En la región de las grandes islas (RGI) del golfo de California la mezcla por mareas juega un papel muy importante en la distribución de propiedades disueltas. Aunque la variabilidad temporal de las masas de agua está ligada con la dinámica oceanográfica de la región, su importancia no ha sido considerada. En este trabajo se estima el efecto de la dinámica de las masas de agua sobre la distribución espacial y variación estacional del carbono inorgánico disuelto (CID) en la RGI, con especial énfasis en el canal de Ballenas, durante el invierno de 2002, la primavera de 2003 y el verano de 2004. El Agua del Golfo de California (AGC) se encontró en toda la superficie en los primeros 100 m de profundidad. Por debajo del AGC, el Agua Subsuperficial Subtropical (ASS) llenó las cuencas Delfín, Salsipuedes y Tiburón, mientras que en el sureste se encontró entre 150 y 350 m. El Agua Intermedia del Pacifico no atravesó los umbrales. Se encontró que el ASS enriquece de CID las aguas superficiales de la RGI cuando aumenta su volumen y cuando se mezcla con el AGC por efecto de las mareas. El aporte disminuye hacia el verano, cuando el ASS se hunde al mismo tiempo que el volumen de AGC aumenta. En invierno, el AGC presentó tres tipos de agua asociadas a los procesos de mezcla y en combinación con la presencia de ASS. Se encontró también que en la RGI la relación CID vs temperatura podría aplicarse en futuros estudios para analizar la dinámica del carbono en la RGI, tanto en la superficie mediante imágenes de satélite como en la vertical para simular procesos físicos. | In the Midriff Islands region (MIR) of the Gulf of California (Mexico), tidal mixing plays a very important role in the distribution of chemical properties. Although the temporal variability of the water masses is linked to the ocean dynamics of this region, its importance has not been considered. This work estimates the effect of water mass dynamics on the spatial distribution and seasonal variation of dissolved inorganic carbon (DIC) in the region, with special emphasis on the Ballenas Channel, during winter 2002, spring 2003, and summer 2004. Gulf of California Water (GCW) was found throughout the area in the first 100 m. Below, Subtropical Subsurface Water (SSW) filled the Delfín, Salsipuedes, and Tiburón basins, while to the southeast it was found between 150 and 350 m. Pacific Intermediate Water did not cross the sills. SSW enriches the surface water of the MIR with DIC when it increases in volume and when mixed with GCW by tidal effects. This contribution decreases towards summertime, when SSW sinks and the volume of GCW increases. In winter, GCW had three water types associated with oceanographic mixing processes and in combination with the presence of SSW. There was a strong DIC vs temperature relationship, which can be applied to analyze the carbon dynamics in the MIR, both at the surface using satellite imagery and vertically to simulate physical processes.

The continuous abstraction of groundwater from Arusha aquifers in northern Tanzania has resulted in a decline in water levels and subsequent yield reduction in most production wells. The situation is threatening sustainability of the aquifers and concise knowledge on the existing groundwater challenge is of utmost importance. To gain such knowledge, stable isotopes of hydrogen and oxygen, and radiocarbon dating on dissolved inorganic carbon (DIC), were employed to establish groundwater mean residence time and recharge mechanism.¹⁴C activity of DIC was measured in groundwater samples and corrected using a δ¹³C mixing method prior to groundwater age dating. The results indicated that groundwater ranging from 1,400 years BP to modern is being abstracted from deeper aquifers that are under intensive development. This implies that the groundwater system is continuously depleted due to over-pumping, as most of the sampled wells and springs revealed recently recharged groundwater. High ¹⁴C activities observed in spring water (98.1 ± 7.9 pMC) correspond with modern groundwater in the study area. The presence of modern groundwater suggests that shallow aquifers are actively recharged and respond positively to seasonal variations.