Case study analysis of warm conveyor belt and low level jet phenomena

Letestu, Andre-Charles

January 1994

No description available.

551.5

Baroclinic wave; Frontogenesis

On the generation of waves during frontogenesis

Shakespeare, Callum

January 2015

Density fronts are ubiquitous features of the ocean and atmosphere boundary layers. Boundary layers are characterised by strong surface fluxes of heat, water and momentum, and exhibit intense eddy fields that are associated with strong horizontal strains. Such boundary layer phenomena can drive the generation and sharpening of frontal density gradients in a process known as frontogenesis. Analytic models of frontogenesis have typically employed the `two-dimensional front' configuration where the density front is assumed to be infinitely long and straight, such that gradients along the front may be neglected, and the mathematical problem reduced to two spatial dimensions. Hoskins and Bretherton (1972) used this configuration to demonstrate how a weak background strain flow, associated with a large scale weather system, can drive the collapse of a boundary front to a discontinuity in the inviscid equations in finite time. More recently, Blumen (2000) has used the same configuration to demonstrate how an unbalanced initial state --- associated with a rapidly applied boundary flux --- can trigger an adjustment process which drives frontogenesis on the boundary. These two types of frontogenesis are known as `forced' and `spontaneous', respectively. Forced and spontaneous frontogenesis have typically been studied in isolation, despite it being well established that they can and do occur simultaneously. Furthermore, neither the Hoskins and Bretherton (1972) nor Blumen (2000) models include propagating inertia-gravity waves, despite recent observations and numerical simulations showing that these waves are often generated during active frontogenesis. Here we formulate a generalised mathematical model for the classical two-dimensional density front subject to a simple background strain flow, as studied by Hoskins and Bretherton (1972) . This model firstly unifies the disparate frontogenesis theories of Hoskins and Bretherton (1972) and Blumen (2000). Secondly, the model extends these theories by permitting arbitrary initial conditions, stratification and strong strains. Thirdly, the model incorporates non-hydrostatic effects and unbounded domains. An important novel feature of the model is the accurate description of inertia-gravity wave generation during frontogenesis. We show that these waves can be generated both by the geostrophic adjustment of initial imbalances in a stratified ambient, and spontaneously due to the acceleration of the strain flow around the front. The generalised model thus provides a unified theory capable of describing frontogenesis and wave generation in the atmosphere and ocean boundary layers on a vast range of scales. In particular, the inclusion of strong strains permits the description of frontogenesis on the ocean submesoscale. The predictions of the generalised model are confirmed by comparison with a suite of fully non-linear numerical simulations.

551.46

Oceans ; Waves ; Fronts ; Frontogenesis

Variability of Suspended-Sediment Concentration in the Connecticut River Estuary

Cuttler, Michael Vincent William

January 2012

Thesis advisor: Gail Kineke / Turbidity maxima are areas of elevated suspended-sediment concentration commonly found at the head of the salt intrusion in partially-mixed estuaries. The suspended-sediment distribution in the Connecticut River estuary was examined to determine where turbidity maxima exist and how they form. Areas of enhanced suspended-sediment concentration were found to exist at all phases of the tide near the head of the salt intrusion as well as downstream of this point in deeper parts of the estuarine channel. These areas are locations where peaks in the longitudinal salinity gradient exist, suggesting the presence of a front, or zone of flow convergence. During flood conditions there is a layer of landward-flowing water in the middle of the water column that decelerates upon entering deep parts of the estuary; thus enhancing particle settling. During ebb conditions, stratification and therefore settling from surface waters is enhanced. The combination of processes acting throughout the tidal cycle focuses and, potentially, traps sediment in the deeper parts of the Connecticut River estuary. / Thesis (BS) — Boston College, 2012. / Submitted to: Boston College. College of Arts and Sciences. / Discipline: College Honors Program. / Discipline: Geology & Geophysics Honors Program. / Discipline: Earth and Environmental Sciences.

estuary

Connecticut River

frontogenesis

turbidity maximum

suspended-sediment