The North Atlantic oscillation influence on the wave regime in Portugal an extreme wave event analysis

Semedo, Alvaro A. M.

03 1900

Waves in the North Atlantic are strongly seasonal, and peak in the winter season. The west coast of Portugal is exposed to winter swell, generated by wind associated with North Atlantic extratropical cyclones. The track of these storms, generated near the North America east coast, is strongly influenced by the North Atlantic Oscillation (NAO). When the NAO is in its positive phase they normally track northeast and reach Western Europe well north of the Iberian Peninsula, in the British Islands or Scandinavia. However, in the negative NAO situation,the track of the storms is more zonal and south than usual, due to a weakened NAO. The characteristics of wave regime in Portugal are shown to be strongly related to the NAO phase and corresponding storm tracking. Positive NAO storms, tracking northeast towards the north of Europe, drive longer period swell from the northwest, whereas negative NAO storms have associated shorter period swell arriving to Portugal from a more westerly direction. The relation between the NAO phase and the storm tracks and the characteristics of the wave regime is investigated with ten year observations from four directional waverider coastal buoys, located off the coast of Portugal.

North Atlantic oscillation

Wind waves

Ocean-atmosphere interaction

Cyclones

The variability of North American winter surface temperature and its relation to the sea surface temperature /

Li, Wei, 1982-

January 2006

No description available.

North Atlantic oscillation.

Evolution of climate anomalies and variability of Southern Ocean water masses on interannual to centennial time scales

Santoso, Agus, Mathematics & Statistics, Faculty of Science, UNSW

January 2005

In this study the natural variability of Southern Ocean water masses on interannual to centennial time scales is investigated using a long-term integration of the Commonwealth Scientic and Industrial Research Organisation (CSIRO) coupled climate model. We focus our attention on analysing the variability of Antarctic IntermediateWater (AAIW), Circumpolar DeepWater (CDW), and Antarctic Bottom Water (AABW). We present an analysis of the dominant modes of temperature and salinity (T - S) variability within these water masses. Climate signals are detected and analysed as they get transmitted into the interior from the water mass formation regions. Eastward propagating wavenumber-1, -2, and -3 signals are identied using a complex empirical orthogonal function (CEOF) analysis along the core of the AAIW layer. Variability in air-sea heat uxes and ice meltwater rates are shown by heat and salt budget analyses to control variability of Antarctic Surface Water where density surfaces associated with AAIW outcrop. The dominant mode in the CDW layer is found to exhibit an interbasin-scale of variability originating from the North Atlantic, and propagating southward into the Southern Ocean. Salinity dipole anomalies appear to propagate around the Atlantic meridional overturning circulation with the strengthening and weakening of North Atlantic Deep Water formation. In the AABW layer, T - S anomalies are shown to originate from the southwestern Weddell Sea, driven by salinity variations and convective overturning in the region. It is also demonstrated that the model exhibits spatial patterns of T - S variability for the most part consistent with limited observational record in the Southern Hemisphere. However, some observations of decadal T - S changes are found to be beyond that seen in the model in its unperturbed state. We further assess sea surface temperature (SST) variability modes in the Indian Ocean on interannual time scales in the CSIRO model and in reanalysis data. The emergence of a meridional SST dipole during years of southwest Western Australian rainfall extremes is shown to be connected to a large-scale mode of Indian Ocean climate variability. The evolution of the dipole is controlled by variations in atmospheric circulation driving anomalous latent heat uxes with wind-driven ocean transport moderating the impact of evaporation and setting the conditions favourable for the next generation phase of an opposite dipole.

Climatic changes -- Mathematical models.

Dynamics of laboratory models of the wind-driven ocean circulation

Kiss, Andrew Elek.

January 2000

No description available.

Ocean circulation Mathematical models

Surface heat flux estimates from NCAR electra data over the pacific warm pool during TOGA COARE

Greiser, Christine M.

25 January 2002

The warm pool region of the western tropical Pacific is of particular interest to atmospheric dynamics because it represents a significant source of energy to the atmosphere. A better understanding of heat transfer driven by mesoscale and turbulent circulations within this region could lead to improved global circulation models, and therefore to improved prediction of global weather patterns. A first step to this understanding is to evaluate empirical data as well as the methods used to estimate heat transfer, or heat flux, at the surface. Of specific interest here are latent heat flux, the heat transfer associated with evaporation, and sensible heat flux, the heat transfer associated with convection and conduction. In this paper, two different methods of turbulent flux calculation, eddy correlation and the bulk aerodynamic method are compared. Eddy correlation directly uses turbulence measurements to estimate heat flux whereas the bulk aerodynamic method relies on similarity theory to relate heat flux to mean flow quantities. A brief discussion of selection of averaging length based on flight altitude is included, as well as a comparison of errors introduced in averaging velocity as a scalar or as a vector. Errors introduced by averaging, including mesoscale flux enhancement, are evaluated for strong and weak wind cases during relatively light convection in the region. Finally, month to month variability in heat flux is evaluated in an effort to further understand the accuracy of various approximations used in flux calculation. / Graduation date: 2002

Atmospheric temperature -- Pacific Ocean

Simulation of tropical pacific circulation anomalies with linear atmosphere and ocean models

Dixit, Sanjay

12 August 1987

A simple atmosphere and ocean model of relevance to El Nino and Southern Oscillation (ENSO) is discussed. Both the atmosphere and ocean models are two layer, three dimensional, linear and baroclinic, and generally follow the Oregon State University coupled general circulation model. However, the parameterization differs considerably from previous work in the treatment of the atmospheric latent heat release. This new parameterization follows the formula used in the theory of conditional instability of the second kind (CISK). In this the latent heat release is proportional to the low level convergence. Utilizing the "Comprehensive Ocean Atmosphere Data Set" (COADS), which contains all oceanic and atmospheric surface variables over the global ocean from 1946-1979, experimental model results are discussed for determination of the validity of the parameterizations. In particular, the years 1957, 1965 and 1972 in which El Nino events occurred are examined. The parameterization is deemed to be realistic, and should permit simulation of the El Nino upon coupling the two models. / Graduation date: 1988

El Niño Current

Southern oscillation

A study of El Niño/southern oscillation : numerical experiments and data analysis

Ahn, Joong Bae

23 August 1990

For the purpose of investigating the fundamental nature of the interannual oscillation observed in the tropical Pacific in conjunction with El Nino/Southern Oscillation (ENSO), the Comprehensive Ocean Atmosphere Data Set was analyzed. Based upon this analysis, an "intermediate" tropical atmosphere-ocean coupled model was developed. For reason of their particular importance to atmosphere-ocean interactions, moisture processes such as condensation-convergence, evaporation-sea surface temperature and evaporation-wind feedbacks were given special emphasis in both the data analysis and modeling processes. The atmospheric component of the model is based on the first baroclinic mode, which is driven by the atmospheric internal heating. The oceanic model consists of two layers with an imbedded oceanic mixed-layer, by which SST is predicted. The present study has demonstrated that despite the structural simplicity of the oceanic model, it is capable of simulating mean oceanic circulation. In preparation for coupling, individual models were first tested with the use of appropriate time-dependent boundary conditions specified from the composite ENSO data. Both model simulations reproduced the major features associated with the ENSO events. Coupling was performed following the imposition of wind stress anomalies over the western Pacific for a given time period and the removal of all external forcing for a period of eight years thereafter. The coupled responses simulated during the the first two-year period provided reasonable simulations of the following ENSO-like features: the appearance of warm sea-surface temperature anomalies in the central Pacific, deepening/shallowing of mixed-layers in the eastern/western Pacific, weakening of the trades in the central Pacific, strengthening/weakening of the North Equatorial Counter Current/South Equatorial Currents, and enhanced convective activities around the dateline. The long-term coupled integration showed a pattern of interannual oscillation over a period of approximately three years. The results obtained from this coupling study have illustrated (1) that the necessary condition for the interannual oscillation is the interaction between the atmosphere and the ocean and (2) that it is likely that oceanic wave dynamics plays a crucial role in the determination of the growth and decay of ENSO events. / Graduation date: 1991

El Niño Current

Southern oscillation

Air flow separation over wind generated waves

Saxena, Gaurav.

January 2007

Thesis (M.S.)--University of Delaware, 2007. / Principal faculty advisor: Fabrice Veron, College of Marine and Earth Studies. Includes bibliographical references.

Extraction of wind speed from high frequency ground wave radar oceanic backscatter /

Green, David W.,

January 2005

Thesis (M.Eng.)--Memorial University of Newfoundland, 2005. / Bibliography: leaves 71-76.

Surface wind response to oceanic fronts /

Song, Qingtao.

January 2006

Thesis (Ph. D.)--University of Rhode Island, 2006. / Typescript. Includes bibliographical references (leaves 94-101).