ecco2.org/results/mode_water_8.html

<head>
<title>Mode water formation.</title>
<link rel="shortcut icon" href="/ecco.ico" >
</head>

<h1>Studying the genesis of MODE waters with 1/8 degree lat-lon solutions.</h1>
<h4>People</h4>
<A href="mailto:gmaze@ocean.mit.edu"> Guillaume Maze</A>,<br>
<A href="mailto:jmarsh@mit.edu">John Marshall</A><br>
and <A href="mailto:cnh@mit.edu">Chris Hill</A>


<h4>Project Description</h4>
This project is examaining 1/8 degree resolution solutions from ECCO2 to help develop
and validate theoretical models of the air-sea processes that drive MODE water formation.
The project is developing high-spatial resolution and high-temporal frequency maps
of potential vorticity (PV) fields in active MODE water formation regions such as the Gulf
Stream region PV plot shown below
<br>
<A href=QisoN.video.gif><img src="QisoN.video.gif" width=600></A>
<br>
Through this work (and other complementary field and data analysis studies) a better understanding
of the covariations between air-sea surface processes and the genesis and formation
rates of important ocean interior water masses is being developed.
<h4>Status</h4>

You can read more about how the MODE water analyses are carried out and about 
their  progress at Guillaume Maze's 
<A href=http://www.mit.edu/~gmaze/index_postdoc.html> research web pages - 
(possibly the first blogger to focus on potential vorticity!)</A>
<br>

With NASA AMES we are currently performing a 2000-2005 1/8 degree integration 
with high-frequency sampling in the upper 
1000m of the regions shown by the blue rectangles in the figure below
<br>
<img src="ioregions.gif">
<br>
We are sampling both surface and interior state of the simulation at high 
(sub-daily)
frequency and at every model grid cell within the boxed regions. Additionally
full depth sections along the dotted lines are being sampled at high-frequency.

<br>

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1	bbaker	1.1	<head>
2			<title>Mode water formation.</title>
3			<link rel="shortcut icon" href="/ecco.ico" >
4			</head>
5
6			<h1>Studying the genesis of MODE waters with 1/8 degree lat-lon solutions.</h1>
7			<h4>People</h4>
8			<A href="mailto:gmaze@ocean.mit.edu"> Guillaume Maze</A>,<br>
9			<A href="mailto:jmarsh@mit.edu">John Marshall</A><br>
10			and <A href="mailto:cnh@mit.edu">Chris Hill</A>
11
12
13			<h4>Project Description</h4>
14			This project is examaining 1/8 degree resolution solutions from ECCO2 to help develop
15			and validate theoretical models of the air-sea processes that drive MODE water formation.
16			The project is developing high-spatial resolution and high-temporal frequency maps
17			of potential vorticity (PV) fields in active MODE water formation regions such as the Gulf
18			Stream region PV plot shown below
19			<br>
20			<A href=QisoN.video.gif><img src="QisoN.video.gif" width=600></A>
21			<br>
22			Through this work (and other complementary field and data analysis studies) a better understanding
23			of the covariations between air-sea surface processes and the genesis and formation
24			rates of important ocean interior water masses is being developed.
25			<h4>Status</h4>
26
27			You can read more about how the MODE water analyses are carried out and about
28			their progress at Guillaume Maze's
29			<A href=http://www.mit.edu/~gmaze/index_postdoc.html> research web pages -
30			(possibly the first blogger to focus on potential vorticity!)</A>
31			<br>
32
33			With NASA AMES we are currently performing a 2000-2005 1/8 degree integration
34			with high-frequency sampling in the upper
35			1000m of the regions shown by the blue rectangles in the figure below
36			<br>
37			<img src="ioregions.gif">
38			<br>
39			We are sampling both surface and interior state of the simulation at high
40			(sub-daily)
41			frequency and at every model grid cell within the boxed regions. Additionally
42			full depth sections along the dotted lines are being sampled at high-frequency.
43
44			<br>
45
46			<br>
47
48			<br>
49