Antal Embey-Isztin

Petrology and geochemistry of spinel peridotite xenoliths from the western Pannonian Basin (Hungary) : evidence for an association between enrichment and texture in the upper mantle

Twenty spinel peridotite xenoliths from Pliocene alkali basaltic tuffs and lavas of the western Pannonian Basin (Hungary) have been analysed for bulk rock major and trace elements, electron probe mineral compositions, and REE and Sr, Nd isotopes on separated and leached clinopyroxenes. The xenoliths are texturally diverse, including protogranular, porphyroclastic, equigranular and poikilitic textures which can generally be correlated with geochemical features. Protogranular xenoliths are relatively undepleted in Ca, Al, Ti and Na, whereas poikilitic xenoliths are more refractory. LREE-depleted patterns. and MORB-like εNd and εSr values are associated with protogranular peridotites. In contrast, xenoliths with complex textures are generally LREE-enriched. Much of the isotopic variation in the suite (εSr=−20.4 to +10.4, +Nd=+1.8 to +13.7) can be related to interaction between protogranular mantle and melts resembling the host alkali basalts, but a third (high εSr) component may be due to Miocene subduction beneath the region.

Thermal evolution of the lithosphere beneath the western Pannonian Basin: Evidence from deep-seated xenoliths

Abstract A series of recently and previously collected peridotite xenolith samples from the western Pannonian Basin has intensively been studied using electron microprobe techniques and a thermo-barometric approach in order to obtain relevant information about the thermal evolution of the lithosphere. Most of the xenoliths have chemically homogeneous mineral phases reflecting ambient equilibrium P–T conditions. The results indicate hot and thinned lithosphere in agreement with heat flow, seismic and magnetotelluric properties of the area. A strong relationship has been observed between deformation and temperatures of peridotites, in as much as coarse-grained protogranular and poikilitic xenoliths have high temperatures (up to 1175°C), whereas fine-grained equigranular and mosaic xenoliths have low temperatures (800–900°C). This picture suggests that diapiric uplift of hot mantle material into a cooler uppermost mantle has probably taken place.

Petrology and geochemistry of peridotites and associated vein rocks of Zabargad Island, Red Sea, Egypt

SummaryZabargad (St. Johns) Island in the Red Sea contains three ultramafic bodies, one of which bas produced the famous gem olivine (peridot). The ultramafic rock types consist of two major groups—the peridotites and the vein rocks within them. The peridotites are divided into three groups: primitive, depleted and metasomatized. The primitive peridotites are the most abundant and are represented by mainly pristine spinellherzolites which have chemical compositions representative of the subcontinental upper mantle. The depleted peridotites are mainly harzburgites and nome dunites and both are similar to worldwide occurrences. The most depleted peridotites also appear to have the greatest metasomatic additions of incompatible elements, as has been noted at other localities. Metasomatic additions were clearly accompanied by tectonic shearing. Metasomatism included infiltration of incompatible elements and the formation of porphyroblasts of clinopyroxene, amphibole, Al-spinel and plagioclase; il took place under a variety of p-T conditions and with fluids of differing compositions.The vein rocks are mainly monomineralic and comprise olivinites, orthopyroxenites, clinopyroxenites, websterites, hornblendites and plagioclasites. These rocks are believed to have formed from fluids similar to that which metasomatized the host rock, rather than by some kind of igneous process. The fluids were derived from peridotite reservoirs (fertile and depleted) and apparently were in equilibrium with these reservoirs. Highly abundant fluid inclusions document the hypersaline and CO2-dominated character of these fluids. Monomineralic vein rocks are closely associated with metasomatic and tectonic processes, and there is a complete transition between metasomatic impregnation and formation of vein rocks. These processes may have also been active in other peridotite bodies of the world, as was earlier recognized and documented in the Seiad Ultramafic Complex, California. Metasomatism is evident along clinopyroxenite and hornblendite veins, whereas orthopyroxenites, olivinites and plagioclasites do not show any interaction with the wall rocks. Olivinites are probably the latest (lowest p-T) vein rock type, and the latest olivine which formed within their open cavities became the gem peridot.Zabargad ultramafic rocks preserve relic phases indicating an initial depth of origin greater than 85 km. Clinopyroxenites preserve the memories of the highest p-T conditions and they may be the first vein rock type formed in the peridotites. The p-T path of uplift coincides with the oceanic geotherm at great depth but deviates systematically from it with falling pressure in a series of tectonic stages accompanied by metasomatism and recrystallization. The p-T and petrologic history indicates rapid uplift, a feature which is supported by extensive contact metamorphism of the associated metasediments.ZusammenfassungAuf der Insel Zabargad (St.Johns Island) im Roten Meer befinden sich drei Peridotit-Körper von denen einer seit Jahrtausenden den berühmten Peridot (Edelolivin) geliefert hat. Die ultramafischen Gesteine von Zabargad gliedern sich in zwei Hauptgruppen: die Peridotite und die mit diesen vergesellschafteten Ganggesteine. Die Peridotite können in drei Gruppen gegliedert werden: die primitiven, die verarmten und die metasomatisch veränderten Peridotite. Am meisten verbreitet auf Zabargad sind die primitiven Peridotite. Diese sind meist Spinell-Lherzolithe mit einer chemischen Zusammensetzung, welche dem subkontinentalen Oberen Erdmantel entspricht. Die verarmten Peridotite werden hauptsächlich von Harzburgiten und einigen wenigen Duniten repräsentiert. Beide sind jenen aus anderen Vorkommen der Welt sehr ähnlich. Die am stärksten verarmten Peridotite scheinen auch die stärksten metasomatischen Veränderungen erfahren zu haben—ein Trend, der auch schon an anderen ultramafischen Komplexen erkannt wurde. Metasomatische Anreicherungen inkompatibler Spurenelemente sind häufig direkt mit tektonischer Verformung und Kataklase gekoppelt. Die Metasomatose ist als Infiltration inkompatibler Elemente erkennbar und führte auch zur Bildung von Porphyroblasten von Klinopyroxen, Amphibol, Al-Spinell und Plagioklas. Diese Bildungen fanden unter verschiedenen p-T-Bedingungen statt und erfolgten durch Fluide mit unterschiedlichen Zusammensetzungen.Die (meist ultramafischen) Ganggesteine sind häufig monomineralisch und umfassen Olivinite, Orthopyroxenite, Klinopyroxenite, Websterite, Hornblendite und Plagioklasite. Wir glauben, daß diese Gesteine von Fluiden gebildet wurden, welche ähnlich jenen waren, die die Metasomatosen der Peridotite verursachten. Diese Genese wird von uns der magmatischen vorgezogen. Die Fluide stammten aus peridotitischen Reservoiren (fertilen und verarmten) und waren mit diesen offenbar im Gleichgewicht. Die Ganggesteine sind sehr reich an “fluid inclusions”, welche allerdings keine Flüssigkeit enthalten, sondern nur Festkörper (Salze) und CO2 (± N2), also einen trockenen, hypersalinen Charakter haben. Auch die monomineralischen Ganggesteine sind eng mit tektonischen Prozessen verknüpft und somit auch mit metasomatischen Prozessen. Es existieren vollkommene Übergänge von metasomatischen Imprägnationen bis zu echten Ganggesteinen. Solche Prozesse waren offensichtlich auch weltweit in anderen ultramafschen Komplexen aktiv und wurden schon im Seiad Ultramafc Complex in Kalifornien erkannt und beschrieben. Metasomatismus begleitet überlicherweise die Klinopyroxenit- und Hornblendit-Gänge. Orthopyroxenite, Olivinite und auch Plagioklasite zeigen jedoch keine Wechselwirkung mit den Wirtgesteinen. Olivinite sind wahrscheinlich die zuletzt gebildeten Ganggesteine. Der zuletzt sich bildende Olivin wurde der schönste und zum gesuchten Peridot.Alle ultramafschen Gesteine von Zabargad enthalten Minerale aus verschiedenen Bildungsepochen. Einige Relikte erinnern an eine Herkunft aus einer Tiefe von mehr als 85 km. Klinopyroxenite konservierten die höchsten p-T-Bedingungen. Sie waren daher wahrscheinlich die ersten (noch erhaltenen) Ganggesteine, welche sich im peridotitischen Erdmantel unterhalb des heutigen Roten Meeres bildeten. Der p-T-Pfad der Zabargad Ultramafitite deckt sich in großer Tiefe mit der ozeanischen Geotherme. Mit abnehmender Tiefe entfernt sich dieser Pfad allerdings zunehmend von der Geotherme und läßt eine Reihe von tektonischen Aktivitäten verbunden mit Metasomatose und Rekristallisation erkennen. Die p-T-Geschichte der Zabargad Ultramaftite deuten auf einen raschen Aufstieg aus dem Erdmantel hin. Diese Daten werden durch die weitverbreitete und intensive Kontaktmetamorphose der mit den Peridotiten assoziierten Metasedimenten unterstützt.

Origin of megacrysts and pyroxenite xenoliths from the Pliocene alkali basalts of the Pannonian Basin (Hungary)

Clinopyroxene and amphibole megacrysts and type II pyroxenite xenoliths occur in young (mainly Pliocene) alkali basalts of the Pannonian Basin. Major and trace element contents (the latter were determined by LAM-ICP-MS) of the clinopyroxenes and amphiboles suggest that megacrysts and type II xenoliths share a common origin. Both suites are fragments of igneous cumulates and pegmatitic veins that crystallised from alkali basaltic melts in the upper mantle at 11-14 kbar pressures. Trace element contents of the calculated hypothetical melts in equilibrium with the megacrysts and type II xenoliths are very similar to those of the host alkali basalts, but 8 7 Sr/ 8 6 Sr ratios are significantly lower and 1 4 3 Nd/ 1 4 4 Nd ratios are higher in the megacrysts and xenoliths than in the Pliocene alkali basalts that host them. The source rocks of the megacrysts and type II xenoliths had probably crystallised from earlier intrusions of alkali basaltic melts in the lithospheric mantle and were disrupted later by more voluminous intrusions of compositionally similar but isotopically more enriched alkali basaltic magmas.

Oxygen isotope ratios of phenocrysts from alkali basalts of the Pannonian basin: Evidence for an O-isotopically homogeneous upper mantle beneath a subduction-influenced area

Oxygen isotope compositions of olivine and pyroxene phenocrysts and pyroxene and amphibole megacrysts from Neogene alkali basalts of the Pannonian basin (0.5–11 Ma) have been determined by laser fluorination. Measured δ18O values in olivine and clinopyroxene phenocrysts show rather restricted variations from 5.00 to 5.20‰ and from 5.07 to 5.34%., respectively, with cpx-ol fractionations Δ18O(cpx-ol) ranging from + 0.04 to + 0.29‰. These δ18O values are significantly lower than those of the corresponding whole rocks, suggesting that low temperature alteration has increased the 18O16O ratios of the groundmass of host rocks, even in fresh looking samples, whereas their phenocrysts have retained original oxygen isotope compositions. The uniform oxygen isotope ratio in the phenocrysts suggests that the mantle source of the alkali basalts was also homogeneous with respect to its oxygen isotope composition, which is in contrast to the relatively wide variation of Sr, Nd and Pb isotope ratios in the source. Variations in radiogenic isotope compositions in the basalts have been explained by the interaction of subduction-related fluids with the mantle source of the basalts. If this is the case, then the fluids which caused significant changes in the Sr and Pb isotope ratios of the mantle source clearly did not noticeably modify its oxygen isotope composition. These data support the opinion that the upper mantle is more homogeneous with respect to its oxygen isotope composition than it was previously considered.

The upper mantle beneath Kapfenstein and the Transdanubian volcanic region, E Austria and W Hungary: A comparison

SummaryA representative suite of ultramafic xenoliths from Kapfenstein, Austria, has been investigated petrographically. Textures and mineral chemistries are compared with published data on Hungarian xenoliths and discussed within the framework of the hypothesis of a mantle diapir beneath the Transdanubian Volcanic Region (TVR) of E Austria and W Hungary. We succeeded in recognizing important differences which seem to support the TVR mantle diapir concept. Below the external part of the TVR (Kapfenstein) the upper mantle seems to be essentially untectonized and lithologically rather monotonous (e.g., Type II clinopyroxenites are absent). In contrast, both deformed (equigranular) and undeformed (protogranular) peridotite xenoliths occur in the internal part (Balaton area) where Type II clinopyroxenite xenoliths as well as Type I/Type II composite rocks are present. It is remarkable that at Gérce (Hungary), situated approximately mid-way between the internal and external regions, almost exclusively porphyroclastic xenoliths occur.The undeformed xenoliths from Kapfenstein are largely unfractionated. A small proportion exhibits depletions in basaltic component or some mild influence of mantle metasomatism. Several mineral chemical parameters, such asmg-number of olivine, Al2O3 content of spinel and clinopyroxene, apparent pyroxene equilibration temperature, etc., show a narrow distribution with a pronounced maximum in the undeformed Kapfenstein xenoliths. By contrast, the deformed xenoliths from the internal TVR show a much broader range of values with no distinct maximum, attesting to a more complex chemical and physical evolution. Thus a direct relationship between deformation and chemistry seems to be confirmed. The deformed rocks can be extreme in two ways: they can either be strongly depleted or strongly enriched as documented by the high contents of clinopyroxene in equigranular xenoliths from Szigliget. Tectonization apparently opens the way for mass transport in either direction.ZusammenfassungEine repräsentative Suite von ultramafischen Xenolithen von Kapfenstein, Steiermark, wurde petrologisch untersucht. Die Gefüge und Mineralchemismen werden mit publizierten Daten von ungarischen Vorkommen verglichen und im Rahmen der Mantel-Diapir-Hypothese für die Transdanubische Vulkanische Region (TVR) diskutiert. Der Vergleich ergab wesentliche Unterschiede, welche das TVR-Mantel-Diapir-Konzept unterstützen. Der Mantel unterhalb des äußeren Teiles der TVR (Kapfenstein) ist praktisch untektonisiert und lithologisch monoton (z.B. fehlen Typ II Klinopyroxenite). Im Gegensatz dazu finden sich im inneren Teil (Balaton-Region) sowohl deformierte (equigranulare) als auch nicht-deformierte (protogranulare) Xenolithe zusammen mit Typ II Klinopyroxeniten. Auch zusammengesetzte Xenolithe, bestehend aus Typ I und Typ II Gesteinen sind vorhanden. Bemerkenswert ist, daß bei Gérce (Ungarn), eine Lokalität, welche sich zwischen dem inneren und äußeren Teil der TVR befindet, fast ausschließlich nur porphyroklastische Xenolithe vorkommen.Die undeformierten Xenolithe von Kapfenstein sind größtenteils unfraktioniert. Einige wenige zeigen Verarmungen oder geringfügige metasomatische Anreicherungen. Histogramme mineralchemischer Parameter zeigen sehr deutlich die Unterschiede zwischen den undeformierten Kapfenstein Xenolithen und den deformierten der inneren TVR. Die Kapfenstein Xenolithe zeigen typischerweise regelmäßige Verteilungen mit einem deutlichen Maximum. Die Xenolithe der inneren TVR hingegen zeigen eine flache Verteilung und weisen damit auf eine wesentlich komplexere chemische Entwicklung hin. Unsere Daten scheinen einen direkten Zusammenhang zwischen Deformation und chemischer Veränderung aufzuzeigen. Die deformierten Gesteine können in dieser Hinsicht zwei Extreme annehmen: Sie können entweder stark verarmt oder stark angereichert sein. Letzeres wird z.B. beeindruckend durch die hohen Gehalte an Klinopyroxen der equigranularen Xenolithe von Szigliget dokumentiert. Tektonisierung scheint die Wege für Massen-Transporte in beiden Richtungen zu öffnen.

Cryptic metasomatism in clino- and orthopyroxene in the upper mantle beneath the Pannonian region

Abstract Clino- and orthopyroxenes in anhydrous spinel peridotite xenoliths from Pliocene alkali basalts of the western Pannonian Basin have been analysed for trace elements by laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS). Clinopyroxenes show highly variable mantle normalized REE (rare earth elements) patterns but basically can be classified into three major groups: LREE-depleted, LREE-enriched and U-shaped patterns. As the REE patterns of clinopyroxenes usually reflect the REE patterns of the host peridotite, the three major REE patterns define three geochemically different groups of xenoliths. LREE-depleted xenoliths generally have undeformed protogranular textures, while the more deformed xenoliths with porphyroclastic and equigranular textures have LREE-enriched trace element patterns. The U-shaped pattern is very distinctive and is generally associated with poikilitic textures. The HREE content of the clinopyroxenes suggest that most of the xenoliths experienced less than15% partial melting, with the lowest degree occurring in the LREE-depleted xenoliths, and the highest degree in LREE-enriched xenoliths. Cryptic metasomatism frequently accompanies deformation. Metasomatic enrichment of incompatible trace elements can be observed not only in clinopyroxenes but also in coexisting orthopyroxenes. The metasomatic agents were probably alkaline mafic melts of asthenospheric origin and some may relate to upper Cretaceous alkali lamprophyre magmatism. Geochemical signatures of subduction-related melts or fluids have not been found in the anhydrous LREE-enriched xenoliths, although poikilitic xenoliths with U-shaped normalized REE patterns may indicate the influence of subduction-related melts.

Genesis of garnets in some magmatic rocks from Hungary

Garnets from Miocene di-normative, medium-K andesites as well as from a Mesozoic fine-grained albite granite have been petrologically investigated. The chemical compositions of the garnets from the andesites as determined by electron microprobe (alm 57–65,pyr 14–22,gross 10–24,spess 2–5, -all in mol.-%) are compatible with the garnets being high pressure megacrysts. Garnets from the granite (alm 71–74,pyr 12–18,gross 3.5–5.5,spess 5.6–11) apparently crystallized in a low pressure environment. They are believed to have formed in an autometasomatic event.

Origin and significance of poikilitic and mosaic peridotite xenoliths in the western Pannonian Basin: geochemical and petrological evidences

Peridotite xenoliths erupted by alkali basaltic volcanoes in the western Pannonian Basin can be divided into two fundamentally contrasting groups. Geochemical characteristics of the abundant protogranular, porphyroclastic and equigranular nodules suggest that these samples originate from an old consolidated and moderately depleted lithospheric mantle domain. In contrast, the geochemical features of the worldwide rare, but in the Pannonian Basin relatively abundant, poikilitic xenoliths attest to a more complex evolution. It has been argued that the origin of the peculiar texture and chemistry may be intimately linked to melt/rock reactions at successively decreasing liquid volumes in a porous melt flow system. The most likely site where such reactions can take place is the asthenosphere–lithosphere boundary. In this context, poikilitic xenoliths may provide petrological and geochemical evidence for reactions between magmatic liquids issued from the uprising asthenosphere and the solid mantle rocks of the lithosphere. These reactions are important agents of the thermal erosion of the lithosphere; thus, they could have considerably contributed to the thinning of the lithosphere in the Pannonian region. We suggest that in the Pannonian Basin, there could be a strong relation between the unusual abundance of poikilitic mantle xenoliths and the strongly eroded lithosphere.

Petrology of a new basalt occurrence in Hungary

SummaryA new occurrence of basalt (minimum K/Ar age 57.9 ± 2.2 m.y.) is reported from Budaliget, near Budapest. Major and minor element concentrations show that the basalts are alkaline and potassic in nature ranging from olivine tholeiite to moderately undersaturated basanite. High mg-values and concentrations of Ni and Cr indicate that some of the samples may represent primary compositions. High pressure accidental xenoliths, xenocrysts and cognate megacrysts are frequent and the chemical zoning patterns of olivine and pyroxene phenocrysts indicate a complex evolution and polibaric conditions for the crystallization. The discovery of the new basalt occurrence is important from a geodynamical point of view: prior to the last two major geodynamical events (Plio-Pleistocene rifting with associated alkali basaltic volcanism and collision of microplates with associated Miocene calk-alkaline volcanism) the continental lithosphere below NE Transdanubia may have experienced another rifting period in the Paleocene or Upper Cretaceous.ZusammenfassungAus der Nähe von Budapest (Budaliget) wird ein neues Basaltvorkommen (minimum K/Ar Alter 57.9 ± 2.2 m. J.) beschrieben. Die Konzentrationen der Haupt- und Spurenelemente zeigen dass die Basalte Kali-betont sind und dass sie zwischen Olivintholeiiten und mässig untersättigten Basaniten variieren. Hohe mg-Zahlen sowie Ni- und Cr-Konzentrationen sprechen dafür, dass die Proben zum Teil primäre Zusammensetzungen aufweisen. Xenolithe mit Hochdruckparagenesen, Xenokristalle und cognate Megakristalle kommen haufig vor. Der chemische Zonarbau von Olivinund Pyroxenphenokristallen deutet auf eine komplexe Kristallisationsgeschichte bei wechselnden Druck hin. Die Entdeckung dieses neuen Basaltvorkommens ist von geodynamischer Bedeutung: Vor den letzten zwei geodynamischen Ereignissen (a) Entstehung von Rifttekonik im Plio-Pleistozän mit alkalibasaltischem Vulkanismus und (b) Kollision von verschiedenen Mikroplatten begleitet von miozänem kalkalkalischem Vulkanismus war die Lithossphäre unterhalb von NE Transdanubien einer weiteren Riftperiode im Paleozän oder in der oberen Kreide ausgesetzt.