The Gulf of Mexico (GoM) is a semienclosed sea with deep areas and narrow as well as wide continental shelves (Fig. 1). The GoM has been the object of many studies, so it is important to periodically review and synthesize recent results and to identify knowledge gaps, warranting investigation in the near future. The purpose of this manuscript is to review what has been learned in recent years related to the local surface forcing of the GoM, both by heat fluxes and wind stress. Some historic publications have reviewed general aspects of the GoM and others have been more topically focused. Examples of these review publications are the very ambitious and successful Fishery Bulletin 89 (Galtsoff, 1954) that summarizes the knowledge on the Gulf at that time, including information of its marine meteorology, geological features, the physics and chemistry of its waters, its physical oceanography, and a detailed review of its biology. Another classical document is a book edited by Capurro and Reid (1972), which includes chapters related to the physical phenomena affecting the GoM that were studied at that time. Recently, the American Geophysical Union published a monograph (Sturges and Lugo-Fernández, 2005), which includes articles on the current knowledge of the Gulf in selected topics.

Fig. 1.

The Gulf of Mexico. States and names of shelves are indicated. Position of the Canek Project moorings along the 130m isobath are also indicated (Drubranna et al., 2011).

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Recent events, like the Deep Water Horizon oil spill of 2010, opened discussion on several aspects of the GoM dynamics, like the influence of the wind on the oil spill advection and dispersion, the transport from deep-water to coastal areas, the role of wind waves in the mixing and dispersion of the oil, the mixed layer dynamics, etc., which brought renewed attention to these ocean processes (Liu et al., 2011). Perhaps bolstered by this event, substantial work has been undertaken on a new generation of very high resolution numerical models used to simulate biogeochemical and biological processes, which are strongly influenced by the ocean-atmosphere interaction. The present work summarizes recent advances in understanding the influence of heat and momentum fluxes (wind stress) on the GoM dynamics and thermodynamics. The annual cycle of heat fluxes and winds is described, emphasizing the response of the mixed layer depth, sea surface temperature (SST), and entrainment. The influence of the wind stress and wind stress curl on the circulation of the GoM, particularly on the shelves, coastal upwelling and cross-shelf transports, including the seasonality and interannual variability (in some cases), are also described.

Although the low level winds over the GoM are very important for the ocean circulation, surface fluxes, mixed layer properties, and generation of wind waves, there are relatively few studies about them (e.g., DiMego et al., 1976; Gutiérrez and Winant, 1996; Wang et al., 1998). However, several other studies have analyzed specific aspects of the winds over the GoM that are related with particular ocean processes (e.g. Oey, 1995; Zavala-Hidalgo et al., 2003; Morey et al., 2005; Nowlin et al., 2005; Vázquez de la Cerda et al., 2005; Martínez-López and Zavala-Hidalgo, 2009; Dubranna et al., 2011; Mateos-Jasso et al., 2012; Pérez-Brunius et al., 2013). Here, a general description of the characteristics of the wind and surface fluxes in the GoM is presented, and other aspects that need to be analyzed or updated are suggested.

2.1Seasonal variability of the winds

The winds in the GoM have strong variability over different time and space scales, with important seasonality. The GoM is affected by intense winds caused by tropical cyclones that cross it between May and November and by cold fronts reaching the area mainly between September and May. Winds that are not associated with these strong events are weaker, but are important for upwelling, mixed layer depth, surface fluxes, circulation (particularly on the shelves), development of wind waves, etc.

Winds over the GoM are part of the trade winds and have a large influence on the North American continent. Based on long-term monthly means computed from the QuikSCAT/SeaWinds scatterometer data, it is observed that, during summer, the wind turns toward the north in the northwestern Gulf due to the influence of the North Atlantic semi-permanent atmospheric high-pressure system over the northeastern region (Fig. 2). This pattern is probably reinforced by the high temperature over land driving a monsoonal effect. Between May and August, winds are more intense in the western Gulf and are weaker in the northeast, with this pattern more evident in July (Fig. 2). In September, this wind pattern changes because the cold fronts associated with atmospheric high-pressure systems coming from the northwestern United States begin to reach the GoM and the semi-permanent high-pressure system over the Atlantic Ocean shifts northeastward. During autumn, the long-term monthly mean wind direction in the northern Gulf is mainly westward, with a small southward component. In the Bay of Campeche an intense southward wind component develops, mainly in the western side of the bay, favored by a mountain blocking effect caused by the Sierra Madre Oriental in Mexico that directs the wind through the Isthmus of Tehuantepec where the mountain chain has a low altitude passage. In addition, the lower pressure in the Gulf of Tehuantepec also favors southward winds (Romero-Centeno et al., 2003). This pattern remains until February and it is more pronounced in December (Fig. 2).

Fig. 2.

Long-term monthly means (1999-2006) of the winds in the Gulf of Mexico based on Qscat/SeaWinds data. Contours indicate the scalar mean wind speed (ms-1) according to the color bar and arrows indicate the wind direction. (Continues.)

The time-mean wind stress curl is negative (anticyclonic) north of 23 ºN and positive (cyclonic) south of that latitude, mainly in the Campeche Bay. The zero wind stress curl contour line has a southeast-northwest orientation (Gutiérrez de Velasco and Winant, 1996, their Figs. 5-8). The annual cycle of the wind stress curl is characterized by the displacement of the zero contour line, moving southward during spring and summer and northward in autumn and winter. The largest negative values of the wind stress curl are observed in the northeastern GoM in summer and they became smaller in winter. During autumn and winter, positive values are larger in the western Bay of Campeche (Gutiérrez de Velasco and Winant, 1996, their Figs. 5-8).

2.2High frequency winds

Every year several easterly waves are generated over west Africa and the eastern tropical Atlantic. These perturbations travel from east to west as Rossby waves, with wavelengths of about 2000 to 5000km and phase speed between 8 and 12ms−1. In some cases, these waves develop into tropical storms or hurricanes (Burphee, 1974; Diedhiou et al., 1999), but not all the tropical cyclones are generated by easterly waves. In the tropical North Atlantic basin there is an annual cumulative average of 11.3 named systems of which 6.2 are hurricanes (www.nhc.noaa.gov). Not all the easterly waves reach the GoM because, in many cases, they turn northeastward crossing the major Caribbean Islands or turn even before the Caribbean Sea. When easterly waves reach the GoM they affect the stratification and shelf circulation, because they produce changes in the direction and intensity of the winds (Mateos-Jasso et al., 2012).

The cold fronts, or northers, can occur all year round in the GoM but with different intensity, frequency, and southward penetration. They have associated strong northerly winds and cold and dry air masses. During summer they are very rare, while in autumn-winter are more frequent. The transition between these two seasons occurs in late September and is very sharp. These strong fronts can continue to occur until spring, but diminishing in numbers and intensity through April and May (DiMego et al., 1976). Not all the fronts cross the whole GoM; most of them only reach the northern part. The duration of the strong winds and cold air associated with the passage of fronts also decreases southward. Therefore, the number of observed fronts per year and their duration depends on the region of the GoM (Fig. 3) (DiMego et al.,1976). Another characteristic of the northers is the occurrence during autumn, in some years, of long periods of continuous northerly winds offshore of Veracruz (Mateos-Jasso et al., 2012) (Fig. 4). These long events were not observed in the winter months, although the study of Mateos-Jasso et al. (2012) covers few years.

Fig. 3.

Long-term monthly means of the frequency of occurrence of frontal systems during the 1965-1972 period. Figure from DiMego et al., 1976.

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Fig. 4.

Along-coast wind component at the Veracruz Coral Reef System computed from the NARR data (2007–2012): northwesterly winds in gray and southeasterly winds in black (following Mateos-Jasso et al., 2012).

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Before the arrival of a cold front, southeasterly winds are observed, associated with high moisture content, high temperatures and low atmospheric pressure. Once the front crosses a given location, the wind intensifies and changes its direction, the atmospheric pressure increases, and the temperature drops (DiMego et al., 1976). Frequently, during the frontal passage, heavy precipitation occurs (López-Méndez, 2009).

The SST of the GoM has a large amplitude annual cycle, with a considerable spatial variability. This was the object of study in the 1980s, 1990s, and early 2000s, but recently there has not been an update based on new available data and high resolution models. The goal of an update should be to have smaller uncertainties on the assessment of the contribution of each term in the heat balance equation (Eq. 1). Some early studies estimated the value of one or several terms of the heat content equation for the GoM (Hastenrath, 1968; Etter, 1983; Etter et al., 1987; Adem et al., 1993; Zavala-Hidalgo et al., 2002), which can be represented as follows:

where

is the total heat energy, is the density and Cp is the specific heat of sea water, T is the temperature, and Tref is a reference temperature so that H values are relative to it. Qs, Qb, Qe, and Qh are the net short wave radiation into the ocean, the heat emitted by the ocean as long wave radiation (including the atmospheric feedback due to the greenhouse effect), the latent heat flux due to evaporation, and the sensible heat, respectively (in this case all terms are positive when the ocean gains heat, so usually Qb is negative). The term Qa is the lateral heat advection. Heat content has been estimated based on hydrographic data (Etter, 1983), empirical formulae and, in some cases, considering the temperature and fluxes through the Yucatan Channel (Hastenrath, 1968; Hastenrath and Lamb, 1978; Etter, 1983; Adem et al., 1993). These estimations have shown that the GoM gains heat from March or April to August or September, with the peak of heat gain between May and July. The net surface heat flux over the whole year is estimated to vary between −24 Wm−2 and 46.6 Wm−2 (Table I). Differences are due to the different methodologies used in those studies, e.g. different turbulent coefficients on the bulk formulae, short wave radiation formulations, cloud cover, wind speed, and the consideration or not of entrainment (see Zavala-Hidalgo et al., 2002 for a detailed discussion of each term). Heat fluxes associated with individual synoptic scale events, such as northers, may be very large, as discussed by Nowlin and Parker (1974), Villanueva et al. (2010), and Rudzin et al. (2013).

Zavala-Hidalgo et al. (2002), Mendoza et al. (2005), and Villanueva et al. (2010) proposed that the mixed layer entrainment via turbulent mixing has a significant contribution to the winter SST cooling. It was found that there is a better agreement between observations and the modeled SST when entrainment is considered. SST, mixed layer depth and entrainment were estimated using a primitive equation numerical model with bulk formulas by Zavala-Hidalgo et al. (2002), and using a model with climatological currents coupled to a Kraus-Turner type model (Kraus and Turner, 1967) by Mendoza et al. (2005). Both studies show similar annual cycles and values for the entrainment, with larger values between November and February, and for the mixed layer depth, which is deeper in December-March and shallower in June-August (Fig. 5). In addition, it was shown that there is a strong relation between the entrainment and pigment concentration in the deep GoM (estimation of chlorophyll-a concentration), with high values during winter and low in summer (Fig. 5).

Fig. 5.

Top: Comparison of the annual cycle of the mixed layer depth from observations (solid line) and model results (dashed line). Bottom: Annual cycle of the entrainment velocity (dashed line) and the photosyntetic pigment concentration (solid line). Adapted from Mendoza et al., 2005.

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The autumn-wintertime changes of mixed layer depth and entrainment discussed above are mainly due to the northers, through increased mixing and cooling heat flux during autumn-winter. These processes are more intense in the northern GoM where the lowest temperatures are observed. The impact of a single norther on the SST and mixed layer depth was studied by Villanueva et al. (2010). During that event there was a larger contribution to the temperature decrease by the entrainment than by the added contribution of the sensible and latent heat fluxes.

There are differences between the physical processes in the deep ocean and those occurring on the shelves, even considering only the near surface layer of tens of meters. The shoreline restricts the motion leading to circulation patterns that are not observed in the open ocean, in particular the coastally trapped waves, mainly barotropic, although baroclinic waves are observed along the slope. Another difference is the influence on the dynamics of rivers discharge, which induces strong density gradients by the input of fresh water that affects the water motion through buoyancy forces. Another major characteristic of the shelf circulation is due to the relatively low depth, which makes the bottom friction important. In addition to those characteristics of the shelves, the slope works, in some cases, as a barrier between the deep ocean and the shelf because of the conservation of potential vorticity, making the ratio of along-shelf current variability to cross-shelf current variability large.

Several studies have shown that the dynamics of the shelves, particularly in the inner shelf of wide shelves, is mainly driven by the local momentum flux and the fresh river input. Over the outer shelf, deep ocean eddies and the Loop Current may have an important contribution when they impinge on the shelf slope (Oey, 1995; Walker, 2005; Weisberg et al., 2005; Dubranna et al., 2011). The wind stress forcing has a seasonality in its direction and intensity, reversing the inner shelf currents along the year. The shelves in the GoM are distinguished by their behavior along the annual cycle, that is the case of the West Florida Shelf (WFS), the Mobile-Alabama-Florida shelf (MAFLA), the Texas-Louisiana shelf (LATEX), the Tamaulipas-Veracruz shelf (TAVE), and the Campeche Bank. Most studies have found that the inner-shelf is dominated by a wind-driven circulation with the along-coast wind stress component determining the current direction (e.g. Zavala-Hidalgo et al., 2003; Nowlin et al., 2005; Weisberg et al., 2005). Therefore, a scheme showing the monthly along-coast wind stress component has been helpful to understand the seasonality of the currents and other processes (Morey et al., 2005; Zavala-Hidalgo et al., 2006) (Fig. 6). There are regions showing a different behavior of the along-coast wind stress component and its variability along the year. The Campeche Bank has a clockwise wind stress component during the whole year; a small region offshore of the Campeche State has weak wind stress but changes between a counterclockwise direction during spring-summer to a clockwise during autumn-winter. The southernmost part of the GoM, in front of the Tabasco State, also shows a clockwise direction along the year. The region between southern Veracruz to the international border at the Río Bravo (Río Grande) mouth has a counterclockwise along-coast wind stress direction between September and March and clockwise between April and August. In the LATEX shelf, most of the year the wind stress component is counterclockwise except for a small period when it reverses. The WFS has a period with clockwise along-coast winds between October and March, and counterclockwise between April and September.

Fig. 6.

Monthly climatology of the wind stress (× 10−2 Pa) along the 200m isobath. The corresponding locations for along-isobath distances in the left panel are indicated in the map. Positive in the counterclockwise direction (from Morey et al., 2005).

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The seasonal shift in the wind direction has an associated directional change in the momentum fluxes affecting mainly the inner-shelf, in particular when the along-coast wind stress component is large. Major results regarding the circulation on the shelves are presented next.

5.2The Tamaulipas-Veracruz shelf

Compared to the LATEX shelf, there have been few studies on the TAVE shelf and observations are scarce. The most extensive observational program in the area has been the Canek Project, carried out by the Centro de Investigación Científica y de Educación Superior de Ensenada (Dubranna et al., 2011; Pérez-Brunius et al., 2013). Other observations have been made on the TAVE shelf at the regional level (Mateos-Jasso et al., 2012). Also, numerical studies have given a general view of the low frequency characteristics of the circulation on this shelf (Zavala-Hidalgo et al., 2003; Morey et al., 2005).

A major difference between the TAVE and the LATEX shelves is that the TAVE is narrower, varying from around 65km width in the border between Tamaulipas and Texas to around 15km in southern Veracruz and 40km in Tabasco, compared to the 200km width of the LATEX shelf. This difference affects the circulation because a distinction between the inner and outer shelves in the TAVE shelf is not as clear as in the LATEX shelf. The impinging eddies on the slope affect the external or outer shelf and studies on the LATEX shelf found that they have a major influence in the circulation from the shelf edge to the 50m isobath, but a similar study has not been done in the TAVE shelf.

Boicourt et al. (1998) first suggested that there may be a reversal of the currents on the TAVE shelf. Based on a numerical study, Zavala-Hidalgo et al. (2003) found a seasonal shift in the inner-shelf circulation (from the coast to the 25m isobath) along the TAVE shelf, being clockwise between May and August and counterclockwise between September and March. They were also able to reproduce the previously reported circulation for the LATEX shelf, being downcoast during the non-summer months and upcoast in July. They computed the transports between the 25m and the 50m isobaths on the TAVE shelf and obtained similar directions than those for the inner shelf. However, the TAVE shelf is narrow and more observations are needed to identify the coherence of the circulation between the inner and outer shelf.

During the Canek project, seven moorings were installed along the TAVE shelf and the southern GoM at 130m depth from November 2007 to July 2009. On the monthly scale, correlations between the along-shore wind stress and the along-shelf currents of about 0.77 and 0.78 on northern Veracruz and southern Tamaulipas, were estimated. Significant correlations of 0.47 in southern Veracruz (offshore of Coatzacoalcos) and of 0.41 in a site northwest of Ciudad del Carmen, Campeche, were found. However, a low and non-significant correlation was found offshore of Alvarado, Veracruz. Observed currents on the shelf of Veracruz in summer, pointing upcoast (clockwise), were about 15 to 40cm s−1. In northern Veracruz and central Tamaulipas current velocities in winter were 30 to 40cm s−1. It was also observed that in Tamaulipas there was a period in January when the current was heading northward while the wind was downcoast. Finally, a non-significant correlation between the along coast wind-stress and the observed currents offshore of northern Tamaulipas (Perdido) was found, although on average the seasonal pattern, with prevailing northward currents in spring-summer and southward currents in autumn-winter, was observed. During that project, the trajectory of drifters reaching the continental shelf was analyzed, concluding that during spring-summer 70% of the time the drifters headed upcoast. However, they found that there were some differences between drifters north of 21ºN, which all headed north, and those south of that latitude, which had more variable trajectories. During fall and winter, 74% of the drifters headed downcoast.

Coastally trapped waves were identified on the TAVE shelf by Dubranna et al. (2011) in the current observations associated to the intrusion of cold fronts with intense along-shore downcoast winds (Fig. 7). They identified two events in September and two in October. The phase speed of the coastal waves was estimated at 2.9ms−1, which was corroborated with the increase of the sea level in Veracruz city in both episodes.

Fig. 7.

Alongshore current velocities (cm s−1) measured by the moorings: (a) PER, (b) LMP, (c) ARN, (d) LNK, (e) IT1, (f) CTZ, and (g) IT2 (see Fig. 1 for location). Superimposed are the alongshore wind stresses at the position of the moorings. Positive (negative) values are upcoast (downcoast). The beginning of events of interest is marked by a vertical solid line with a W. Arrows show the maximum mean current speed following each W event. (h) The lowpassed (cutoff period is 30 days, dotted line) and band-passed (periods between 2 and 30 days, solid line) sea level anomaly (SLA) at the City of Veracruz which is located between LNK and IT1. SLA corresponding to the W events are marked by an arrow.

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As mentioned above, cross-shelf transports are constrained by the conservation of potential vorticity, such that the barotropic circulation is dominantly in the along-isobath direction. Therefore, cross-shelf transports imply that either there is strong baroclinicity, or friction and other terms are important in the momentum balance equation, making these motions less frequent than along-shelf motions. On the other hand, cross-shelf motions are important because they may carry nutrient rich subsurface water onto the shelf, and the shelf may bring riverine low salinity waters into the deep ocean. Also, cross-shelf transports may carry contaminants coming from inland into the deep ocean, or from the deep ocean onto the shelf as happens when there are deep ocean oil-spills. Larvae are also transported from the shelf to the deep ocean or vice versa (Sanvicente-Añorve et al., 2014).

In the GoM, eddy-pairs have been associated with cross-shelf transports (Biggs and Müller-Karger, 1994), but it has been demonstrated that there are regions with some seasonality in the cross-shelf transports not always related to eddy-pairs. The following summarizes those results.

Spatial variability of wind-driven circulation on the shelves results in differences in along-shelf transport, which in turn lead to regions of convergence or divergence. As seen in previous sections, this may be caused by the corresponding convergence or divergence of the along-coast wind component, which can occur due to spatial variability of the wind field or changes in orientation of the shelf under a relatively homogeneous wind field. The low frequency along-coast wind component has a region of convergence in the southernmost part of the GoM, mainly from September to February although present throughout the year; in the southern Texas shelf there is convergence between April and August. These two regions were identified to have large seasonality in their associated values of chlorophyll-a concentration and low salinity waters (Morey et al., 2003a, b, 2005; Zavala-Hidalgo et al., 2003; Martínez-López and Zavala-Hidalgo, 2009). In addition to these regions, a low salinity and high chlorophyll-a concentration seasonal signature has been identified offshore of the Mississippi river (Fig. 8), with a peak in June-August due to the southerly winds in the region favoring a westward Ekman transport during these months. Martínez-López and Zavala-Hidalgo (2009) showed that the interannual variability of the chlorophyll-a concentration offshore of the southern Texas shelf and in the Bay of Campeche might be explained by the interannual variability of the along-coast wind stress component and the corresponding of the shelf currents. Here, we extend the period of their computations and found that high correlations remain, explaining a large fraction of the interannual variability of chlorophyll-a concentration by the convergence of mass induced by the along-coast currents in those regions (Fig. 9). The chlorophyll-a concentration values over the southern Bay of Campeche were averaged in a box located between 19.5° N and 20.5° N in latitude and 93° W and 92° W in longitude. For the southern Texas shelf, the box limits were 26.5º N to 27.5º N in latitude and 96.75° W to 96° W in longitude.

Fig. 8.

Long-term monthly means (1997-2012) of chlorophyll-a concentration anomalies in the Gulf of Mexico. Anomalies were computed relative to the annual mean following the Martínez-López and Zavala-Hidalgo (2009) method.

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Fig. 9.

Alongshelf wind convergence anomalies (graythick line) and chlorophyll-a concentration anomalies from both SeaWiFS data (dashed line) and MODIS data (solid line). Upper panel: October-November anomalies in the Bay of Campeche. Lower panel: April-June anomalies in the southern Texas shelf. Following computations from Martínez-López and Zavala-Hidalgo (2009).

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Coastal upwelling has strong seasonality in the GoM, but occurs at different periods over different shelves. The TAVE shelf, in the western GoM, has upwelling conditions predominantly during summer, as has been identified in satellite images (Walker et al., 2003; Walker, 2005; Zavala-Hidalgo et al., 2006) (Fig. 10). The analysis in Mateos-Jasso et al. (2012), based on long-term almost continuous measurements of temperature in the water column at the Sistema Arrecifal Veracruzano (SAV), offshore of Veracruz city, shows stratification between April and September with low temperature near the bottom due to upwelling in the region. The upwelling is interrupted by the influence of tropical systems, like easterly waves and tropical storms, which change the Ekman transport from upwelling to downwelling conditions increasing temperature of the entire water column (Fig. 11). The signature of the upwelled water in the SST is relatively weak because the outcropping of the isotherms is not often observed in the satellite images. Upwelling and downwelling over the WFS occur in almost opposite seasons than in the TAVE shelf, with upwelling occurring in winter and downwelling in summer (Weisberg et al., 2005). There are important differences between the upwelling in the WFS and the TAVE shelves, since northerly winds in winter that induce upwelling (downwelling) in the WFS (TAVE) are more intense than the southeasterlies in summer that induce downwelling (upwelling) in the WFS (TAVE).

Fig. 10.

Mean sea surface temperature in the Gulf of Mexico for July computed from an 8-year AVHRR database (adapted from Zavala-Hidalgo et al., 2006).

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Fig. 11.

Annual time series of temperature at the surface and bottom (30m) in the northern Veracruz Coral Reef System for the years 2007-2012. SSTs from the AVHRR (blue); bottom temperature from an ADCP recorded every 30min (green), and temperature measured by a moored thermistor at 27m (purple). Black line represents the 24-h running mean (following Mateos-Jasso et al., 2012).

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The surface momentum and heat fluxes are intense in the GoM and are important for its hydrodynamics. As a consequence of these fluxes the mixed layer depth changes seasonally, being deeper in winter and there is a contribution on the winter cooling due to the entrainment of subsurface low temperature water that reaches the mixed layer. The entrainment also carries nutrients into the upper layer, increasing the chlorophyll-a concentration during winter months. Research on the importance of local forcing in the GoM has shown that shelves respond to wind stress and buoyancy fluxes due to surface heat fluxes and fresh water inputs. The response to the local forcing is more clear or, in some cases, limited to the inner shelf that develops along-shore currents as a consequence of the surface Ekman transport that induces cross-shelf pressure gradients and geostrophic along-coast currents. The heat fluxes also can induce cross-shelf pressure gradients because temperature decreases (increases) faster in autumn (spring) in the shallower regions, as has been shown for the WFS. The wide shelves, as the LATEX, the WFS and the Campeche Bank, have a well defined inner shelf strongly influenced by the along-coast wind stress. The external shelf has the influence of the Loop Current and the Loop Current eddies through their interaction with the slope, but still there are many open questions on these processes.

In the Bay of Campeche and offshore of the southern LATEX shelf, seasonality has been identified in cross-shelf transports as a result of the influence of the along-shelf wind stress component. This behavior has also been observed by the seasonality of the chlorophyll-a concentration estimated from satellites in those regions and by the modeled offshore export of low salinity waters. Also, the seasonality of the chlorophyll-a concentration, offshore of the Mississippi river mouth, was reported and explained as a consequence of the seasonality of the wind stress direction, which favors a westward transport in the northern GoM during summer.