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2  J. Campin, C. Hill, H. Jones, and J. Marshall, 2011:  J. Campin, C. Hill, H. Jones, and J. Marshall, 2011:
3  <a href="http://www-paoc.mit.edu/paoc/papers/superparam.pdf">  <a href="http://www-paoc.mit.edu/paoc/papers/superparam.pdf">
4  Superparameterization in ocean modeling: application to deep  Superparameterization in ocean modeling: application to deep
5  convection.</a> Ocean Modeling, submitted.  convection.</a> Ocean Modeling, in press.
6    </li></ul>
7    
8    <ul><li>
9    A. Condron and P. Winsor, 2011:
10    <a href="http://ecco2.org/manuscripts/2011/CondronWinsor2011.pdf">
11    A subtropical fate awaited freshwater discharged from glacial Lake
12    Agassiz.</a> Geophys. Res. Lett., 38, L03705.
13  </li></ul>  </li></ul>
14    
15  <ul><li>  <ul><li>
16  X. Davis, L. Rothstein, W. Dewar, and D. Menemenlis, 2011:  X. Davis, L. Rothstein, W. Dewar, and D. Menemenlis, 2011:
17  <a href="http://ecco2.org/manuscripts/2010/DavisJcli10.pdf">  <a href="http://ecco2.org/manuscripts/2011/DavisJcli10.pdf">
18  Numerical investigations of seasonal and interannual variability of  Numerical investigations of seasonal and interannual variability of
19  North Pacific Subtropical Mode Water and its implications for Pacific  North Pacific Subtropical Mode Water and its implications for Pacific
20  climate variability.</a> J. Clim., in press.  climate variability.</a> J. Clim., 24, 2648-2665.
21  </li></ul>  </li></ul>
22    
23  <ul><li>  <ul><li>
24  E. Hill, D. Enderton, P. Heimbach, and C. Hill, 2011: SPGrid: A  S. Dutkiewicz, 2011:
25  numerical grid generation program for domain decomposed geophysical  <a href="http://ecco2.org/manuscripts/2011/dutkiewicz_variations.pdf">
26  fluid dynamics models. Mon. Weather Rev., submitted.  Driving ecosystem and biogeochemical models with optimal state
27    estimates of the ocean circulation.</a> U.S. CLIVAR Variations, 9, 1.
28  </li></ul>  </li></ul>
29    
30  <ul><li>  <ul><li>
31  M. Manizza, M. Follows, S. Dutkiewicz, D. Menemenlis, J. McClelland,  G. Forget, G. Maze, M. Buckley, and J. Marshall, 2011:
32  C. Hill1, B. Peterson, R. Key, 2011:  Estimated Seasonal Cycle of North Atlantic Eighteen Degree Water Volume.
33  <a href="http://ecco2.org/manuscripts/2010/ManizzaJGR2010.pdf">  J. Phys. Oceanogr., 41(2), 269-286, doi:10.1175/2010JPO4257.1
 Modeling the Arctic Ocean carbon cycle and its sensitivity to the  
 influence of the riverine dissolved organic carbon.</a>  
 J. Geophys. Res., submitted.  
34  </li></ul>  </li></ul>
35    
36  <ul><li>  <ul><li>
37  G. Maze, G. Forget, M. Buckley and J. Marshall, 2011: Using  H. Gennerich and H. Villinger, 2011:
38  transformation and formation maps to study water mass transformation:  <a href="http://ecco2.org/manuscripts/2011/Gennerich_2011.pdf">
39  a case study of North Atlantic Eighteen Degree water. J. Phys.  Deciphering the ocean bottom pressure variation in the Logatchev
40  Oceanogr, submitted.  hydrothermal field at the eastern flank of the Mid-Atlantic Ridge.</a>
41    Geochemistry Geophysics Geosystems, 12, doi:10.1029/2010GC003441.
42    </li></ul>
43    
44    <ul><li>
45    P. Heimbach, C. Wunsch, R. Ponte, G. Forget, C. Hill, and J. Utke, 2011:
46    Timescales and Regions of the Sensitivity of Atlantic Meridional Volume and
47    Heat Transport Magnitudes: Toward Observing System Design. Deep Sea Res. II
48    (Topical issue on "Climate and the AMOC"), 58(17-18), 1858-1879, doi:10.1016/j.dsr2.2010.10.065.
49    </li></ul>
50    
51    <ul><li>
52    M. Manizza, M. Follows, S. Dutkiewicz, D. Menemenlis, J. McClelland,
53    C. Hill, B. Peterson, R. Key, 2011:
54    <a href="http://ecco2.org/manuscripts/2011/Manizza2011.pdf">
55    A model of the Arctic Ocean carbon cycle.</a>
56    J. Geophys. Res., 116, C12020, doi:10.1029/2011JC006998.
57  </li></ul>  </li></ul>
58    
59  <ul><li>  <ul><li>
60  A. Nguyen, D. Menemenlis, and R. Kwok, 2011:  A. Nguyen, D. Menemenlis, and R. Kwok, 2011:
61  <a href="http://ecco2.org/manuscripts/2010/NguyenJGR10.pdf">  <a href="http://ecco2.org/manuscripts/2011/NguyenJGR2011.pdf">
62  Arctic ice-ocean simulation with optimized model parameters: approach  Arctic ice-ocean simulation with optimized model parameters: approach
63  and assessment.</a>  J. Geophys. Res., submitted.  and assessment.</a>  J. Geophys. Res., 116, C04025,
64    doi:10.1029/2010JC006573
65    </li></ul>
66    
67    <ul><li>
68    Piecuch, C. G., and R. M. Ponte, 2011: Mechanisms of interannual steric sea level variability, Geophys. Res. Lett., 38, L15605, doi:10.1029/2011GL048440.
69    </li></ul>
70    
71    <ul><li>
72    Rampal, P., J. Weiss, C. Dubois & J.-M. Campin 2011: IPCC climate models do not capture Arctic sea ice drift acceleration: Consequences in terms of projected sea ice thinning and decline, J. Geophys. Res., vol. 116, C00D07, doi:10.1029/2011JC007110.
73    </li></ul>
74    
75    <ul><li>
76    Roquet, F., C. Wunsch, and G. Madec, 2011: On the patterns of wind-power input to the ocean circulation. J. Phys. Oceanogr., 41, 2328-2342, 10.1175/JPO-D-11-024.1.
77    </ul></li>
78    
79    <ul><li>
80    G. Spreen, R. Kwok, and D. Menemenlis, 2011:
81    <a href="http://ecco2.org/manuscripts/2011/Spreen2011.pdf">
82    Trends in Arctic sea ice drift and role of wind forcing:
83    1992-2009.</a>  Geophys. Res. Lett., 38, L19501.
84    </li></ul>
85    
86    <ul><li>
87    S. Tank, M. Manizza, R. Holmes, J. McClelland, and B. Peterson, 2011:
88    <a href="http://ecco2.org/manuscripts/2011/Tank2011.pdf">
89    The processing and impact of dissolved riverine nitrogen in the Arctic
90    Ocean.</a> Estuaries and Coasts, doi:10.1007/s12237-011-9417-3.
91  </li></ul>  </li></ul>
92    
93  <ul><li>  <ul><li>
94  R. Tulloch, J. Marshall, C. Hill, and K. Smith, 2011:  R. Tulloch, J. Marshall, C. Hill, and K. Smith, 2011:
95  <a href="http://ocean.mit.edu/~tulloch/Publications/tulloch_etaljpo10.pdf">  <a href="http://ocean.mit.edu/~tulloch/Publications/tulloch_etaljpo10.pdf">
96  Scales, growth rates and spectral fluxes of baroclinic instability in  Scales, growth rates and spectral fluxes of baroclinic instability in
97  the ocean.</a> J. Phys. Oceanogr., submitted.  the ocean.</a> J. Phys. Oceanogr., in press.
98  </li></ul>  </li></ul>
99    
100  <ul><li>  <ul><li>
101  C. Ubelmann and L. Fu, 2011:  C. Ubelmann and L. Fu, 2011:
102  <a href="http://ecco2.org/manuscripts/2011/UbelmannFu2011.pdf">  <a href="http://ecco2.org/manuscripts/2011/UbelmannFu2011a.pdf">
103  Vorticity structures in the tropical Pacific from a numerical simulation.</a>  Vorticity structures in the Tropical Pacific from a numerical simulation.</a>
104  Geophys. J. Phys. Oceanogr., submitted.  J. Phys. Oceanogr., 41, 1455.
105  </li></ul>  </li></ul>
106    
107  <ul><li>  <ul><li>
108  N. Vinogradova, R. Ponte, M. Tamisiea, J. Davis, and  C. Ubelmann and L. Fu, 2011:
109  E. Hill, 2011: Effects of self-attraction and loading on annual  <a href="http://ecco2.org/manuscripts/2011/UbelmannFu2011b.pdf">
110  variations of ocean bottom pressure. J. Geophys. Res., submitted.  Cyclonic eddies formed at the Pacific tropical instability wave fronts.</a>
111    J. Geophys. Res., 116, C12021.
112  </li></ul>  </li></ul>
113    
114  <ul><li>  <ul><li>
115  N. Vinogradova, R. Ponte, and P. Heimbach, 2011: Dynamics and forcing of sea  D. Volkov and L. Fu, 2011:
116  surface temperature variability on climate time scales. J. Clim., submitted.  <a href="http://ecco2.org/manuscripts/2011/VolkovFu2011.pdf">
117    Interannual variability of the Azores Current strength and eddy energy
118    in relation to atmospheric forcing.</a> J. Geophys. Res., 116, C11011.
119  </li></ul>  </li></ul>
120    
121  <ul><li>  <ul><li>
122  D. Volkov and L. Fu, 2011: Mechanism for the interannual variability of the  Wunsch, C., 2011:
123  Azores Current eddy energy. Geophys. Res. Let., submitted.  The decadal mean circulation and Sverdrup balance.
124    J. Marine Res., 69, 417-434.
125  </li></ul>  </li></ul>
126    
127  <ul><li>  <ul><li>
128  L. Zanna, P. Heimbach, A. Moore and E. Tziperman, 2011. Analysis of the  Y. Xu and L. Fu, 2011:
129  predictability and variability of the Atlantic ocean in response to optimal  <a href="http://ecco2.org/manuscripts/2011/XuFu2011.pdf">
130  surface excitation.  Quart. J. Roy. Met. Soc., submitted.  Global variability of the wavenumber spectrum of
131    oceanic mesoscale turbulence.</a> J. Phys. Oceanogr., 41, 802-809.
132  </li></ul>  </li></ul>
133    
134    <ul><li>
135    L. Zanna, P. Heimbach, A. Moore, and E. Tziperman, 2011: Optimal
136    excitation of interannual Atlantic meridional overturning circulation
137    variability. J. Climate, 24(2), 413-423, doi:10.1175/2010JCLI3610.1.
138    </li></ul>
139    
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