1 |
<ul><li> |
2 |
M. Balmaseda, M., et al., 2015: The ocean reanalyses intercomparison project |
3 |
(ora-ip). J. Oper. Oceanogr., 8 (sup1), s80-s97. |
4 |
</li></ul> |
5 |
|
6 |
<ul><li> |
7 |
H. Brix, D. Menemenlis, C. Hill, S. Dutkiewicz, O. Jahn, D. Wang, |
8 |
K. Bowman, and H. Zhang, 2015: |
9 |
<a href="http://ecco2.org/manuscripts/2015/Brix2015.pdf"> Using |
10 |
Green's Functions to initialize and adjust a global, eddying ocean |
11 |
biogeochemistry general circulation model.</a> Ocean Model., 95, 1-14. |
12 |
</li></ul> |
13 |
|
14 |
<ul><li> M. Buckley, R. Ponte, G. Forget, and P. Heimbach, 2015: Determining |
15 |
the origins of advective heat transport variability in the North Atlantic. J. |
16 |
Clim., 18, 3943-3956. |
17 |
</li></ul> |
18 |
|
19 |
<ul><li> |
20 |
R. Chen, G. Flierl, and C. Wunsch, 2015: Quantifying and Interpreting |
21 |
Striations in a Subtropical Gyre: A Spectral Perspective. J. Phys. Oceanogr., |
22 |
45, 387-406. |
23 |
</li></ul> |
24 |
|
25 |
<ul><li> |
26 |
P. Duarte, P. Assmy, H. Hop, G. Spreen, S. Gerland, and S. Hudson, |
27 |
2015: <a href="http://ecco2.org/manuscripts/2015/Duarte2015.pdf"> The |
28 |
importance of vertical resolution in sea ice algae production models.</a> |
29 |
J. Mar. Syst., 145, 69-90. |
30 |
</li></ul> |
31 |
|
32 |
<ul><li> |
33 |
I. Fenty, D. Menemenlis, and H. Zhang, 2015: |
34 |
<a href="http://ecco2.org/manuscripts/2015/Fenty2015.pdf"> |
35 |
Global Coupled Sea Ice-Ocean State Estimation.</a> Clim. Dyn., |
36 |
doi:10.1007/s00382-015-2796-6 |
37 |
</li></ul> |
38 |
|
39 |
<ul><li> |
40 |
M.M. Flexas, M. Schodlok, L. Padman, D. Menemenlis, and A. Orsi, 2015: |
41 |
<a href="http://ecco2.org/manuscripts/2015/Flexas2015.pdf"> |
42 |
Role of tides on the formation of the Antarctic Slope Front at the |
43 |
Weddell-Scotia Confluence.</a> J. Geophys. Res., 120, 3658-3680. |
44 |
</li></ul> |
45 |
|
46 |
<ul><li> |
47 |
G. Forget, D. Ferreira, and X. Liang, 2015: On the observability of |
48 |
turbulent transport rates by argo: supporting evidence from an |
49 |
inversion experiment. Ocean Science, 11, 839-853. |
50 |
</li></ul> |
51 |
|
52 |
<ul><li> |
53 |
G. Forget and R.M. Ponte, 2015: |
54 |
<a href="http://www.sciencedirect.com/science/article/pii/S0079661115001354"> |
55 |
The partition of regional sea level variability.</a> Prog. Oceanogr., |
56 |
137, 173-195. |
57 |
</ul></li> |
58 |
|
59 |
<ul><li> |
60 |
G. Forget, J.M. Campin, P. Heimbach, C.N. Hill, R.M. Ponte, and |
61 |
C. Wunsch, 2015: |
62 |
<a href="http://www.geosci-model-dev.net/8/3071/2015/gmd-8-3071-2015.pdf"> |
63 |
ECCO version 4: an integrated framework for non-linear inverse |
64 |
modeling and global ocean state estimation.</a> Geosci. Model Dev., 8, |
65 |
3071-3104. |
66 |
</ul></li> |
67 |
|
68 |
<ul><li> |
69 |
The ECCO Consortium (G. Forget, I. Fukumori, P. Heimbach, T. Lee, D. Menemenlis, and R.M. Ponte), 2015: |
70 |
<a href="http://ecco2.org/manuscripts/2015/ECCO_CLIVAR.pdf"> |
71 |
Estimating the Circulation and Climate of the Ocean (ECCO): Advancing |
72 |
CLIVAR Science.</a> CLIVAR Exchanges, 67, 41-45. |
73 |
</ul></li> |
74 |
|
75 |
<ul><li> |
76 |
I. Fukumori, 2015: Combining models and data in large-scale oceanography: |
77 |
Examples from the Consortium for Estimating the Circulation and Climate of the |
78 |
Ocean (ECCO). Advanced Data Assimilation for Geosciences: Lecture Notes of the |
79 |
Les Houches School of Physics: Special Issue, June 2012. |
80 |
</li></ul> |
81 |
|
82 |
<ul><li> |
83 |
I. Fukumori, O. Wang, W. Llovel, I. Fenty and G. Forget, 2015: A near-uniform |
84 |
fluctuation of ocean bottom pressure and sea level across the deep ocean |
85 |
basins of the Arctic Ocean and the Nordic Seas. Prog. Oceanogr., 134, 152-172. |
86 |
</li></ul> |
87 |
|
88 |
<ul><li> |
89 |
D. Halkides, D. Waliser, T. Lee, D. Menemenlis, and B. Guan, |
90 |
2015: <a href="http://ecco2.org/manuscripts/2015/Halkides2015.pdf"> |
91 |
Quantifying the processes controlling intraseasonal mixed-layer temperature |
92 |
variability in the tropical Indian Ocean.</a> J. Geophys. Res., 120, 692-715. |
93 |
</li></ul> |
94 |
|
95 |
<ul><li> |
96 |
D. Halpern, D. Menemenlis, and X. Wang, |
97 |
2015: <a href="http://ecco2.org/manuscripts/2015/Halpern2015.pdf"> |
98 |
Impact of data assimilation on ECCO2 Equatorial Undercurrent and North |
99 |
Equatorial Countercurrent in the Pacific Ocean.</a> J. Atmos. Ocean |
100 |
Tech., 32, 131-143. |
101 |
</li></ul> |
102 |
|
103 |
<ul><li> |
104 |
P. Heimbach, 2015: Application of derivative code in climate modeling. |
105 |
in: N. Gauger, M. Giles, M. Gunzburger, and U. Naumann (eds.): |
106 |
Adjoint Methods in Computational Science, Engineering, and Finance. |
107 |
Dagstuhl Reports, 4, 14-16. |
108 |
</li></ul> |
109 |
|
110 |
<ul><li> |
111 |
V. Le Fouest, M. Manizza, B. Tremblay, and M. Babin, 2015: |
112 |
<a href="http://www.biogeosciences.net/12/3385/2015/bg-12-3385-2015.html"> |
113 |
Modeling the impact of riverine DON removal by marine bacterioplankton on |
114 |
primary production in the Arctic Ocean.</a> Biogeosciences, 12, 3385-3402. |
115 |
</li></ul> |
116 |
|
117 |
<ul><li> |
118 |
X. Liang, C. Wunsch, P. Heimbach, and G. Forget, 2015: |
119 |
Vertical redistribution of oceanic heat. J. Clim., 28, 3821-3833. |
120 |
</ul></li> |
121 |
|
122 |
<ul><li> |
123 |
K. McCaffrey, B. Fox-Kemper, and G. Forget, 2015: Estimates of Ocean |
124 |
Macro-turbulence: Structure Function and Spectral Slope from Argo Profiling |
125 |
Floats. J. Phys. Oceanogr., 45, 1773-1793. |
126 |
</ul></li> |
127 |
|
128 |
<ul><li> |
129 |
L. Ott, S. Pawson, G. Collatz, W. Gregg, D. Menemenlis, H. Brix, C. Rousseaux, |
130 |
K. Bowman, J. Liu, A. Eldering, M. Gunson, and S. Kawa, |
131 |
2015: <a href="http://ecco2.org/manuscripts/2015/Ott2015.pdf"> Assessing the |
132 |
magnitude of CO2 flux uncertainty in atmospheric CO2 records using products |
133 |
from NASA's Carbon Monitoring Flux Pilot Project.</a> J. Geophys. Res., 120, |
134 |
734-765. |
135 |
</li></ul> |
136 |
|
137 |
<ul><li> |
138 |
C. Piecuch, 2015: Bottom-pressure signature of annual baroclinic |
139 |
Rossby waves in the northeast tropical Pacific Ocean. J. Geophys. |
140 |
Res., 120, 2449-2459. |
141 |
</li></ul> |
142 |
|
143 |
<ul><li> |
144 |
C. Piecuch, I. Fukumori, R. Ponte, and O. Wang, 2015: Vertical |
145 |
structure of ocean pressure fluctuations with application to |
146 |
satellite-gravimetric observations. J. Atmos. Oce. Tech., 32, 603-613. |
147 |
</li></ul> |
148 |
|
149 |
<ul><li> |
150 |
C. Piecuch, P. Heimbach, R.M. Ponte, and G. Forget, 2015: Sensitivity |
151 |
of contemporary sea level trends in a global ocean state estimate to effects |
152 |
of geothermal fluxes, Ocean Model., 96, 214-220. |
153 |
</li></ul> |
154 |
|
155 |
<ul><li> |
156 |
K. J. Quinn, R. M. Ponte, and M. E. Tamisiea, 2015: Impact of self-attraction |
157 |
and loading on Earth rotation. J. Geophys. Res., 120, 4510–4521. |
158 |
</li></ul> |
159 |
|
160 |
<ul><li> |
161 |
A. Storto, and 36 others, 2015: Steric sea level variability (1993-2010) in an |
162 |
ensemble of ocean reanalyses and objective analyses. Clim. Dyn., |
163 |
doi:10.1007/s00382-015-2554-9 |
164 |
</li></ul> |
165 |
|
166 |
<ul><li> |
167 |
Toyoda, T., and 32 others, 2015: Interannual-decadal variability of wintertime |
168 |
mixed layer depths in the north pacific detected by an ensemble of ocean |
169 |
syntheses. Clim. Dyn., doi:10.1007/s00382-015-2762-3 |
170 |
</li></ul> |
171 |
|
172 |
<ul><li> |
173 |
T. Toyoda, and 32 others, 2015: Intercomparison and validation of the |
174 |
mixed layer depth fields of global ocean syntheses. Clim. Dyn., |
175 |
doi:10.1007/s00382-015-2637-7 |
176 |
</li></ul> |
177 |
|
178 |
<ul><li> |
179 |
T. Van der Stocken, 2015: |
180 |
<a href="http://ecco2.org/manuscripts/2015/Stocken2015.pdf"> Biological and |
181 |
environmental drivers of mangrove propagule dispersal: A field and modeling |
182 |
approach.</a> Ph.D. Thesis, Vrije Universiteit Brussel and the Universite |
183 |
Libre de Bruxelles. |
184 |
</li></ul> |
185 |
|
186 |
<ul><li> |
187 |
E. Villar, G. Farrant, M. Follows, et al, 2015, Environmental characteristics |
188 |
of Agulhas rings affect interocean plankton transport, Science, Vol. 348, |
189 |
6237. |
190 |
</li></ul> |
191 |
|
192 |
<ul><li> |
193 |
N. Vinogradova, R. Ponte, K. Quinn, M. Tamisiea, J.M. Campin, and J. Davis, |
194 |
2015: Dynamic Adjustment of the Ocean Circulation to Self-Attraction and |
195 |
Loading Effects. J. Phys. Oceanogr., 45, 678-689. |
196 |
</li></ul> |
197 |
|
198 |
<ul><li> |
199 |
X. Wang, L. Zhao, Z. Li, and D. Menemenlis, 2015: |
200 |
<a href="http://ecco2.org/manuscripts/2015/Wang2015.pdf"> |
201 |
Regional ocean forecasting systems and their applications: Design |
202 |
consideration of such a system for the South China Sea.</a> |
203 |
Aquat. Ecosyst. Health Manag., 18, 443-453. |
204 |
</li></ul> |
205 |
|
206 |
<ul><li> |
207 |
J. Whitefield, P. Winsor, J. McClelland, and D. Menemenlis, |
208 |
2015: <a href="http://ecco2.org/manuscripts/2015/Whitefield2015.pdf"> A new |
209 |
river discharge and river temperature climatology data set for the |
210 |
pan-Arctic region.</a> Ocean Model., 88, 1-15. |
211 |
</li></ul> |
212 |
|
213 |
<ul><li> |
214 |
C. Yan, J. Zhu, and J. Xie, 2015: An ocean data assimilation system in the |
215 |
Indian Ocean and west Pacific Ocean. Adv. Atmos. Sci., 32, |
216 |
1460-1472. |
217 |
</li></ul> |
218 |
|
219 |
<ul><li> |
220 |
V. Zemskova, B. White, and A. Scotti, 2015: Available potential energy |
221 |
and the general circulation: Partitioning wind, buoyancy forcing, and |
222 |
irreversible mixing. J. Phys. Oceanogr., 45, 1510-1531. |
223 |
</li></ul> |
224 |
|
225 |
<ul><li> |
226 |
Y. Zhang, D. Jacob, S. Dutkiewicz, H. Amos, M. Long, and E. Sunderland, 2015: |
227 |
Biogeochemical drivers of the fate of riverine mercury discharged to the |
228 |
global and Arctic oceans. Global Biogeochem. Cycles, 29, 854-864. |
229 |
</li></ul> |