Chemical weathering intensity and rare earth elements release from a chlorite schist profile in a humid tropical area, Bengbis, Southern Cameroon

An in situ weathering profile overlying chlorite schists in southern Cameroon was chosen to quantify chemical weathering intensity and to study the behaviour of rare earth elements (REE). Mafic index alteration values combined with the ternary diagrams of the Al – Fe – Mg – Ca – Na – K system show that the hydrolysis of feldspars is proportional to that of mafic minerals (losses in Mg), although the hydrolysis of the plagioclases (Ca, Na) is more intense than that of ferromagnesian minerals. The studied materials are localised in the domain of kaolinitisation, except for nodular materials which are slightly lateritised. The change in the behaviour of Mg in the weathering environment is expressed by the low values in Ca/Mg ratio. Potassium and Be are leached in the soil in association with Mg. The order of mobility of the elements in the weathering environment is: Ca Na > Fe Sr > Mg Co > Mn > Li > Ba > Rb > P > Cd > Ni > Si > Be > K > Sn. The enrichments in K, Cs and Be in saprolites are linked to the presence of illite. Cesium accumulation in the soil is due to the presence of kaolinite. The most stable system is: Hf – Nb – W – U. Saprolites, nodular and loose clayey materials are depleted in REE relative to the parent rock. REE exhibit three types of behaviour along the Bengbis profile like indicated by (La/Yb) N ratio values ((La/Yb) N < 1, (La/Yb) N ~ 1 and (La/Yb) N > 1). Light REE and Middle REE accumulate in the weathering materials for pH values ranging between 5.5 and 5.6 and for those of Eh varying between +60 and +70mV. The order of mobility of REE in these horizons is: Middle REE > Heavy REE Light REE. This fact is counter-intuitive, because Heavy REE are more mobile in supergene environment than Light REE. Adsorption or co-precipitation of LREE onto Fe oxides mainly may control the concentration of these elements in the profile. Weak Ce anomalies in the weathering materials of Bengbis area, due to the change in Ce to Ce, are probably due to the presence of low amounts in rhabdophane. The studied weathering materials show a fractionation in Gd (Gd/Gd* ~0.70 – 0.84) due to intense chemical leaching. This fact has been rarely reported in lateritic weathering environment. It appears that, a part of Gd distribution and remobilization is controlled by mafic minerals in the studied weathered materials. REE distribution and mobilization are thus controlled by (1) adsorption or co-precipitation in mafic and Fe minerals, (2) and slightly by REE-bearing minerals such as rhabdophane found in the studied weathering profile.


Introduction
Lateritic materials are heterogeneous due the nature of the parent rock, climate, biology (vegetation and fauna) and topography (Tardy, 1993). This heterogeneity makes the understanding of the mechanisms of their genesis and their supergene evolution relatively complex. This led scientists to use diverse approaches, mineralogical, thermodynamic and kinetic, mass balance and restructuring methods to quantify processes that take place during weathering. Apart from mass balance and restructuring methods, numerous chemical weathering indices are also used in the geochemical approach. However, these indices have many limitations. For example, the use of chemical index of alteration (CIA) of , and 1989 presents the disadvantage of not taking into consideration the redox dependent behaviour of iron. In addition, CIA is inefficient in the study of most advanced weathering materials. New weathering indices (Mafic index of alteration (MIA) and, Index of lateritisation (IOL)) by Babechuk et al. (2014) enable the quantification of the behaviour of mafic minerals in the study of rock weathering processes. Moreover, it has been shown that, the knowledge of the behaviour of trace elements, especially rare earth elements (REE), gives useful information on the oxidation state in the weathering environment (Braun et al., 1993;Ndjigui et al., 2008;Kamgang et al., 2009;Nyassa Ohandja et al., 2020). Relevant studies have been carried out on the weathering and the behaviour of these REE on granito-gneissic (Zheng and Lin, 1996;Nesbitt and Markovics, 1997;Bao and Zhao, 2008), volcanic (Irfan, 1999;Patino et al., 2003;Babechuk et al., 2014), carbonate (Walter et al., 1995;Bourbon et al., 2009), and metamorphic rocks (Gardner and Walsh, 1996;Kamgang et al., 2009;Rajamani et al., 2009;Gong et al., 2011). These scientific works have shown that the distribution and mobilization of REE are (1) mainly controlled by minerals such as monazite, allanite, xenotime, zircon, rhabdophane, and clay minerals, (2) and that the only two REE that may show signs of anomalous behaviour are Ce and Eu, depending on the oxidizing or reducing conditions prevailing in the weathering environment. The aim of this study is to quantify the intensity of supergene weathering, using weathering indices that take into account the hydrolysis of mafic minerals, and explain gadolinium anomalies in relation to the different stages of chlorite schists weathering along lateritic profiles, wherein the distribution and mobilization of REE is not controlled by clay minerals but mainly by mafic minerals and iron oxyhydroxides.

Location, Geology and Climate
The Mbalmayo-Bengbis series, roughly limited between 2° and 4° North and 11° and 16° East, occupies the central part of the Cameroonian Southern Plateau and belongs to the Yaounde Group. Metapelites and meta-psammopelites of the Yaounde Group underwent a multiphase deformation history which can be subdivided into the stages D 1 -D 2 , D 3 and D 4 (Owona et al., 2010). The deformation stage D 1 -D 2 has a progressive character and led to the formation of the regionally dominant foliation S 2 (Owona et al., 2010). The Bengbis region, located in these geological formations has been selected as study site (Fig. 1). The parent rock is a greenish, shiny at the surface and foliated chlorite schist. Millimetre-size concordant quartz veins within the chlorite schist are observable, although chlorite schists in this region are more alkaline than those of Mbalmayo (Kamgang et al., 2009). Also, the greenish colour is due to a high amount of chlorite contained in the Bengbis rocks. Microtectonic study shows that the phenomenon of mylonitisation is pronounced in the Bengbis rocks (Onana, 2010). Quartz, muscovite, chlorite, plagioclases and opaque minerals are smaller in size than those observed in chlorite schists of the Mbalmayo region (Kamgang et al., 2009). These rocks generate low plateaus (600-700 m) (Santoir, 1995). A landscape of hills close to large valleys is observed. The total annual rainfall is 1668 mm and the average annual temperature is 24.2°C (Suchel and Tsalefac, 1995). The actual climate is of equatorial type with transition nuance of oceanic traits.

Materials and methods
On the Nyangbassa asymmetrical interfluves, located within the most representative morphological unit (Fig. 1), the thickness of the weathering profile is about 16 m on the top (Pit BE3). Only the pit at the top of the interfluve, showing the sharpest lateral and vertical pedological variations, was studied in detail. After a macroscopic description of the profiles (after Duchaufour, 1977), 14 samples were collected from each horizon of the profile for physical, mineralogical, and chemical analyses. Undisturbed samples were collected for density measurements. Bulk density values were determined by Flint and Flint's method (Flint and Flint, 2002). The mineralogical composition of the rocks and the weathering cover was determined by X-ray diffraction on the total fine fractions.
The samples were then analysed by XRD using Co radiation at 40 kV and 45 mA at the Geoscience Laboratories (GeoLabs) of the Ontario Geological Survey in Sudbury Ontario (Canada). Major element concentrations were determined by X-ray fluorescence after sample ignition. Sample powders were ignited and then melted with lithium tetraborate flux before analysis using a Rigaku RIX-3000 wavelengthdispersive X-ray fluorescence spectrometer. Rock powders were prepared for inductively coupled plasma mass spectrometry analysis (ICP-MS) for trace element concentrations by acid digestion in closed beakers. Rock powders were dissolved in a mixture of HCl and HClO 4 acids at 120°C in sealed teflon containers for 1 week. The containers were rinsed with diluted HNO 3 and the solutions boiled to dryness. The residue was dissolved in HCl and HClO 4 and evaporated to dryness a second time, before being dissolved again in a mixture of HNO 3 , HCl and HF at 100°C. Ferrous iron concentrations were obtained by potassium dichromate titration. Sample solutions were analysed in a Perkin-Elmer 5000 ICP-MS instrument. At first the analysis was performed using the IM100 analytical package, in which a weighted average of instrument responses for three certified reference materials prepared in the same manner as the unknown was compared with the instrument response of the unknown solution for each element.
The nominal zero concentration was assumed to be equal to the measured response from an acid blank. Standard solutions were run between each batch of 30 samples along with a check sample for every 14 samples. Data are reported for 14 rare earth elements (La, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, and Lu). The pH and Eh of soils samples were determined with the aid of a Shott Gerate CG818 pH-Eh meter. Their colour was obtained using a Munsell soil colour chart (Munsell Color, 2000). The formulae of weathering indices proxy used are: CIA = 100 x [Al 2 O 3 /(Al 2 O 3 + CaO* + Na 2 O + K 2 O)] (1) A value of 100 indicates complete removal of the mobile elements. The molar CaO is corrected for the presence of carbonate and apatite as for the CIA (e.g., Fedo et al., 1995) to consider only the silicate-bound Ca (CaO*).
In oxidising environment and when Fe is retained, total Fe is considered an immobile element along with Al (Al 2 O 3 ) and the MIA calculation is: Unweathered mafic rocks have IOL values that are less than 40. In the same manner as CIA and MIA, higher IOL values correspond to more intensely weathered materials (Babechuk et al., 2014).

Macroscopic and mineralogical description of weathered materials
The lateritic weathering profile of Bengbis is located at the summit of an interfluve, under a secondary Equatorial forest at 695 m of altitude. It has a total thickness of 16 m and presents from bottom to top, a saprolitic zone, a nodular level and a loose sandy clayey zone (Fig. 2).
The saprolitic zone has a thickness greater than 12 m. It is divided into two main horizons, which are from bottom to top, the coarse saprolite and the fine saprolite.
The friable coarse saprolite (4.60 m) is a clayey material with a well-preserved parent rock structure. This clay embeds compact blocs where primary minerals are visible (quartz and phyllites).
Phyllosilicates are soft and black in colour. They are already affected by the weathering. The passage to the overlying facies is diffuse.
The red coarse saprolite (2.40 m) is a sandy clayey material with a banded structure. Visible minerals are quartz and relics of phyllosilicates. The transition between this purplish to red material and the yellow facies is gradual.
The yellow coarse saprolite (2 m) is a clayey friable material. The structure of the parent rock is quite visible. The recognisable mineral is quartz.
The reddish coarse saprolite (1.45 m) is a silty clayey, friable and dense material. Recognisable minerals are quartz which constitutes light bands and, phyllites such as muscovite, abundant in the The yellow coarse saprolite presents the same characteristics with the underlying facies except that it is less thick (0.90 m). The transition of this coarse saprolite with the overlying fine saprolite is sharp.
The fine saprolite (1.55 m) is a reddish (10R 6/ 6) clayey material, friable, porous and less dense (da = 1.3 g/cm 3 ). This reddish clay which represents almost 50% of the material encloses pluri-centimetric indurated fragments. These red fragments present in their edges, a yellow clayey fine film and their nucleus is bright red. This set is reminiscent of a carapace. Inside this yellow matrice, there are also centimetre-sized scales whitish grey rock fragments with well-preserved chlorite schist structure. These scales for which mineralogical transformations preserve the characteristics of fine saprolite, without creating new structures are alloteritic hardpans (Boulangé, 1984). Transition to the nodular level is progressive.
With 1.40 m in thickness and a bulk density of 1.4 g/cm 3 , the medium level is a red (10R 4/8) clayey material (~50%) containing blocks of various nature (quarzitic and ferruginous) and sizes as well as centimetre-sized nodules. Blocks are observed preferentially at the top of the nodular level. Two types can be described, (1) blocks of quartz, which represent at most 5% of this part of the profile, (2) ferruginous blocks whose dimensions vary between 15 cm x 9.5 cm and 28 cm x 28 cm, and whose proportion reaches 10%. These blocks co-exist with the ferruginous nodules constituting almost 35% of the materials. The quantity of these nodules decreases towards the summit. Many roots of trees with sizes close to 8 cm in diameter are also visible. Transition to the uppermost part is sharp.
The loose superficial level (1.70 m) is a brown (7.5YR 5/4) clayey material, very porous (da = 1.3 g/cm 3 ) and friable. It is dotted with many roots and rootlets and is made up in its first thirty centimetres by a humus rich A horizon. The weathered materials are distinguished by (1) the high thickness of the alterites and the low soils thickness, and (2)  Vertical distribution of major elements along the profile (Table 1; Fig. 3) shows five types of major elements behaviour. In general, Al 2 O 3 and P 2 O 5 have the same saw-toothed evolution along the profile.  contents increase (Fig. 3b). K 2 O and MgO are present in major amounts in the chlorite schist and saprolites and decrease in soil horizons where they occur in minor amounts (Fig. 3c). The lowest K 2 O and MgO contents are observed in the nodular materials and nodules. MnO and TiO 2 are relatively stable in the weathering profile (Fig.  3d). These two oxides accumulated extensively in nodular materials.
pH-Eh data indicate that Bengbis weathering materials evolve in an acidic weathering environment while chloriteschists are alkaline reducing materials (Table 1).
Weathered materials of the coarse saprolite have CIA values varying between 76 and 85. This fact indicates a moderate weathering that is consistent with the presence of clays such as illite and illite/ smectite mixed layers (Babechuk et al., 2014) in these materials as shown by X-Ray diffraction data (Table 1).
CIA values range between 88 and 100, from fine saprolite to soils, indicating the total loss of bases. The most weathered materials of the Bengbis region have reached the stage of complete kaolinitisation as indicated by the presence of kaolinite in the studied profile. However, CIA is not appropriate for the quantification of advanced weathering processes. In fact, the predominant hydrolitic process in the meteoric weathering is de-silicification but silicon is not taken into consideration in the CIA calculation (Babechuk et al., 2014). The CIA strength is the utility of the accompanying A-CN-K diagram (Nesbitt and Young, 1984;Nesbitt, 1992). In this diagram (Fig.  4), weathered materials follow a parallel evolution to A-K axis. This corresponds to a total loss of Ca and Na and, reflects the presence of muscovite in relatively significant contents in the weathering environment, except in the nodular horizon (  Although not localised on the A-K axis like those of Bengbis and Mbalmayo regions, weathering materials on sericite-quartz schists of the Yunnan province in China (Gong et al., 2011) present a similar evolution, enrichment in K, less than 30% (Fig. 4). This fact is different from that observed on the weathered materials overlying basalts in India where laterites show an evolution towards A apex, parallel to A-CN axis and the absence of muscovite (Babechuk et al., 2014). Generally, during the weathering of schistose rocks, for a CIA value of ~70, the dissolution rate of plagioclases (CaO + Na 2 O) is ~90%.
MIA values are average, below 60 and relatively close to those of CIA. This relative distance is because the USGS standard used is that of mica schists and not that of chlorite schists. These MIA values are greater than those of the alkaline metabasites of the Mbalmayo region (47.9). This progress is materialised by a gap between curves representing CIA and MIA (Fig. 5), along the weathering profile, reflecting a minor retention of the Mg in the weathered materials while Ca and Na are abundantly evacuated during feldspar dissolution from the base of the profile. Magnesium might probably be retained in the illitesmectites. This is similar to the observations made on the weathered materials developed over chlorite schists in Mbalmayo region. A gap appears from the base to the summit of curves representing CIA and MIA in the weathered materials overlying sericite-quartz schists of the Yunnan region in China (Gong et al., 2011). In fact, FeO exists in minor quantities (0.1-1 wt.%) in the weathered materials from the base to the summit of the profiles.  (Table 1). This reflects the conversion of Fe 2+ into Fe 3+ with the increase of the weathering and therefore the accumulation of iron (Fe 3+ ) in weathering oxidizing environment into iron oxides. Thus, the new MIA weathering index is more sensitive to certain changes that appear in the weathering profile than CIA.
Associated to MIA, weathering processes can be graphically quantified in the A-Fe-Mg-Ca-Na-K system with the help of two ternary diagrams inspired by Nesbitt and Young (1989), Nesbitt and Wilson (1992) and Babechuk et al. (2014).
The materials of the Bengbis profile are aluminous. The A-L-F diagram (Fig. 6a) shows a significant decrease of labile elements (Mg, Ca, Na, K) in the weathering environment. Lateritisation only affects nodular materials developed over chlorite schists like in Mbalmayo region. It should be noted that this phenomenon is more pronounced at Mbalmayo than Bengbis (Fig. 6a). This behaviour is similar to that of materials developed on basalts of the Bidar region in India (Babechuk et al., 2014). Weathered materials on the Yunnan region (China) are not lateritised (Gong et al., 2011).
The AF-CNK-M diagram (Fig. 6b) shows that the hydrolysis of feldspar (loss in Ca, Na and K) is proportional to those of mafic minerals (loss in Mg), although the weathering of plagioclases (Ca, Na) is more intense than that of mafic minerals (Mg). The same process has been observed in Mbalmayo and at Yunnan (China). In the weathering profile of the Bengbis region, the values of IOL vary between 23 and 78. The studied materials are localised in the kaolinitisation domain (Fig. 6c). Only nodular materials undergo a moderate lateritisation. This fact is consistent with their position in the weathering profile. Fe 2+/ Fe 3+ ratios are relatively well-correlated with IOL (r 2 = 0.49). The transformation of Fe 2+ into Fe 3+ , in oxidised environment increases with the index of lateritisation.
Weathered materials are localised in the most resistant minerals domain (Fig. 7a). This fact seems counter-intuitive with the data of the SAF diagram which shows that kaolinitisation predominates in the studied weathering profile. However, it is justified by the abundance of quartz and goethite in these materials. Except for materials at the summit of the fine saprolite (hardpan), and that of the nodular horizon, kaolinitisation predominates in the Bengbis weathering materials (Fig. 7b). Several elements are regularly used as immobile elements to quantify gains and losses within weathered materials. Actually, Gresen's equation is applied to identify the immobile element (Chu et al., 2014) by calculating CIA values of all the samples and plotting graphically the chemical elements of the rock and that of the most weathered material in a cross plot. The isocon is U, W, Hf, Nb, Al 2 O 3 , and TiO 2 . In the weathered materials of the Bengbis zone, the invariant element is hafnium (Fig. 8), which shows the lowest variations among all the other elements within the weathering profile in relation to the chlorite schists.
The geochemical mass balance calculations for the weathered materials are thus based on Hf as immobile element and the depletion or concentration factor is given by the following relationship (Brimhall and Dietrich, 1987;Anderson et al., 2002): =100 x [(C j,w /C j,p )/(C Hf,w /C Hf,p ) -1] In this model, the concentrations (C) of elements (j) in the parent rock (p), relative to that of an immobile index element (Hf), are used as a normalisation to establish the mass changes in the progressively altered rock (w). The combination of gains and losses of materials by mass balance calculations, chemical weathering indices present the advantage of linking highprecision trace elements to specific stages of weathering.
Very moderate losses in Si (< -18%) and average losses in Mg (-44 to -63%) associated with gains in Al and K in the coarse saprolite (Table 2) explain the presence of muscovite, sericite and interstratified illite/smectites. The lixiviation of K (-6%) in the fine saprolite justifies the disappearance of illite.
The presence of goethite and hematite is linked to the accumulation of Fe 3+ in weathered materials. Fe 3+ is perfectly linked to V (r 2 = 1) and strongly linked to Cu, Ga, Mo and Th (r 2 = 0.81) and Zr (r 2 = 0.64). These elements accumulate with the iron oxides and oxyhydroxides.
A relationship between the majority of alkali and alkaline earth elements (Li, Na, Rb, Mg, Ca, Sr, and Ba) is observed. Ca, Na and Sr are perfectly linked to the profile (r 2 = 1) and highly linked to Co (r 2 = 0.81). These elements, essentially contained in the plagioclases, are well-correlated with CIA and are quickly removed from the environment. Ca/Na ratio (0.28) of chlorite schists in Bengbis region is lower than that of Mbalmayo (Kamgang et al., 2009) which is 1.31. Bengbis rocks are less rich in plagioclases than τHf,j Table 2. Geochemical mass balance calculations by isohafnium method of the Bengbis chlorite schist profile those of Mbalmayo. Ca/Na ratios values are less constant in the weathering profile. The weathered materials where leaching of Ca compared with that of Na is greater and those where leaching of Na is more pronounced are observed. This fact is probably due to the predominance of Cafeldspar or Na-feldspar in each of these materials. Magnesium is highly linked to Li (r 2 = 0.81) and Ba (r 2 = 0.64) and present tendencies of correlations with Rb (r 2 = 0.47). Lithium, Ba and Rb are perfectly correlated to Fe 2+ (r 2 = 1). These elements are linked to the hydrolysis of mafic minerals. The leaching of Mg is less intense than that of Ca, Na and Fe 2+ as illustrated by the evolution curves of CIA and MIA. The change in behaviour of Mg in the studied weathering environment is expressed by low values of the Ca/Mg ratio which varies between 0.00 and 0.11, as observed by Babechuk et al. (2014) for the weathered materials over basalts in India.
Potassium, Be and Cs remain in the alterites and are strongly linked (Table 2, Fig. 9). Beryllium and K are perfectly correlated in the alterites (r 2 = 1) and evacuated in the soils while Cs continues to accumulate. Potassium and Be are leached in the soils in association with Mg. The enrichments in K, Cs and Be in saprolites are linked to the presence of illite. The accumulation of Cs in the soil might be due to the presence of kaolinite in the weathered materials (Lim et al., 1980;Ugur and Sahan, 2012). High gains in Tl, up to 784 681%, in weathered materials are associated with the presence of Fe 3+ , and consequently that of goethite and hematite in the weathering environment.
In general, a saw-toothed behaviour of all the elements can be observed along the studied profile (Fig. 9).
The constancy of the HFSE ratios (Fig. 10) suggests that they behaved more or less equally immobile, except for Th. But, the most stable system is: Hf -Nb -W -U.

REE fractionation
The concentrations of REE in the weathered materials as well as the characteristic ratios ( REE, LREE/HREE, (La/Yb) N , Ce/Ce*, Eu/ Eu*,  (Braun et al., 1993;Laveuf and Cornu, 2009;Gong et al., 2011;Babechuk et al., 2014;Sababa et al., 2015) which showed that HREE are more mobile than LREE during the weathering process. The mobility of HREE and LREE is comparable in the coarse saprolite, fine saprolite, nodular level and loose clayey materials depleted in REE according to the order MREE > HREE ~ LREE (Fig. 11). This fact is counter-intuitive, because HREE are more mobile in supergene environment than the LREE. Kamgang et al. (2009) report higher mobility of LREE compared with HREE in the weathered materials on chlorite schists in the Mbalmayo region. This phenomenon can be because the Bengbis materials are acidic (4.78 < pH < 5.75) and those of Mbalmayo, weakly acidic to basic (6.70 < pH < 7.80).
In the Bengbis region, LREE and MREE accumulate in the coarse saprolite for pH values comprised between 5.5 and 5.6 and for those of Eh varying between +60 and +70mV. Contrary to the work of Gong et al. (2013), LREE are not adsorbed by clays during pedogenesis, despite the abundant presence of kaolinite in the loose clayey materials. Adsorption or co-precipitation of LREE onto Fe oxides mainly may control the concentration of these elements in this part of the profile (Ren et al., 2015). (La/Yb) N values are very close to 1 in almost all the materials of the profile except for some materials of the saprolite, thus showing a slight fractionation between LREE and HREE.
The fractionation between neighbouring REE is not detectable (Sm/Nd ~1), except for the basal coarse saprolite, where Sm/Nd ratio is equal to 0.76. In fact, this material has the highest content in Ce (441.00 ppm). This is the same for materials where the fractionation between neighboring REE was only observed in the basal coarse saprolite. This well-known fact (Ndjigui et al., 2008;Kamgang et al., 2009;Wang et al., 2013) is due to the accumulation of REE and mostly of Ce at the base of the lateritic weathering profiles. The parent rock constitutes by its nature and its pH, a barrier to the vertical migration of these elements.
Weathered materials do not present anomalies for values ranging between 0.90 and 1.10 (Braun et al., 1993). The values of the Eu/Eu* ratio range between 1.02 and 1.15. Weathered materials in the Bengbis area do not present anomalies in europium. The absence of anomalies in europium Eu/Eu* indicates complete dissolution of feldspar in the weathered materials.
The parent rock has a negative Ce anomaly. This is not expected for an unweathered rock. This creates three issues with the internal normalization strategy (1) negative Ce anomalies in the rest of the weathering profile can be masked, (2) any existing positive Ce anomaly is amplified, and (3) (Braun et al. 1993;Ndjigui et al. 2008;Kamgang et al. 2009;Ren et al., 2015;Sababa et al. 2015;Onana et al., 2016). They are due to the change in Ce 3+ to Ce 4+ . The weak positive anomalies in Ce, despite the degree of weathering of materials in the Bengbis area, are probably due to the presence of low amounts of rhabdophane as indicated by correlations between Ce -P 2 O 5 (r 2 = 0.49), Ce -La (r 2 = 1) and Ce -Nd (r 2 = 0.81) as well as the low content in P 2 O 5 (< 0.25 wt. %) in the weathering environment.
The values of Gd/Gd* vary between 0.70 and 0.84. Weathered materials of the Bengbis area present Gd fractionation. This fractionation materialises the similitude of behaviour between LREE and HREE and the MREE depletion. These values of Gd/Gd* corroborate the data of (La/Yb) N . Gadolinium is linked to Fe 2+ , Mg, Li and Ni which are highly leached elements of this environment (r 2 (Fe

2+
, Mg, Li, Ni) -Gd = 0.40). Gadolinium is thus present in mafic minerals. This element which does not have the possibility to change its valence to remain stable in the weathering milieu, is leached, hence a negative anomaly is observed. It appears that, a part of Gd distribution and remobilization is controlled by mafic minerals in the studied weathered materials. Gadolinium fractionation is thus due to intense chemical leaching.

Conclusions
This work investigates the intensity of weathering, and elements (alkali and alkaline earth elements and REE) released in a lateritic profile overlying chlorite schists from Bengbis in the southern Cameroon. The main conclusions are as follows: (1) The hydrolysis of the feldspars (losses in Ca, Na and K) is proportional to that of the mafic minerals (loss in Mg), although the dissolution of plagioclases is more intense than that of mafic minerals. The studied materials are localised in the kaolinitisation domain, except for the nodular materials which are slightly lateritised; (2) The order of mobility of elements in the weathering environment is: Ca Na > Fe 2+ . Sr > Mg Co > Mn > Li > Ba > Rb > P > Cd > Ni > Si > Be > K > Sn. The elements Ca, Na and Sr, essentially contained in the plagioclases are well-correlated to CIA and MIA. The change in behaviour of Mg in the weathering profile is expressed by low values of Ca/Mg ratio. Potassium and Be are leached in the soils in association with Mg. Enrichments in K, Cs and Be in saprolites are linked to the presence of illite. The accumulation of Cs in the soils is due to the presence of kaolinite; (3) REE exhibit three types of behaviour along the Bengbis profile as indicated by the (La/Yb) N ratio values which are less than 1, higher than 1 and ~1. REE are not adsorbed by clays during the pedogenesis, despite the abundance of kaolinite in the loose sandy clayey materials. Weak Ce anomalies, despite the degree of weathering are probably due to the presence of low amounts of rhabdophane. The weathered materials of the Bengbis area present a fractionation in Gd.