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Article

Key Factors of Precipitation Stable Isotope Fractionation in Central-Eastern Africa and Central Mediterranean

by
Charles M. Balagizi
1,2,3,* and
Marcello Liotta
3
1
Geochemistry and Environmental Department, Goma Volcano Observatory, 142, Av. du Rond point, Goma, Democratic Republic of the Congo
2
Department of Chemistry, Institut Supérieur Pédagogique de Bukavu, PO Box 854, Bukavu, Democratic Republic of the Congo
3
Istituto Nazionale di Geofisica e Vulcanologia, Sezione di Palermo, Via Ugo La Malfa, 153, 90146 Palermo, Italy
*
Author to whom correspondence should be addressed.
Geosciences 2019, 9(8), 337; https://doi.org/10.3390/geosciences9080337
Submission received: 31 May 2019 / Revised: 16 July 2019 / Accepted: 24 July 2019 / Published: 31 July 2019
(This article belongs to the Special Issue Isotope Geochemistry of Meteoric Waters)
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Abstract

:
The processes of isotope fractionation in the hydrological cycle naturally occur during vapor formation, vapor condensation, and moisture transportation. These processes are therefore dependent on local and regional surface and atmospheric physical features such as temperature, pressure, wind speed, and land morphology, and hence on the climate. Because of the strong influence of climate on the isotope fractionation, latitudinal and altitudinal effects on the δ18O and δ2H values of precipitation at a global scale are observed. In this study, we present and compare the processes governing precipitation isotope fractionation from two contrasting climatic regions: Virunga in Central-Eastern Africa and the Central Mediterranean (Stromboli and Sicily, Italy). While Virunga is a forested rainy tropical region located between Central and Eastern Africa, the Mediterranean region is characterized by a rainy mild winter and a dry hot summer. The reported δ18O and δ2H dataset are from precipitation collected on rain gauges sampled either on a monthly or an approximately bimonthly basis and published in previous papers. Both regions show clearly defined temporal and altitudinal variations of δ18O and δ2H, depending on precipitation amounts. The Central Mediterranean shows a clear contribution of local vapor forming at the sea–air interface, and Virunga shows a contribution from both local and regional vapor. The vapor of Virunga is from two competing sources: the first is the continental recycled moisture from soil/plant evaporation that dominates during the rainy season, and the second is from the East African Great Lakes evaporation that dominates during the dry season.

1. Introduction

Oxygen and hydrogen stable isotopes (δ18O and δ2H) are among the tracers widely used to understand the processes involved in water circulation in the hydrological cycle. Besides the fact that oxygen and hydrogen isotopes are naturally occurring and quantitatively available, the changes in their concentration ratios are easily recorded during physical or chemical processes involving water, making them ideal to trace water mass movement [1,2,3,4,5]. The changes in the concentration ratios of isotopes during physical or chemical processes are referred to as isotopic fractionation. The nature of the processes that have occurred can then be determined from the observed differences in the isotopic compositions [1,4].
δ18O and δ2H fractionation naturally occurs throughout phase changes in the hydrological cycle, i.e., evaporation, condensation and diffusion. During vapor formation from surface waters—e.g., oceans, lakes, large rives, wetlands, etc.—the water molecules with lighter isotopes (i.e., 16O and 1H) evaporate first, leaving the evaporating source enriched with the heavier isotopes (i.e., 18O and 2H) [6,7,8]. As a consequence, the resulting precipitation is depleted in 18O and 2H relative to the residual evaporating source, which becomes enriched [6,9]. Conversely, during precipitation formation, molecules with heavier isotopes condense first, leaving the residual moisture cloud with depleted isotopes. The combined effects of evaporation, condensation and diffusion on stable isotope fractionation in the hydrological cycle lead to both latitudinal—and, thus, climatic—and altitudinal isotope effects [8,10,11,12]. Condensation and rainout over the continent are largely equilibrium-based fractionation processes, whereas evaporation largely undergoes kinetic or diffusion isotope fractionation, which are wind speed and temperature dependent. A close relationship between δ18O and δ2H in precipitation is observed globally and is defined by Dansgaard’s equation δ 2 H = s     δ 18 O + d [8] (where s indicates the slope, d indicates the intercept of the deuterium excess (d-excess), and the equation is known as the Global Meteoric Water Line (GMWL)).
The d-excess is strongly correlated with the physical conditions under which precipitation forms, e.g., air temperature and relative humidity (RH), wind speed and sea surface temperature, and therefore responds to environmental changes [13,14,15,16]. Thus, d-excess has been used in climatic studies to better understand and compare past and/to present precipitation formation processes (e.g., [17,18,19,20,21]). On the other hand, the seasonal weather variation (e.g., precipitation amount and temperature) in a given region leads to seasonal variations in 18O and 2H values. An altitudinal effect is similarly observed in both 8O and 2H values of precipitation at a continental scale, or in a region showing significant variation in elevation of the sampling locations. Hence, at a global scale, climate variation induces differences in stable isotope fractionation processes in precipitation, while at a regional scale, weather, topography and land-cover generally govern the fractionation. This study aims to characterize and compare the stable isotope fractionation of precipitation from two contrasting climatic regions: a continental tropical rainforest region in Central-Eastern Africa and a homogeneous climatic region with a local source of sea-derived vapor in the Central Mediterranean. This comparison brings insight into the ways in which climate features influence the stable isotope fractionation of oxygen and deuterium in precipitation. Climate features of tropical rainforest regions include a relatively high and nearly constant monthly mean air temperature and RH (high evaporation), a long rainy season with extreme events such as rainstorms, and a short dry season. The moisture is mainly from evaporating soil and surface waters, with an important input from plant transpiration. Conversely, the climate in the Mediterranean region is principally characterized by rainy, mild winters and dry, hot summers. These differences in climate and meteorological features yield differences in 18O and 2H fractionation in precipitation from both regions. Even though previous studies and sample collections were carried out in different time periods, the comparison of available datasets provides useful insights on how different climatic settings affect the isotope composition of precipitation. A detailed comparison is, thus, highlighted and discussed in the present study.

2. Material and Methods

2.1. Study Areas’ Geographical, Hydrographical and Climatic Settings

The first set of rainwater samples are from the Virunga region, in the eastern Democratic Republic of the Congo, which is a mountainous region (altitudes up to 4508 m a.s.l) located in the western branch of the East African Rift (Figure 1). At a local scale, it experiences combined effects from the Virunga mountain chain and the equatorial dense forest, which induce a local mountainous micro-climate [22]. The Virunga mountain chain consists of eight major volcanoes, of which only Nyiragongo (3470 m a.s.l) and Nyamulagira (3058 m a.s.l) are presently active [23,24,25,26,27,28]. The significant variations in altitudes in Virunga, often abrupt, are recorded in the noticed difference between the mean annual precipitation in the Virunga lowlands (found below 2000 m a.s.l.; 1300–1700 mm yr‒1) and highlands (> 2000 m; up to 2300 mm yr‒1) [29,30]. Virunga has a bimodal precipitation regime: a dry season (July to August) and a wet season (September to June); with a short dry-like period observed from mid-January to late-February. The mean monthly air temperature in the lowlands is ~20 °C with daily maxima of 32 °C, while in the highlands, the mean monthly temperature is ~10 °C with daily minima of 7 °C [29]. Hence, the dominant temperature fluctuation occurs in the daily temperatures rather than in monthly or yearly mean temperatures. The hydrography of Virunga consists of Lake Kivu (1460 m a.s.l.; evaporation rates ~1500 mm yr‒1), Lake Edward (912 m a.s.l.), several springs, and middle to large rivers (see compilation in [22,30]). At the regional scale, Virunga is located at the border between the Central and Eastern Africa regions, where a humid rainforest tropical climate predominates. The Virunga mountains influence the regional wind circulation, particularly those of the lower atmosphere. Virunga is part of the African Great Lake Region (Figure 1), where Lake Victoria, Lake Tanganyika, Lake Malawi, Lake Albert, etc., large rivers, and wetlands impact the East African regional climate and moisture production [30]. These lakes, large rivers and wetlands are subject to important evaporation. The region abounds in large dense forests that mainly consist of national parks. The majority of these tropical rain forests are wet and clouded all year long, and are, thus, important sources of moisture through evapotranspiration, principally during the rainy season.
The second set of samples was collected from Sicily and Stromboli islands in the Central Mediterranean. From a geological point of view, Sicily represents part of the south-verging branch of the Apenninic–Maghrebian orogenic belt made up of a pile of nappes derived from the deformation of different Meso-Cenozoic domains resulting from the collision of the African and Eurasian tectonic plates [31]. The climate is a typically Mediterranean one: characterized by hot summer droughts and winter rain in the mid-latitudes, north of the subtropical climate zone. In summer, the subtropical high-pressure cells drift toward the Northern Hemisphere (from May to August). This coincides with substantially higher temperatures than in winter and little rainfall [32,33]. During the winter, the high-pressure cells drift back toward the equator, and the weather is dominated by cyclonic storms [34]. At ground level, the mean monthly relative humidity is always higher than 70% and close to 80% during the rainy season. The Mediterranean Sea represents an important source of energy and moisture for cyclone development [33]. Several authors have provided detailed descriptions of climatic features and cyclogenesis in the Mediterranean, and have related them to orographic effects [35,36] and to large-scale circulation [37,38]. In addition, climate change is believed to be responsible for the increased intensity of cyclones over the Mediterranean Sea [39]. The hydrological cycle in the Mediterranean has been described by [40]. These authors have shown that evaporation from the Mediterranean Sea is greatest during the winter and in its eastern part. Climatic features and the soil types are responsible for the poor vegetation coverage of the studied area.

2.2. Sampling and Analytical Techniques

Rain samples were collected from rain gauges that consisted of a plastic funnel fixed on a plastic container; the latter was filled with approximately 250 cm3 of pure Vaseline oil to avoid evaporation. In Virunga, the samples were collected monthly from December 2013 to October 2015. After collecting the required aliquot for laboratory analysis and measuring the monthly precipitation amounts, the containers were washed with distilled water, and changed every 2–3 months during the study period. Water samples were filtered in the field through 0.45-mm-pore-size polysulfone syringe filters and stored at room temperature in 30-mL high-density polyethylene plastic bottles with double screwcaps. No additives were added to the samples. In the Mediterranean, rain samples were collected during different time periods. In Sicily, a rain gauge network was installed and sampled monthly in the period February 2002 to March 2003. Single rain events were also collected from one site of the network during the period October 2005 to September 2006. Rain samples at Stromboli Island, Italy, were collected between October 2003 and October 2005 on an approximately bimonthly basis. Additional rain samples were collected monthly in Sicily from May 2004 until June 2006, from a network of 50 rain gauges [32,33,41,42].
The majority of the samples from Virunga were analyzed for hydrogen and oxygen stable isotopes in the Isotope Hydrology Laboratory of the International Atomic Energy Agency (IAEA) in Vienna, Austria. The analyses were performed using an off-axis integrated cavity output laser spectroscopy (OA-ICOS), following the analytical procedure of [43]. Samples were first run in duplicate on a different day and instrument. Samples for which repeatability of the two runs was not within 2 times the typical uncertainty were repeated on a dual-inlet isotope ratio mass spectrometer (Isoprime DI 100) following equilibration with H2 or CO2 gases respectively [44]. A few of the samples from Virunga were analyzed at the Istituto Nazionale di Geofisica e Vulcanologia (INGV) in Palermo using Analytical Precision AP 2003 and Finnigan MAT Delta Plus spectrometers to analyze δ18O and δ2H, respectively [30]. The majority of the samples from the Mediterranean was analyzed at the Istituto Nazionale di Geofisica e Vulcanologia (INGV) in Palermo. Details on the analytical methods are described in [32,33,41,42].
The oxygen and hydrogen isotopic compositions of a sample are reported as the deviation of the isotopic ratio of the sample relative to that of an established reference material (standard), and calculated as following:
δ 18 O =   18 R sample   18 R standard   18 R standard   x   10 3   ( ) ,   and   δ 2 H =   2 R sample   2 R standard   2 R standard   x   10 3   ( )
where δ18O and δ2H represent, respectively, the oxygen and hydrogen isotope composition of the sample. R refers to the ratio between natural abundances of the rare to abundant isotopes of the element, which results in 18R = 18O/16O for oxygen and 2R = 2H/1H for hydrogen. Ocean water is the internationally established zero point of the delta notation for δ18O and δ2H of water [6,7], and is known as the Vienna-Standard Mean Ocean Water (V-SMOW). For both Virunga and Mediterranean, the d-excess was deduced from Dansgaard’s equation [8], relating the δ18O and δ2H of water, by the relationship d = δ2H-8δ18O. The typical uncertainty is reported as the long-term standard deviation of a dedicated control sample and is 0.08‰ for δ18O and 0.50‰ for δ2H.

3. Results and Discussion

3.1. General Variabilities

The isotopic composition of the precipitation of both regions has monthly values that are spread over a wide range (Table 1), particularly for δ2H (Figure 2), with Virunga showing the higher δ18O and δ2H values and the Central Mediterranean showing the most negative (Figure 2A). Thus, Virunga monthly values span from −32.53 to 58.89‰ for δ2H and −6.44 to 6.16‰ for δ18O (N = 223), and for the Central Mediterranean, from −74.20 to 18.00‰ for δ2H and −11.60 to 3.60‰ for 18O (N = 1272) (Table 1). As a general tendency for both regions, the higher δ values were obtained during the dry periods: the dry and warm season in Virunga and dry and hot summer months in the Central Mediterranean. These periods are characterized by very low precipitation, yielding the observed δ18O and δ2H enrichment. Furthermore, the most negative values were obtained during the heavy rainy season in Virunga and during the cold and wet winter period in the Central Mediterranean.
Strong positive correlations are observed between the δ18O and δ2H of precipitation when monthly values are used, and show Ordinary Least Squares Regression (OLSR) lines of δ2H = 7.60 δ18O + 16.18 (r2 = 0.96; p < 0.0001 and N = 223) for Virunga, and δ2H = 6.21 δ18O + 4.01 (r2 = 0.91; p < 0.0001 and N= 1272) for the Central Mediterranean. These lines are strongly influenced by extreme values that have higher δ18O than that of their corresponding Local Meteoric Water Lines (LMWL) in particular, and than that of the GMWL in general (Figure 2A). In such circumstances, precipitation-weighted values are commonly recommended for the calculation of the LMWL. These extreme values are typically the result of extreme weather conditions (e.g., at the peak of the dry or wet periods, or during thunderstorms) or due to secondary processes that may affect raindrops during their fall and that modify the isotopic composition of the pristine rainwater. This point is further discussed in Section 3.4. Hence, the mean precipitation-weighted values for the Central Mediterranean vary from −62.45 to −29.28‰ for δ2H and −10.47 to −5.45‰ for δ18O; and from −11.79 to 5.45‰ for δ2H and from −4.00 to −1.07‰ for δ18O in Virunga (Figure 2B). Thus, using the precipitation-weighted values, the equations for the LMWL are δ2H = 5.84 δ18O + 12.34 (r2 = 0.99; p < 0.0001; N = 13) for Virunga, and δ2H = 6.23 δ18O + 4.25 (r2 = 0.93; p < 0.0001; N = 67) for the Central Mediterranean. These equations are referred to as the Mean Local Meteoric Water Lines (MLMW), MVLMW for Virunga and MCMLWL for the Central Mediterranean (Figure 2B). The higher enrichment of Virunga precipitation clearly emerges when precipitation-weighted values are used (Figure 2B).

3.2. Spatiotemporal Variabilities of δ18O, δ2H and D-Excess

As mentioned in Section 3.1, clearly defined seasonal variations are observed for both δ2H and δ18O in the two regions (Figure 3), with higher values found during the dry seasons in Virunga (July and August, and during the short dry season of mid-January to mid-February (Figure 3A,B) and during the summer months in the Central Mediterranean (Figure 3B,D). Conversely, the most depleted δ values were obtained during the rainy season in Virunga (principally from October to December and March to June) and during the cold and rainy winter period in the Central Mediterranean. In Virunga, samples from the lower altitudes generally showed the enriched δ2H and δ18O values during the sampling period; this is responsible for the alignment observed in the mean data points shown in the δ2H versus δ18O chart in Figure 2B. Similar behaviors were observed in δ2H and δ18O data collected from the Central Mediterranean.
Therefore, strong negative relationships were found between both the mean precipitation-weighted δ2H and δ18O and the altitude, while, conversely, the deuterium excess showed a strong positive relationship with the altitude (Figure 4). Virunga shows slightly higher vertical oxygen (−0.15‰/100 m) and hydrogen (−0.86‰/100 m) gradients compared to the Central Mediterranean area, where the vertical oxygen and hydrogen gradients are −0.24‰/100 m and −1.00‰/100 m for Stromboli and −0.16‰/100 m and −1.07‰/100 m for Sicily. However, Stromboli showed the higher d-excess gradient of 0.89/100 m (Virunga has a value of 0.32/100 m), which is consistent with the fact that the d-excess gradient has an opposite trend to that of the vertical oxygen and hydrogen gradients. The oxygen and hydrogen gradients for the Central Mediterranean area consistent with those previously reported for Sicily (e.g., [45,46,47]).
The high vertical oxygen and hydrogen gradients for Virunga are because of the high slope at Mt Nyiragongo, along which part of the samples were collected. Hence, in Virunga, a difference in gradients is observed between samples collected from the lowland sites found below 2000 m a.s.l. and those from the highland ones found above this altitude (see further discussions in [29,30]). Both the oxygen and hydrogen gradients at highland sites are 2-fold higher in comparison to those of lowland sites; these high values increase the overall gradient for Virunga. This difference is also attributed to two other important parameters: (1) different moistures affect highland and lowland areas in Virunga, and (2) the effect of precipitation amounts as they greatly vary between the low and highland sites (further discussed in Section 3.4). In the Central Mediterranean area, particularly in Stromboli Island, the local topography does not allow to us evaluate for such an effect.

3.3. Meteorological Effects: Temperature and Precipitation Amount

The Virunga monthly air temperature means are nearly constant for a given station, and therefore show variations generally less than 2 °C at an annual time scale (Figure 5A,B), because the region is located close to the equator. However, significant air temperature differences are observed between mean monthly values from stations found at different altitudes (e.g., compare temperature values of Figure 5A,B), or during diurnal air temperature variations at a given station. At a regional scale, in the Central and Eastern African regions nearing Virunga, precipitation is principally formed from the condensation of continental recycled moisture. The dominant evaporating and evapotranspiring surfaces are found in local lowlands [30,48,49,50], and hence the surface air temperature at moisture source regions is comparable to that of the study area. Such a lack of spatiotemporal variation in the air temperature results in the noticed lack of dependency between δ18O and the air temperature in Virunga (Figure 5A,B), and is the common trend found in tropical regions [3,51,52].
Virunga monthly δ18O, δ2H and d-excess show weak correlation with monthly precipitation amounts (R2 varies from 0.11 to 0.32 for δ18O; 0.13 to 0.34 for δ2H and 0.00 to 0.45 for d-excess). Particularly, the δ18O dependency averages 2.96 ‰/100 mm of monthly precipitation, but ranges from 2.10 to 4.51 ‰/100 mm. A combination of monthly precipitation amounts, and the altitudes show that the δ18O precipitation amounts dependency is higher in lowlands, which was likely favored by the influence from the heavier water vapor from the neighboring Lake Kivu [30]. The δ18O, δ2H and d-excess relationships with monthly precipitation amounts show higher correlations when mean precipitation-weighted and the average annual precipitation values are plotted, and give an R2 of 0.58 for δ18O (Figure 6A), 0.49 for δ2H (Figure 6B) and 0.76 for d-excess (Figure 6C).
In the Central Mediterranean, monthly air temperature averages show a clear seasonality with the lower values in winter and high values in summer (Figure 6C,D). In addition, significant air temperature differences are observed between mean monthly values from stations at different altitudes with diurnal air temperature variations. The Central Mediterranean monthly δ18O, δ2H and d-excess show weak correlation with monthly precipitation amounts. The δ18O, δ2H and d-excess relationships with precipitation amounts show higher correlations when mean precipitation-weighted and the average annual precipitation values are plotted, and give anR2 of 0.40, 0.87 and 0.85 for δ18O, δ2H and d-excess, respectively.

3.4. Precipitation Stable Isotope Fractionation in Virunga and in the Central Mediterranean

3.4.1. Stable Isotope Fractionation in Virunga

Virunga LMWL has a higher intercept compared to the GMWL, and it shows a slope comparable to that of the GMWL (Figure 2A) and that from other Central African regions (e.g., [12,53,54,55]. Such a slope suggests processes of rain formation under equilibrium conditions at the regional scale. In addition, the intercept indicates that Virunga precipitation originates from high-altitude recycled continental moisture [15,56]. The high d-excess values of precipitation are the consequence of vapor formation under non-equilibrium conditions at source, favored by both low RH and strong winds. A difference of ~10‰ in the d-excess values is observed when comparing lowland to highland areas of Virunga, and is caused by the kinetic fractionation during vapor formation and moisture transportation, and by the difference in the composition of the moistures arriving in the low and highlands.
A secondary process additionally affects the raindrops during their fall as they pass through the water vapor in the lower atmosphere [30]. In fact, the pristine falling raindrops interact with the isotopically-enriched water vapor present in the lower atmosphere, the vapor coming mostly from Lake Kivu. This lake has isotopically enriched surface waters, showing values up to 27.76‰ and 3.68‰ for δ2H and δ18O, respectively [30]. The lower atmosphere in the study area is, thus, saturated in isotopically enriched water vapor when considering the recorded high RH (monthly values range: ~70 to 90%). According to [57], such high RH favors equilibrium between the falling raindrops and the water vapor, a process that likely contributes to the δ2H and δ18O enrichment of Virunga lowland precipitation. Therefore, Virunga highlands receive only precipitation from the upper atmosphere produced from remote moisture sources, whereas the lowland areas are additionally affected by local water vapor that mediates the enrichment of the falling raindrops.
The moisture source regions for Virunga abound in small to large open surface waters, the surface waters of the lakes are particularly isotopically enriched (e.g., [30,58,59,60,61,62,63,64,65]). The enrichment of their surface waters in the heavy isotopes is due to the intense evaporation process that in some cases exceeds the precipitation they receive over their surfaces. These lakes represent the predominant source of water vapor for the atmosphere during the dry periods, while during the rainy season the soil/plants evapotranspiration is the major source (further discussed in [30]). Because the plants-transpired vapor tends to be isotopically similar to the liquid water drawn into its roots (e.g., [66,67]), there are few variations in the δ2H and δ18O during the rainy season when considering the abundant neighboring tropical forest and other isolated plants. Thus, the precipitation from the rainy season is isotopically depleted because it is derived from the condensation of vapor from (1) freshly precipitated rain, (2) plants-transpired vapor and (3) because of the high precipitation amount. Conversely, during the dry season, the residual soil-water that is then evaporating will be composed of heavier isotopes, and this vapor mixes with the permanently enriched vapor from the lakes and, thus, yields enriched precipitation.
The changes in wind direction also influence the precipitation δ2H and δ18O, as it brings moisture from different sources. In fact, the equatorial East African region experiences three major air streams: the northeast monsoon system, the southeast monsoon system from the Indian Ocean, and the southwesterly humid air from the Congo basin [68]. The NE, E and SE winds bring moisture evaporated from Lake Edward, Lake Albert and Lake Victoria surface waters, in addition to that evapotranspired in their moderately to densely forested catchments. Conversely, the S and SW winds carry moisture evapotranspired in the Tanganyika-Kivu basins, especially that from the neighboring Lake Kivu. Once in the study area, the NE, E and SE winds principally occupy the upper atmosphere as they originate from outside the rift, while the S and SW follow the low-lying channel of the rift and are consequently maintained in the lower atmosphere. Thus, the NE and E originating high-speed air mass moves upward as a result of topography changes and might yield orographic lifting at Virunga Mountains. The moisture they bring principally influences the δ2H and δ18O of the precipitation of highland sites, whereas the S and SW low-level moisture additionally influences that of lowland sites. The high speeds of the NE and E-SE winds yield the earlier discussed kinetic fractionation that lead to the higher d-excess values that characterize the precipitation of highland sites. Conversely, the S and SW winds in the lower atmosphere are less strong and favor a relatively equilibrium fractionation in conjunction with the high RH prevalent in lowland areas. Because of the topographic constraints of the rift structure and the prevailing weak winds, this S to SW originating moisture is essentially permanent in the lower atmosphere and drives the earlier noted isotopic enrichment of the falling rain drops.

3.4.2. Stable Isotope Fractionation in the Central Mediterranean

At a regional scale, in the Central Mediterranean, precipitation is principally formed from the condensation maritime vapor forming over the Atlantic Ocean as well as from the Mediterranean Sea [32,33]. The Mediterranean Sea is a classic example of a reservoir producing water vapor characterized by high deuterium excess [13,16]. Such an effect depends on kinetic fractionation occurring when dry air masses travel over the sea surface. This effect coupled with the kinetic condensation of local orographic clouds, forming on significant topographic features such as hills and mountains, is responsible for the high deuterium excess found in rain samples from mountains in the Central Mediterranean. The high seasonal variation in d-excess between summer and winter reflects the climatic features and circulation patterns of the Central Mediterranean. In fact, when cold air masses, characterized by low relative humidity, travel over seawater, kinetic fractionation produces high deuterium excess values in the vapor, whereas the movement of warm air masses, usually characterized by high relative humidity, leads to lower deuterium excess values [33]. At Stromboli Island, the production of volcanic aerosol close to the craters favors the non-equilibrium condensation of water droplets. Under these conditions, the diffusional growth of hydrometeors could cause a great deuterium excess as a result of the higher diffusivity of HD16O compared to that of H218O [69]. Therefore, the coalescence of raindrops and haze droplets in the orographic cloud generates the increase in the deuterium excess values in the rain. Consequently, the composition of the precipitation is not changed directly by volcanic activity. Nevertheless, the production of volcanic aerosols could indirectly enhance deuterium excess in rain near the craters.

4. Conclusions

Virunga precipitation originates from high-altitude recycled continental moisture. The slope of the LMWL further reveals that during the condensation, rainwater forms under equilibrium, conditions as is the case for central Africa forest regions, whereas the higher intercept and the δ18O values are closer to those from the East Africa region. Even though Virunga is generally a high-altitude region, a clear shift is observed between the isotope composition of the precipitation from the local lowland and highland sites, which is topographically driven. In fact, the lowland sites are characterized by higher δ2H and δ18O and lower d-excess values, while the highland areas have lower δ2H and δ18O and higher d-excess. The values δ2H, δ18O and d-excess at low- and highland areas are in line with the weather patterns such as the temperature (temperature is lower at highland and higher at lowland areas), wind speed and direction (high speed and of well-defined direction at highland, calm and generally lacking of unique-direction at lowland) or precipitation (higher and lower precipitation at highland and lowland areas, respectively). The monthly δ2H and δ18O showed a well-defined seasonality, with the heavier δ2H and δ18O obtained during the dry periods and the lighter, in the wet periods, with strong correlation to precipitation amount. The vapor from the East African Great Lakes has a strong influence on the isotopic composition of Virunga precipitation, particularly during the dry season, while in the rainy season, the precipitation is mainly formed from soil/plants evapotranspiration. No δ18O dependency on air temperature was observed as is generally the case for tropical regions, while the δ18O and δ2H are negatively correlated to precipitation amounts.
In the Central Mediterranean, the isotopic composition of precipitation clearly reflects the origin of the vapor feeding the raindrops. The climatic and morphological features of the Mediterranean represent a unique natural environment where air masses, mainly coming from the Atlantic Ocean, travel over the Mediterranean Sea and produce rain events from the condensation of water with different proportions of vapor from different areas. In addition, local orographic clouds induce a kinetic condensation process. With respect to Virunga, precipitation occurring in the Central Mediterranean does not show any clear contribution from the re-evaporated air masses, because of the poor vegetation cover and the regional air circulation systems.
The marked differences of the isotopic composition of precipitation in Virunga and in the Central Mediterranean reflect very different climatic and morphological features, where several fractionation processes and vapor sources play dissimilar roles. This study, thus, represents a key paper for researchers dealing with this topic.

Author Contributions

C.M.B. and M.L. drafted the manuscript, which they had latter amended and approved.

Funding

This research received no external funding and “the APC was funded by the Istituto Nazionale di Geofisica e Vulcanolgia - Sezione di Palermo.

Acknowledgments

Virunga water samples were analyzed in the isotope hydrology laboratory of the International Atomic Energy Agency (IAEA) within the framework of the Global Network of Isotopes in Precipitation. A few other samples from Virunga were analyzed at INGV-Palermo, where all the samples from Sicily and Stromboli were analyzed. The authors acknowledge insightful comments from Wendy McCausland (U.S. Geological Survey), and comments and recommendations from two anonymous reviewers who improved the manuscript; and the editorial handling of Autumn Du.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Topographic map of Virunga (A) located on the limit between Central and Eastern Africa, within the western branch of the East African Rift System (see insert map of A); Stromboli (B1) and Sicily (B2) (Italy) in the Central Mediterranean. In Virunga, the sampling sites are situated in the north basin of Lake Kivu and on Mt Nyiragongo (3470 m a.s.l.). On the map (A), Mt Nyamulagira (3058 m a.s.l), Mt Mikeno (Mi, 4437 m a.s.l), Mt Karisimbi (K, 4508 m a.s.l), Mt Visoke (V, 3911 m a.s.l), Mt Sabinyo (S, 3647 m a.s.l), Mt Gahinga (G, 3474 m a.s.l), and Mt Muhabura (Mu, 4127 m a.s.l) are also shown. The sampling sites were designed in order to capture any spatial and altitudinal variations of the stable isotope composition of oxygen and deuterium in precipitation.
Figure 1. Topographic map of Virunga (A) located on the limit between Central and Eastern Africa, within the western branch of the East African Rift System (see insert map of A); Stromboli (B1) and Sicily (B2) (Italy) in the Central Mediterranean. In Virunga, the sampling sites are situated in the north basin of Lake Kivu and on Mt Nyiragongo (3470 m a.s.l.). On the map (A), Mt Nyamulagira (3058 m a.s.l), Mt Mikeno (Mi, 4437 m a.s.l), Mt Karisimbi (K, 4508 m a.s.l), Mt Visoke (V, 3911 m a.s.l), Mt Sabinyo (S, 3647 m a.s.l), Mt Gahinga (G, 3474 m a.s.l), and Mt Muhabura (Mu, 4127 m a.s.l) are also shown. The sampling sites were designed in order to capture any spatial and altitudinal variations of the stable isotope composition of oxygen and deuterium in precipitation.
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Figure 2. Relationship between δ2H and δ18O in monthly rainwater from the Virunga region, located on the limit between Central and Eastern Africa, within the western branch of the East African Rift System, and the Central Mediterranean (Stromboli and Sicily Islands, Italy). In (A) and (B), EMMWL refers to the Eastern Mediterranean Meteoric Water Line after Gat and Carmi [13], and GMWL to the Global Meteoric Water Line after Craig [6]. In (A) the Virunga Local Meteoric Water Line (VLMW), and the Central Mediterranean Local Meteoric Water Line (CMLWL) are plotted; both lines were obtained using monthly values. In (B), the Mean Virunga Local Meteoric Water Line (MVLMWL) and Mean Central Mediterranean Local Meteoric Water Line (CMLWL) are plotted, and both were obtained using mean precipitation-weighted values.
Figure 2. Relationship between δ2H and δ18O in monthly rainwater from the Virunga region, located on the limit between Central and Eastern Africa, within the western branch of the East African Rift System, and the Central Mediterranean (Stromboli and Sicily Islands, Italy). In (A) and (B), EMMWL refers to the Eastern Mediterranean Meteoric Water Line after Gat and Carmi [13], and GMWL to the Global Meteoric Water Line after Craig [6]. In (A) the Virunga Local Meteoric Water Line (VLMW), and the Central Mediterranean Local Meteoric Water Line (CMLWL) are plotted; both lines were obtained using monthly values. In (B), the Mean Virunga Local Meteoric Water Line (MVLMWL) and Mean Central Mediterranean Local Meteoric Water Line (CMLWL) are plotted, and both were obtained using mean precipitation-weighted values.
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Figure 3. Temporal variation of δ2H, δ18O and d-excess in monthly precipitation in Virunga (A,B), located on the limit between Central and Eastern Africa, within the western branch of the East African Rift System, and in the Central Mediterranean (C,D), Sicily in sourthern Italy.
Figure 3. Temporal variation of δ2H, δ18O and d-excess in monthly precipitation in Virunga (A,B), located on the limit between Central and Eastern Africa, within the western branch of the East African Rift System, and in the Central Mediterranean (C,D), Sicily in sourthern Italy.
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Figure 4. Mean precipitation-weighted δ2H, δ18O and d-excess values plotted against altitude in Virunga, (AC) located on the limit between Central and Eastern Africa, within the western branch of the East African Rift System, and southern Italy (DF) in the Central Mediterranean (data are from Stromboli and Sicily).
Figure 4. Mean precipitation-weighted δ2H, δ18O and d-excess values plotted against altitude in Virunga, (AC) located on the limit between Central and Eastern Africa, within the western branch of the East African Rift System, and southern Italy (DF) in the Central Mediterranean (data are from Stromboli and Sicily).
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Figure 5. δ18O monthly values from isolated stations plotted against temperature in Virunga, located on the limit between Central and Eastern Africa, within the western branch of the East African Rift System (A,B), and the Central Mediterranean (C,D). In Virunga, the data used in A and B are respectively from the OVG (1535 m a.s.l.) and summit (3460 m a.s.l.) stations (see map of Figure 1A), while in the Central Mediterranean the data used in C are from a station in the Spagnuola area (see map of Figure 1B2) and data for D are from the LBR station in Stromboli (see map of Figure 1B1). No clear relationships can be recognized between isotope composition and temperature.
Figure 5. δ18O monthly values from isolated stations plotted against temperature in Virunga, located on the limit between Central and Eastern Africa, within the western branch of the East African Rift System (A,B), and the Central Mediterranean (C,D). In Virunga, the data used in A and B are respectively from the OVG (1535 m a.s.l.) and summit (3460 m a.s.l.) stations (see map of Figure 1A), while in the Central Mediterranean the data used in C are from a station in the Spagnuola area (see map of Figure 1B2) and data for D are from the LBR station in Stromboli (see map of Figure 1B1). No clear relationships can be recognized between isotope composition and temperature.
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Figure 6. Mean precipitation-weighted δ18O, δ2H and d-excess values plotted against averaged annual precipitation in Virunga, located on the limit between Central and Eastern Africa, within the western branch of the East African Rift System (AC), and southern Italy (DF) in the Central Mediterranean (data are from Stromboli and Sicily). The two areas exhibit a different extent in the negative correlation between the isotope composition against the precipitation amount (A,B,D,E), and in the positive correlation between deuterium excess against the precipitation amount (C,F).
Figure 6. Mean precipitation-weighted δ18O, δ2H and d-excess values plotted against averaged annual precipitation in Virunga, located on the limit between Central and Eastern Africa, within the western branch of the East African Rift System (AC), and southern Italy (DF) in the Central Mediterranean (data are from Stromboli and Sicily). The two areas exhibit a different extent in the negative correlation between the isotope composition against the precipitation amount (A,B,D,E), and in the positive correlation between deuterium excess against the precipitation amount (C,F).
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Table
Table 1. Sampling sites elevation (meter, m), monthly min, average and max δ2H, δ18O and deuterium excess (per mil) of rainwater collected on a monthly basis in Central Mediterranean (Stromboli and Sicily, Italy) and in Central-Eastern Africa (at Mount Nyiragongo and the surroundings, Democratic Republic of the Congo).
Table 1. Sampling sites elevation (meter, m), monthly min, average and max δ2H, δ18O and deuterium excess (per mil) of rainwater collected on a monthly basis in Central Mediterranean (Stromboli and Sicily, Italy) and in Central-Eastern Africa (at Mount Nyiragongo and the surroundings, Democratic Republic of the Congo).
Site NameElevation (m a.s.l.)UTM CoordinatesPrecipitation (mm/month)δ2H (‰)δ18O (‰)d−excess (‰)Number of SamplesSapling PeriodeRegion
EastingNorthingMinAverageMaxMinAverageMaxMinAverageMaxMinAverageMax
FRT28251980442944492.829054112.1399219.959−48−30.5455−3−8.4−5.90455−2.1511.616.6909120.8112003–2005Stromboli (Italy), Central Mediterranean
GNV552089042946992.121791107.099234.1043−49−28.2727−6−7.9−5.17273−1.5613.1090916.6112003–2005Stromboli (Italy), Central Mediterranean
LBR12151874342956813.88995101.3573196.2656−46−28.9091−3−7.9−5.37273−1.710.614.0727319112003–2005Stromboli (Italy), Central Mediterranean
PSF 1881518695429386566.48278115.9677211.4718−48−41.8333−35−8.7−7.71667−6.81619.921.862003–2005Stromboli (Italy), Central Mediterranean
PSF 2900518600429372461.95629126.2466170.4505−51−44.1667−34−9.4−8.26667−6.820.221.9666725.262003–2005Stromboli (Italy), Central Mediterranean
TMP13051670842936382.82905466.90714145.4134−48−28.1111−8−8−5.24444−2.29.413.844441892003–2005Stromboli (Italy), Central Mediterranean
S. Ninfa47031360041829004.95084553.44892141.1698−74.2−30.67694.8−11.4−5.623081.4−6.413.2857123.2142002–2003Palermo (Italy), Central Mediterranean
Triscina1330600041620008.48716349.21039154.4664−67.7−264.3−10.1−4.435710.6−0.59.48571416.1142002–2003Palermo (Italy), Central Mediterranean
Spagnuola1527820041905002.82905446.33587118.3959−62.1−29.1846−10.8−9.4−5.1−2.84.111.6153820.1142002–2003Palermo (Italy), Central Mediterranean
Trapati1228392542124004.24358238.46504113.4451−58−29.29292.8−8.7−5.07857−1.11.811.3357120.1142002–2003Palermo (Italy), Central Mediterranean
Sparagio110030490042145504.24358277.05132193.2244−63−40.1429−18.3−10.2−7.18571−4.5317.3428624.1142002–2003Palermo (Italy), Central Mediterranean
Linici98031200042087757.779976.11167187.2834−64.9−42.6857−23.5−10.6−7.47143−5.47.817.0857121.8142002–2003Palermo (Italy), Central Mediterranean
M. Grande67530205041963005.94101445.85089135.7946−72.2−33.5929−10.4−11.6−6.04286−3.7614.7521.1142002–2003Palermo (Italy), Central Mediterranean
Calatafimi40031282541977507.35554157.77333147.6766−62.3−33.8786−16.4−9.7−5.99286−4.15.914.0642921142002–2003Palermo (Italy), Central Mediterranean
San Vito1530155042280005.65810943.9373999.58271−55−33.0077−4.9−8.5−5.45385−2.2110.6230817.4132002–2003Palermo (Italy), Central Mediterranean
Scopello6031207542133253.53631859.97595152.7689−56.2−32.1−12.1−8.5−5.40833−2.93.511.1666718.4122002–2003Palermo (Italy), Central Mediterranean
INGV−Palermo85351950422570010.3260552.01108127.0245−60−35.7154−22.1−8.8−5.82308−40.510.8692318132002–2003Palermo (Italy), Central Mediterranean
Calatafimi39931279541990588.34679370.1107239.369−53−31.29177−9.16−5.73140.62.214.5595425.28242004–2006Palermo (Italy), Central Mediterranean
Santa Ninfa470313611418279011.3176872.60233252.9503−60−30.52176−9.95−5.658870.46−2.3214.7492124.6222004–2006Palermo (Italy), Central Mediterranean
Triscina730543941619521.41471163.32438263.7021−63−25.2273−2−9.37−4.68546−0.825924.45171312.256419.44222004–2006Palermo (Italy), Central Mediterranean
Spagnuola527809241905205.94178555.0876209.6601−52−26.56524−8.43−4.87347−0.38−6.7612.4225420.84222004–2006Palermo (Italy), Central Mediterranean
S. Vito830159742279946.50766959.78921200.1816−53−28.04173−9.07−5.136610.190.4813.0512120.56222004–2006Palermo (Italy), Central Mediterranean
M.te Sparagio111330491042145149.90297466.57462254.9309−55−29.1176−2−9.58−5.64497−0.75416.0421226.92172004–2006Palermo (Italy), Central Mediterranean
Palazzo Adriano68235753441719893.39530596.86052374.3324−60−35.33330−10.1−6.14078−1−18.7613.792922.8242004–2006Palermo (Italy), Central Mediterranean
Cefalù200417515420719010.1859277.16603169.1994−56−35−6−9.3−5.89516−1.42−13.3612.1613225.08222004–2006Palermo (Italy), Central Mediterranean
Milena444438850541482468.48826463.20066180.5171−62−33.6522−10−9.86−5.86296−1.37068−0.4413.2515223.92232004–2006Palermo (Italy), Central Mediterranean
Lucca Sicula53135056741604438.48826493.67956282.0933−64−34.0909−10−10.82−6.17144−2.651.0415.2806423.36222004–2006Palermo (Italy), Central Mediterranean
Biviere di Gela1544134040983351.83912451.41653161.5098−46−24.72220−7.38−4.355560.01−8.610.1222219.6182004–2006Palermo (Italy), Central Mediterranean
Sant’Agata di Militello1846797342139448.48826464.76427136.3781−52−31.16679−8.63−5.581331.16−0.5613.4839421.56242004–2006Palermo (Italy), Central Mediterranean
Capo Calavà23649484642240859.90297483.32056227.2025−53−33.5417−12−8.93−5.98902−2.3−9.614.3705126.44242004–2006Palermo (Italy), Central Mediterranean
S. Basilio737480777420773934.236108.2069272.7562−70−41.6957−23−10.24−7.16729−3.85−3.215.6426922.48242004–2006Palermo (Italy), Central Mediterranean
S. Stefano di Camastra10244287142080315.09295864.78759142.8858−56−31.6087−2−8.78−5.6577−0.13728−0.9017513.6528721.08242004–2006Palermo (Italy), Central Mediterranean
M.te Soro1853473236419843527.72833133.9289424.4132−53−41.6875−16−9.44−7.66438−3.9615.1619.627525.6162004–2006Palermo (Italy), Central Mediterranean
Alcara Li Fusi391473815420840122.3524397.96228218.1484−61−36.6818−9−9.22−6.56375−2.938.615.8281522.64222004–2006Palermo (Italy), Central Mediterranean
Cesarò111247437841888516.22472769.09939162.6917−70−40.04356−11−7.155080.392.8817.1971224.56232004–2006Palermo (Italy), Central Mediterranean
Novara di Sicilia62051143442077784.24413297.56787336.7011−61−32.3333−7−9.75−5.89777−1.388423.70568114.8488524.12242004–2006Palermo (Italy), Central Mediterranean
Villa Miraglia1525469777419680127.16244169.9318526.7516−67−43.88−14−10.52−7.7932−3.959.418.465627.36232004–2006Palermo (Italy), Central Mediterranean
Agrigento2973787954132044062.98157242.7643−58−31.0952−2−9−5.53821−0.398441.18755713.2104421.96232004–2006Palermo (Italy), Central Mediterranean
INGV−Palermo9035198942255466.50766971.02462159.2964−57−30.95658−8.99−5.440791.25−212.5698122.96212004–2006Palermo (Italy), Central Mediterranean
Alì Terme2253711342063222.82942179.69536219.846−58−28.5238−7−8.24−5.01734−0.39243−3.8605611.614919.96212004–2006Palermo (Italy), Central Mediterranean
Capo Peloro21557072423596612.1665160.17236123.3628−56−29.09520−8.6−5.43903−1.23379.1614.4170127.4212004–2006Palermo (Italy), Central Mediterranean
Termini Imerese7838511842049713.25383448.86141121.3822−66−32.14290−10.1−5.61231−0.180711.4456912.7556122.68212004–2006Palermo (Italy), Central Mediterranean
Cerasella117542147141852356.79061161.26876204.2842−61−37.0417−14−10.41−6.85633−3.2810.0417.80924.2242004–2006Palermo (Italy), Central Mediterranean
Giacalone402346427421284216.26917119.6306346.6041−54−34.3819−9.28−6.03311.33−1.6413.8838123.2212004–2006Palermo (Italy), Central Mediterranean
San Cono48544615241253442.40500873.8286207.9625−53−31.7727−11−8.96−6.05175−2.540789.32623416.6412621.72212004–2006Palermo (Italy), Central Mediterranean
Ramacca28547314941377643.11236366.7676307.1337−69−29.42863−10.72−5.66524−0.436.4415.8933327.12212004–2006Palermo (Italy), Central Mediterranean
Alpe Cucco95036025741926984.24413286.2384254.082−62−37.3759−9.91−6.844580.832.3617.3816725.76242004–2006Palermo (Italy), Central Mediterranean
Assoro38944934141613039.62003277.37722314.2072−52−30.8333−14−8.58−5.68556−2.492.9214.6511123.72192004–2006Palermo (Italy), Central Mediterranean
Ist. Radioastr. Noto10049910040813572.97089268.39483228.9002−48−26−11−8.04−5.01762−2.686.3614.1409522.4222004–2006Palermo (Italy), Central Mediterranean
Alia66338648741818339.3370966.96297159.2964−62−36.14290−10.01−6.52286−0.413.2816.0423.84212004–2006Palermo (Italy), Central Mediterranean
Mussomeli51638937341584186.79061161.97719158.7305−59−34.0909−3−9.84−6.14227−1.236.8415.0472723.84212004–2006Palermo (Italy), Central Mediterranean
Montagna del Vento76733569341625234.24413296.79315280.9615−63−38.7778−17−10.25−6.92389−3716.6133322.2182004–2006Palermo (Italy), Central Mediterranean
Zafferana71550849641719029.195619136.6257342.36−51−22.31580−8.47−4.69947−1.663.6415.2824192004–2006Palermo (Italy), Central Mediterranean
Catania20050641141537264.24413273.00651232.0125−44−25.57141−7.25−4.86929−0.64613.3828620.8142004–2006Palermo (Italy), Central Mediterranean
Acqua Rossa35549477741537264.95148767.23917249.1305−47−24.6875−1−7.79−4.6875−1.534.8812.812519.6162004–2006Palermo (Italy), Central Mediterranean
Intraleo15104923494175399092.30397364.288−65−37.753−10.52−6.72−0.411.8816.0122.96192004–2006Palermo (Italy), Central Mediterranean
Pizzi de Neri281050151241800524.95148774.34304392.5822−59−44.6923−20−9.71−7.99692−4.9215.8819.2830825.08132004–2006Palermo (Italy), Central Mediterranean
Torre del Filosofo2940500106417673413.4397558.82838198.0595−64−44.4167−28−10.84−8.0725−5.6515.7620.1633323.6122004–2006Palermo (Italy), Central Mediterranean
Provenzana180050322441831403.536777125.1274396.119−59−38.1053−4−9.89−6.74105−2.6112.1215.8231621.12192004–2006Palermo (Italy), Central Mediterranean
Serra la Nave172549790641719347.780908102.3147361.1756−63−35.1905−1−10.08−6.50714−0.682.4416.8666728.16202004–2006Palermo (Italy), Central Mediterranean
Scordia15848584741275556.22472773.70642337.4085−57−29.5455−5−9.22−5.36727−1.67413.3927323.36222004–2006Palermo (Italy), Central Mediterranean
Monte Lauro98048414041080245.375989.63114295.816−56−33.3913−9−9.43−6.32565−2.675.3617.2139127.6232004–2006Palermo (Italy), Central Mediterranean
Sortino44550220241149579.62003291.96293381.9719−67−28.381−6−10.58−5.57095−1.986.416.1866725.84212004–2006Palermo (Italy), Central Mediterranean
Ragusa53547598440861056.50766969.10524227.344−50−32.35−16−8.79−6.051−2.5416.05825.08202004–2006Palermo (Italy), Central Mediterranean
Marina di Ragusa546031740714086.22472768.12303251.8185−45−29.0714−13−7.18−5.31643−2.342.7213.4621.28142004–2006Palermo (Italy), Central Mediterranean
Siracusa1552421941064035.80031366.54641257.4773−42−28.0588−6−7.12−5.20059−1.83−22.413.5458821.72172004–2006Palermo (Italy), Central Mediterranean
Licata5240544241066110.56588475.85345271.9074−48−26.71432−7.53−5.087141.1−6.813.9828621142004–2006Palermo (Italy), Central Mediterranean
Bweremana1470724496.598137279.866716110.7962218.1063−12.2210.8447858.89−3.42−0.271875.981−3.58213.0197420.2232013–2015Virunga (RD Congo), Central−Eastern Africa
Sake1514728715.698266784.258267107.4899206.474−18.18.95347841.74−4.151−0.806044.0375.54415.4018319.69232013–2015Virunga (RD Congo), Central−Eastern Africa
Kingi1848730385.9983549814.12498139.4496283.1228−17.913.30111129.46−4.215−1.618061.4413.41816.2455619.198182013–2015Virunga (RD Congo), Central−Eastern Africa
Buhimba1468739267.898193035.712309119.8702223.6109−21.477.09937.44−4.74−1.17422.4411.1116.492620.49202013–2015Virunga (RD Congo), Central−Eastern Africa
OVG1535747783.898139277.270212104.513214.7828−17.734.53857132.87−3.989−1.375572.516.4715.5431420.37212013–2015Virunga (RD Congo), Central−Eastern Africa
Kanyaruchinya175975092898214947.477932139.3237320.3047−18.478.91318256.02−4.604−0.885686.166.7415.9986422.03222013–2015Virunga (RD Congo), Central−Eastern Africa
Kibati1994753477.198264305.400729143.7377263.8048−23.75.28727334.11−4.869−1.414641.85611.2416.6043619.48222013–2015Virunga (RD Congo), Central−Eastern Africa
Rest 12254752329.4982844912.04778194.1072372.4425−24.614.41357146.8−4.914−1.625933.6614.69417.42120.816142013–2015Virunga (RD Congo), Central−Eastern Africa
Rest 22535751531.9982912415.3713188.3133376.597−25.840.89928641.5−5.416−2.188072.4915.92218.4038621.58142013–2015Virunga (RD Congo), Central−Eastern Africa
Shaheru2761750846.7982963153.1764176.3632339.2073−27.272.992539.75−5.657−2.011082.5317.4119.0811720.862122013–2015Virunga (RD Congo), Central−Eastern Africa
Biraro2918750760.4983014535.7279194.3483357.279−30.54−2.0234.51−5.989−2.759581.6617.37220.0566721.834122013–2015Virunga (RD Congo), Central−Eastern Africa
Cabanes3230750386.9983066347.9834177.0123338.9996−32.3−3.727529.08−6.358−3.013420.9518.56420.3798323.476122013–2015Virunga (RD Congo), Central−Eastern Africa
Summit3460749852983119723.26468174.5993274.3986−32.53−7.19232.64−6.435−3.49711.2818.7420.784822.918102013–2015Virunga (RD Congo), Central−Eastern Africa

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MDPI and ACS Style

Balagizi, C.M.; Liotta, M. Key Factors of Precipitation Stable Isotope Fractionation in Central-Eastern Africa and Central Mediterranean. Geosciences 2019, 9, 337. https://doi.org/10.3390/geosciences9080337

AMA Style

Balagizi CM, Liotta M. Key Factors of Precipitation Stable Isotope Fractionation in Central-Eastern Africa and Central Mediterranean. Geosciences. 2019; 9(8):337. https://doi.org/10.3390/geosciences9080337

Chicago/Turabian Style

Balagizi, Charles M., and Marcello Liotta. 2019. "Key Factors of Precipitation Stable Isotope Fractionation in Central-Eastern Africa and Central Mediterranean" Geosciences 9, no. 8: 337. https://doi.org/10.3390/geosciences9080337

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