The Cameroon Hot Line is interpreted as a megashear zone, developed on both oceanic and continental domains [1] . The structure is characterized by a SW-NE alignment (trending 30˚) of volcanic massifs and plutons extending from Pagalu Island to Lake Chad for more than 1600 km. The general geology of Mount Etinde has been extensively described by [5] - [12] and the more recently summarized and updated by [13] [14] [15] . Its basement (Pan-African granite and gneisses) is covered by cretaceous to quaternary sediments [16] . The nephelinitic lavas erupted less 1Ma ago, and is contemporary with recent lavas of Mount Cameroon [17] . These rocks contain nepheline, clinopyroxene, garnet, melilite and post magmatic minerals such as sodalite, zeolite and analcite. Olivine occurs mostly in the olivine nephelinite where it makes up less 5 wt%. Varieties of nephelinites are named on the basis of the dominant mineral and nepheline occurs.

Mineral compositions were studied in detail and the compositional ranges given below are based on electron microprobe (CAMEBAX SX 50 at the University of Marie Curie, Paris) measurement of mafic phases in only a few representative sample of nephelinite. The measurement were made according to standard analyzed data, under the condition expressed in kv (acceleration) nA (beam current) and (counting times at the peak). Olivine (15 kv, 40 nA, 20s and Si, clinopyroxene (15 kv, 40 nA, 20 s for Si, Al, Fe, Mg, Ca, Na Mn and 30 s for Ti and Zr), nepheline (15 kv, 40 nA, 15 s for Si, Al, and 20 s for Ca, Na, K ), garnet (15 kv, 40 nA, 20 s for Si, Al, Fe, Mg, Ca, Na, Mn and 15 s for Ti), melilite ((15 kv, 40 nA, 20 s for al elements), perovskite and sphene (15 kv, 40 nA, 5 s for all

elements), (oxides (15 kv, 40 nA, 20 s for Ti, Fe, Mn, Mg, 20 s for Si, 20 s for Cr and 30 s for Al) natural silicates and oxides as standards, PAP corrections were made using CAMECA software [18] . Whole rock chemical analyses of peralkaline nephelinite from Etinde massif were carried out at the “Centre de Recherches Pétrographiques et Géochimiques” in Nancy. Major elements were analyzed by ICP-AES and trace elements by inductively coupled plasma mass spectrometry ICP-MS by Ngounouno.

Thermodynamic condition of crystallization during the eruption of Etinde nephelinite was determined by the QUILF95 software [19] . The programs application (QUILF thermobarometer) is explained by many works [20] [21] [22] . The minerals used for calculations, had not attained subsolidus re-equilibrium as showed by their unzoned and homogeneous compositions. Oxygen fugacity (fO₂) was calculated using the equation ∆logFMQ = logfO₂ − FMQ (∆logFMQ ≤ 0). The experimental aSiO₂ was calculated using the QUILF95 software from coexisting clinopyroxene, olivine and titano magnetite (aSiO₂ = 0.30 - 0.60). The experiments with an acceptable error (±0.02) gave the lowest values for aSiO₂. Geothermobarometric calculations based on the composition of olivine, clinopyroxene and Fe-Ti oxide was used to determine the temperature range from 950˚C to 1250˚C at lower fO₂.

Our description of the nephelinite is based on samples collected from the flank of Mount Etinde and the Batoke beach, possibly representing the volcanic event. The textures are generally porphyritic (15% - 30% phenocrysts), with groundmass exhibiting various textural types including intergranular, intersertal. Photomicrograph, taken under crossed polarizers, of nephelinte rocks shows olivine, clinopyroxene, nepheline and garnet phenocrysts. The photograph, taken plane polarized light, shows the typical shape of olivine and cliopyroxene: the irregular cracks and slight alteration along the craks (Figure 2(a) and Figure 2(c)). Clinopyroxene and nepheline are birefringent, garnet is black. The most nephelinitic lavas contains phenocrysts of Ca-rich clinopyroxene (<20 vol%), titanomagnetite (<2 vol%) and in some samples, melilite (<5 vol%). Nepheline phenocrysts occurring in some of these nephelinitic rocks is automorphic (Figure 2(b)). They are coarse grained and consist of euhedral to subhedral nepheline (typically replaced by cancrinite alteration product), altered formed haüyne or nosean, and alkali feldspar. Some olivine crystals are surrounded by rims of diopside. These rocks contain rare, resorbed phenocrysts of olivine surrounded by clinopyroxene as well as magnetite. The clinopyroxene phenocrysts are subhedral to euhedral and reach a few millimeters in size. At the contact with these interstitial domains, the brown diopside phenocrysts are transformed into green hedenbergite with a composition that matches that of groundmass pyroxene. Some clinopyroxene show zoning (Figure 2(a)). This characteristic has previously been reported, [9] [12] [13] [23] . Ti-magnetite is common, and partly altered olivine and haüyne are present in haüyne nephelinitic and

haüynophyre. Spinel, described here from the nephelinitic lavas, occurs as tin (up to 2 mm) opaque or brownish euhedral inclusions in olivine and euhedral inclusions in aluminous clinopyroxene. Spinels found are xenomorphic, probably because it crystallized late. Small magnetites are irregularly distributed between the silicates, the locally form lenticular zones of interstitial Ti-magnetite. The groundmass consists of prismatic clinopyroxene and nepheline up to 0・2 mm in length microphenocrysts set in a matrix with smaller crystals, perovskite, magnetite, sphene and carbonate. The prismatic Zeolite is automorphe in LPA and replaced by analcime product (Figure 2(d)). The minor and accessory phases include zeolite, analcime, magnetite, apatite and perovskite. In additional, spinel is the most common accessory mineral but it is usually pale to dark brown. Groundmass is frequently altered and consists of a low temperature assemblage of zeolite, which probably replace feldspar ± nepheline. Melilite microphenocrysts occur in a green-grey aphanitic textural in melilite nephelinite. Groundmass clinopyroxene grains are up to 0.5 mm in size.

The nomenclature of [24] was used for pyroxene. Chemical analyses of pyroxene were plotted on the quadrilateral classification diagram Di-Hd-En-Fs. The result reveals three clinopyroxene types in the Etinde massif, magnesium-rich diopside Wo_49-52En_23-47Fs_4-17, hedenbergite Wo_50-47En_13-11Fs_37-32 and augite Wo_44-47En_17-23Fs_14-17 (Table 1), the diopside has Mg# [=atomic 100 × Mg²⁺/(Mg²⁺ + Fe ²⁺ + Mn²⁺)] ranging between 0.63 and 0.71). Moreover, clinopyroxene crystals display a trend of decreasing En and Wo with increasing Fs on the quadrilateral classification diagram. Clinopyroxene is low in calcium, 0.73 - 0.83 atoms per formula unit (a.p.f.u.), and contains significant Al (0・23 - 0・39 a.p.f.u.). It consists of a relatively large diopsidic core that is relatively Ca-poor and Na-rich, and exhibits large differences in Al content from grain to grain (mg-number 0.78 - 0.83) (Figure 3).

Garnet composition falls within the compositional range of garnets reported in other lavas and ijolites from Oldoinyo Lengai [25] , and nephelinite from Tanzania [3] . There are no significant differences in the compositions of the garnets from the different nephelinite varieties at Etinde. The main compositional variations are in the amounts of Ti and total Fe, which vary inversely. The minor elements, MnO (<1%) and ZrO₂ (<1%), present concentrations in appreciable amounts. Garnet is andratite rich, with an overall compositional range of And_72-43Pr_7-11, Uva_0,1-0.54Sps_4-10, and Grs_13-44 (Figure 4). The TiO₂ contents are low, varying from 7 to 14 wt%.

Representative chemical analyses and structural formulae (O²⁻ = 21) of haüyne is presented in Table 2. Ternary diagram (Figure 5) shows that haüyne data are similar to those of pan de AZUCAR haüyne [27] . The diagram of the system reveals that Haüyne has CaO concentration ranging between 60 and 80 wt%.

Perosvkite and Sphene are trace- and rare element-rich. The Trace elements content

(BaO, SrO, ZrO₂ and Nb₂O₃) represented slightest 4.0 wt%. Sphene’s rare elements content is low ≈ 2 wt%, and for perovskite they vary between 3 - 8 wt%. The ternary classification CaO-SiO₂-TiO₂ diagrams shows that the crystallization temperature condition of sphene is low compared to perovskite [29] . The phase diagram of the system reveals that perosvkite contains 40 wt% Cao and 60 wt% TiO₂.

Spinels chemical compositions were calculated on the basis of three cations and the proportions of Fe³⁺ and Fe²⁺ were determined on the basis of charge balance [30] . The high Al₂O₃ content indicates the low silicate activity [31] . Spinel is relatively poor in Cr and rich in Al. Al₂O₃ content varies from 58 to 59 wt%, MgO (18 - 19 wt%) and FeO (17 - 18wt%). This indicates that they were crystallized from an alkaline magma. Spinel type is pleonaste (Figure 6) and it is similar to the spinel which is included in clinopyroxenes at Oldoinyo Lengai, Tanzanie [4] .

The minerals of the melilite group consist mainly of the solid-solution series between åkermanite (Ca₂MgSi₂O₇), gehlenite (Ca₂Al₂SiO₇) and ferro-akermanite (Ca₂Fe²⁺Si₂O₇). The most melilite however contain appreciable amounts of Na replacing Ca as well as Fe²⁺ replacing Mg [28] . The melilite has been found only as microphenocrysts in melilite nephelinite and rare olivine nephelinite. They are iron and soduim rich (Fe₂O₃ 6 to ~9wt%; Na₂O 5 - 6 wt%). Melilite containing up to 6.0 wt% SrO. The compositional variations are slightest fairly that melilite in small olivine melilitite lavas flows on the floor of the rift valley to the east of Oldoinyo Lengai [25] . Ternary Diagrams [33] shows that composition corresponds to intermediate members of the ferro-akermmanite and Gehlenite.

On the Harker diagram (Figure 7) with increasing MgO contents, TiO₂, FeO and CaO contents generally increase and CaO/Al₂O₃ ratios are relatively constant at MgO < 6 wt% indicating olivine as the dominant crystallizing phase. Slightly positive correlations between MgO vs FeO, MgO vs CaO and TiO₂ a negative correlation between MgO is observed at 5.5 wt% MgO. An interesting phenomenon is that when MgO contents are between 5.5 and 10.0 wt%, Al₂O₃ contents show a negative correlation with MgO whereas P₂O₅ contents exhibit a slightly positive correlation with MgO. It is possible that the high Al₂O₃ (≥19 wt%) contents of the more SiO₂-rich, MgO-poor samples could be result of a process superimposed upon simple fractional crystallization.

Trace element analyses of the nephelinite from Etinde massif are reported in Table 3 and illustrated in primitive mantle-normalized diagrams (Figure 8).They are enriched in large ion lithophile elements (LILE, Rb, Ba, and Sr) and depleted in Ti (high-field strength elements, HFSE). They are also depleted in heavy rare earth elements (HREE) and enriched in light rare earth elements (LREE) relative to HREE. These trace element distribution patterns are similar to that of Oldoinyo Lengai nephelinite and the alkaline lavas of Cameroon Hot Line [1] . The trace element patterns of olivine nephelinite, melilitite and perovskite nephelinite are very similar (parallel) and characterized by a weak slightly positive Zr anomaly (Figure 8). The primitive mantle normalized trace element patterns of the nephelinite show negative P, K, and Ti anomaly. In detail, however, the

negative Nb anomaly is more significant for Etinde. They also show small Zr and Y positive anomalies where as small negative anomalies for these two elements are observed in the olivine nephelinite.

Nephelinite rocks has lower overall REE abundances compared with the haüynophyre, exhibiting different concave up REE pattern with steeper LREE part (La/Sm) = 18 compared with 4 - 5 in nephelinite. The trace element profile resembles that of nepheline from the Tanzania alkaline complex [4] . The total REE concentration and the slope of primitive normalized distribution patterns (La/Sm) ratios increase with differentiation. None of the samples analyzed for REE shows a significant Eu anomaly and this suggest no fractionation of plagioclase.

Primitive mantle-normalized trace-element patterns of Etinde samples (Figure 8 and Table 3 for values) show sub-parallel shapes. The trace elements display a limited range of variations, indicating little influence of fractional crystallization differentiation. The samples nephelinite shows a negative P and Ti anomaly but no anomaly in Zr. This may indicate that apatite may be a residual phase but no ilmenite. The ranges in normalized La abundances and rather constant Yb abundances are consistent with melting occurring in garnet stability field. Nephelinite and melilitite have similar and parallel trace and REE normalized patterns. Primitive mantle-normalized trace-element compositions of the nephelinite rocks display a typical OIB signature with an enrichment of strongly incompatible element contents (Rb, Ba, Sr, Th). An important characteristic of the trace element enrichment patterns of the nephelinite, melilitite and haüynophyre is that the LILEs (Ba, Th) are at about the same level or slightly lower than the La (Figures 8(a)-(c)). The depletions in Cr and Ni and enrichments in incompatible elements such as Ba, Sr, Rb, Zr and Nb reflect olivine, pyroxene and spinel crystallization. Negative K and Rb anomalies accompanied by distinctive positive peaks of Ba and Nb are characteristic of basaltic rocks of anorogenic affinity of the Central European Volcanic Province [35] . The negative K and Rb anomalies accompanied by high and variable K/Rb and Zr/Hf ratios are typical of Bioko basaltic lavas and the Mount Cameroon [36] . These trace element features are believed to result from melting of mantle sources initially slightly depleted with metasomatized by slab-derived, H₂O-rich phases segregating mobile from non mobile elements.

Geochemical characteristics observed on the nephelinite lavas are similar or identical of the Mount Cameroon lavas [37] [38] and [39] . The whole-rock atomic Mg/(Mg + Fe) ratio is practically identical to those of the basaltic lavas of the Cameroon Hot Line. The mineral assemblage of nephelinite could result from the basaltic magma by the pneumatolytic processes (reaction 1 and 2) and metasomatic processes (reaction 3) in agreement of [40] , [41] respectively by the reaction: