近海海洋环境科学国家重点实验室(厦门大学）

The Xiamen Spring School on Ocean Dynamics (Xmod) aims at introducing fundamental ocean dynamics, from the basics to the research frontiers, to graduate students and early-career scientists. The topics cover a wide range of oceanic phenomena and processes. It has a specific theme for every course. For each course, prestigious scientists who have made seminal contributions to the theme-related field are invited to deliver principal lectures. The school, held over one to two weeks, will consist of:

The first Xmod will be held in the State Key Laboratory of Marine Environmental Science (MEL) of Xiamen University on March 12–17, 2018. The theme of the first Xmod is Ocean Dynamics at Meso- and Submeso- Scales. Two principal lecturers have been invited to deliver the core lectures, including

Basic geophysical fluid dynamics about instability theories and eddy-mean flow interaction; large to mesoscale variability and the transition to submesoscales, etc.

Submesoscale dynamics; coupling with gravity-wave motions; frontiers of submesoscale studies (e.g., observations and simulations), etc.

Ten graduate students and early-career scientists are selected as fellows of the school, for whom local accommodation and meals will be provided by MEL. Others are welcomed as guest participants. Fellows are expected to actively participate in all aspects of the school. The fellows are encouraged to publish their project-related outcome together with their supervisors (i.e., the principal or guest lecturers).

Coordinators

Zhiyu Liu ()

Rui Xin Huang (Co-chair, Woods Hole Oceanographic Institution)

Bo Qiu (University of Hawaii)

Jianping Gan (Hong Kong University of Science and Technology)

Minhan Dai (Xiamen University)

Time	Talk Title	Speaker
March 12 Monday
0850-0900	Opening
0900-1100	Lectures 1 & 2	Patrice Klein
1115-1215	Multiple reflection and related mixing during barotropic and baroclinic internal tide propagation	Qiang Li
1215-1430
	Lecture 1 & 2	Bo Qiu
1630-1715	Mooring observations of mesoscale eddies in the northern South China Sea	Zhongbin Sun
Tuesday
	Lectures 3 & 4
1115-1215	Analytic frontogenesis and sub-mesoscale effects in the west Pacific	Zhiyou Jing
1215-1430	Lunch break
	Lecture 3 & 4	Bo Qiu
1630-1715	Quasigeostrophic evolution of an isolated cold eddy perturbed by typhoon	Zhumin Lu
March 14 Wednesday
	Lectures 5 & 6	Patrice Klein
		Guihua Wang
1215-1430
	Lecture 5 & 6	Bo Qiu
	Diagnosis of 3-D vertical circulation in the upwelling and frontal zones east of Hainan Island	Lingling Xie
March 15 Thursday
	Lectures 7 & 8	Patrice Klein
1115-1215	Eddy induced transport: from the Kuroshio to the AMOC	Xiaopei Lin
1215-1430
	Lecture 7 & 8	Bo Qiu
1630-1715	A CFSFDP clustering-based eddy trajectory tracking method	Huizan Wang
March 16 Friday
	Lectures 9 & 10	Patrice Klein
1115-1215	The development of an global eddy-resolving ocean model	Hailong Liu
1215-1430
1430-1515	The Interaction between Mesoscale-eddy and the Western Boundary Undercurrents in the North Pacific Ocean	Qiuping Ren
1530-1615	Diapycnal fluxes of nutrients in an oligotrophic oceanic regime: The South China Sea	Chuanjun Du

March 17 Saturday
0900-1000	Observed and simulated submesoscale vertical pump inside an anticyclonic eddy in the South China Sea	Yisen Zhong
1015-1100	Submesoscale effects on the ecosystem in the South China Sea: preliminary results	Wenfang Lu
1115-1215	The interannual and annual variability of the eddy kinetic energy in the Labrador Sea: observation vs numerical study	Weiwei Zhang
1215-1430	Lunch break
1430-16:30	Summary and discussion

Twenty-five years of satellite altimetry have revealed that mesoscale eddies (with a size of 50-300 km) capture most of the kinetic energy in the World Ocean. For a long time, this mesoscale eddy turbulence was thought to explain most of the horizontal and vertical fluxes of any properties. Only recently, a new vision has emerged that points to the importance of another class of balanced (or geostrophic) motions with smaller scales (1 – 50 km), also called sub-mesoscales. These sub-mesoscales are now known to capture most of the vertical velocity field in the upper ocean. Their dynamical importance has led to revisit our understanding of the ocean dynamics. These lectures aim to explain this new vision and, in particular, to introduce the main dynamical properties associated with these sub-mesoscales as well as their impact on the dispersion of pollutants, biodiversity, air-sea interactions and the ocean energy route. The future observational systems (including those from space and in-situ), designed to capture these scales, will be presented as well as the next challenges our world community will have to meet.

- Definition of sub-mesoscales: differences with mesoscale structures in terms of time scales and spatial scales.

- Evidence of the existence of sub-mesoscale structures in the world ocean from satellite images (coherence between infrared, ocean color, SAR and glitter images) and from recent in-situ observations (gliders, …).

- Basic dynamical properties of sub-mesoscales: role of mesoscale eddies to trigger density fronts at small scales (direct cascade). Vertical extension of sub-mesoscales.

- Why do sub-mesoscales capture most the vertical velocity field in the upper ocean (whereas mesoscale eddies capture most of the horizontal kinetic energy).

- Frontogenesis and Omega equation: basic concepts and how they help to understand sub-mesoscales dynamics.

- The Surface Quasi-Geostrophic model as a suitable and simple dynamical framework to understand the production of sub-mesoscales and their feedback onto mesoscale eddies (through the inverse kinetic energy cascade).

- Surface Quasi-Geostrophic and 2-D turbulence: their major differences (and consequences of these differences on the dispersion of pollutants, the biodiversity, the climate system, …).

- Impact of mixed-layer instabilities on the seasonal cycle of the mesoscale eddy kinetic energy

- A new satellite altimetry mission dedicated to the observation of sub-mesoscales: the Surface and Water Ocean Topography (SWOT): perspectives and challenges to meet (how to discriminate sub-mesoscales and internal gravity waves (IGW)).

- IGWs: basic differences with geostrophic (balanced) motions and in particular with sub-mesoscales.

- The Shallow Water model: a suitable and simple framework to understand the horizontal and vertical propagation of IGWs.

- Mechanisms associated with mesoscale eddies that scatter and disperse large-scale IGWs leading to a continuous IGW spectrum with characteristics close to those of sub-mesoscales.

- Some perspectives to discriminate sub-mesoscales and IGWs from satellite and in-situ observations.

The lectures intend to introduce basic concepts and dynamics regarding mesoscale ocean circulation variability, oceanic waves, instabilities, and nonlinear eddies. Rather than treating them as separate topics, the lectures strive to progressively combine them in a comprehensive way. Through concrete examples of observations, the lectures attempt to help students to gain an appreciation as to how basic dynamic concepts can be usefully applied to understand real-ocean phenomena.

- Baroclinic Rossby waves vs. mesoscale eddies, Mesoscale eddy statistics in world ocean, Eddy-induced material transport, Basics of instability analysis, Kelvin-Helmholts instability

- Richardson number criterion, 2D->3D instability transition, Squire's theorem, Barotropic instability, Effect of beta & divergence, Finite-amplitude behavior of shear instability, eddy-eddy interaction

- Baroclinic Instability, Wave-wave interaction, Seasonality in mesoscale variability, Interior versus mixed layer instability, Inverse energy cascade

- Beta-plume, Zonal-mean flow generation as Rossby wave rectification, Resonant triad instability, Turbulent Sverdrup balance