and Hallberg, 2000)
- enstrophy preserving scheme (Ishizaki and Motoi, 1999)
Model parameter (background value [m2/s] )
- horizontal viscosity : 5.0×10, horizontal diffusivity : 1.0
- vertical viscosity : 1.0×10-4, vertical diffusivity : (0.1 ~ 3.0)×10-4

7. Experimental Design Method
Watanabe and Hasumi
(2009, JPO)
Model domain ： Chukchi Sea and southern Canada Basin
- horizontal resolution : about 2.5 km (eddies are explicitly resolved)
- vertical level :
(25L) [m]
Boundary condition
- NCEP/NCAR reanalysis daily data
　(wind, temperature, radiation etc.)
- lateral : sponge for ocean
　 open for sea ice
- Pacific water inflow at Bering Strait
Model bathymetry [m]
Canada Basin
Chukchi
Sea
Alaska
Barrow
Canyon
Chukchi Plateau
Bering Strait
Initial condition
- T, S : PHC in March
- ocean circulation : static
- sea ice : derived from NIC
Integrated for 1 year from Mar to Feb

8. Sea Ice and Sea Surface Temperature
Result
Sea Ice and Sea Surface Temperature
Sea ice area [ - ] and sea surface temperature [degC]
AMSR-E & MODIS
Sep. 6-13, 2003
CTL
Sep. 22
Barrow
Canyon
Alaska
Bering St.
Warm water cores
Sea Ice
The model reproduces warm water cores along the Beaufort shelf break

9. Pacific Water Pathway Result Eddy-induced transport Alaska Oct. 10 CTL
Pacific water content [m]
Canada
Basin
Eddy-induced
transport
Herald
Canyon
Barrow
Canyon
Alaska
Oct. 10
CTL
Bering St.
Eddy-induced transport of Pacific water seems to be dominant

10. Beaufort Shelfbreak Eddies
Result
Beaufort Shelfbreak Eddies
Ocean velocity [cm s-1] and relative vorticity [s-1] (30 m depth)
50 km
Barrow Canyon
Oct. 10
CTL

11. Beaufort Shelfbreak Eddies
Result
Beaufort Shelfbreak Eddies
Ocean velocity [cm s-1] and relative vorticity [s-1] (30 m depth)
ED5
ED4
ED2
ED3
ED1
50 km
Barrow Canyon Jet
Jul. 22
CTL

12. Beaufort Shelfbreak Eddies
Result
Beaufort Shelfbreak Eddies
Ocean velocity [cm s-1] and relative vorticity [s-1] (30 m depth)
ED5
ED6
ED4
ED3
ED1
ED2
50 km
Barrow Canyon Jet
Aug. 6
CTL

13. Beaufort Shelfbreak Eddies
Result
Beaufort Shelfbreak Eddies
Ocean velocity [cm s-1] and relative vorticity [s-1] (30 m depth)
ED4
ED5
ED1
ED3
ED12
ED7
ED8
ED11
ED9
ED10
50 km
Barrow Canyon Jet
Sep. 15
CTL

14. Variation of Relative Vorticity
Result
Variation of Relative Vorticity
Time series of relative vorticity field [s-1] (30 m depth)
Continuous
Two event
Oct
Type I
Type III
ED8
Sep
ED9
ED11
ED12
ED13
ED7
Type II
ED6
Aug
ED2
ED3
ED4
ED5
Jul
ED1
Barrow
Canyon
Simultaneous
160W
140W

15. Type I Eddy Result Lateral shear of ocean velocity [s-1] (30 m depth)
Jet strength [m s-1]
Rossby Number > O(0.1)
ED6
ED3
ED1
ED2 24
Jet is frequently intensified
throughout summer season
Aug. 6
CTL
Continuous generation of Type I eddy

16. Background PV Condition
Result
Background PV Condition
Vertical structure of potential vorticity [109 m-1 s-1],
relative vorticity [s-1] and potential density [kg m-3]
ED3
CTL
Jul. 12
Type II
26σ
27σ
28σ
-0.1f
[m] N
ED9
Type III
CTL
Sep. 4
25σ
26σ
27σ
28σ
-0.2 f N
30 km
Generated from
shelfbreak wall at mid-depth
Generated from
PV front in surface layer

17. Beaufort Shelfbreak Jet
Result
Beaufort Shelfbreak Jet
Potential temperature [degC] and eastward velocity [cm s-1]
[m]
Type II
Type III 30 10 20
Warm jet
Cold jet 10 5
30 km
Jul. 12
Sep. 4 N N
CTL
CTL
Bottom-intensified cold jet
Surface-intensified warm jet
Shelfbreak jet is capable of producing eddies by baroclinic instability

18. Nonlinear Evolution of Coastal Current
Discuss
Nonlinear Evolution of Coastal Current
Low PV water outflow from a strait could form anti-cyclonic eddies
Kubokawa (1991)
Bussol St.
Yasuda et al. (2000)
Shimada et al. (2001)
Barrow Canyon

19. Potential Vorticity Front
Result
Potential Vorticity Front
PV time series on both sides of shelfbreak [107 m-1 s-1] (0 - 30m)
Type II
Type III
Barrow Canyon
Sep. 4
Type III eddies are generated
when the PV difference
becomes maximum
PVS << PVB
PVS >> PVB
Frontal wave influences
Type III eddy generation ?

20. Summary
Summary
Origin of Beaufort shelfbreak eddies and timing of their generation
Type II
Two event
Jul
Continuous
Jul ~ Sep
Type III
Sep
Type I
Sea Ice Cover
PV front ?
Shelfbreak Jet
Wind
Barrow
Canyon
Jet
Eddy Decay Process
Interannual Variation
Basin-scale Impact
Future Work
Coastal
Current