Regional setting With the exception of
Greece and
Italy, the most recent
volcanic activity in Continental Europe occurred between 40,000 and 6,500 years ago in
Garrotxa, the
Massif Central and the
Vulkaneifel. Volcanism in the region of
Carpathia and
Pannonia has been ongoing since 20 million years ago but has decreased during the
Quaternary. No eruptions took place in the
Holocene. The last volcanism occurred at Ciomadul in the last glacial age. Sparse
basaltic volcanism has also taken place in the area, forming
monogenetic volcanic fields. A
volcanic arc lies in the
Carpathians. In its southern segment, also known as the Călimani (Kelemen) – Gurghiu (Görgényi) – Harghita (Hargita) chain, volcanism has migrated between 9 and 0.22 million years ago southward, forming a volcanic chain. Magma output progressively decreased during time, with early volcanoes being large
stratovolcanoes sometimes featuring
caldera-forming eruptions, while more recent activity includes
monogenetic volcanoes although more precise dating and volume estimation efforts at Ciomad have found an increase of eruption rates over time. This volcanism occurs in a setting where the collision between the
Eurasian Plate and the Tisza-Dacia
microplate took place, preceded by a stage of
subduction involving a narrow
ocean. This is part of the collision between the
African Plate and the Eurasian Plate;
subduction may still be underway in the area of the Carpathians. The , which is away from Ciomadul, features ongoing
earthquake activity; deep earthquakes suggest that a remnant of a
slab exists beneath the Vrancea Zone. This
tectonic setting may also be responsible for ongoing exhumation in the southeastern Carpathians, volcanism at Ciomadul and the
Perșani volcanic field, south of Ciomad, which was concurrently active to the older Ciomadul activity. Other theories on Ciomadul's volcanic activity imply
delamination of the
lithosphere or
roll-back of the subduction zone. Volcanism in this chain is
calc-alkaline, yielding both
andesite,
dacite, and
rhyolite. Three million years ago, a change in the chemistry of volcanism occurred, with an increased content of
potassium in the rocks. This change in composition geographically coincided with the volcanic activity crossing a
lineament known as the Trotuș line.
Volcano Ciomadul is located in the southeastern
Carpathians, at the end of the Călimani (Kelemen) – Gurghiu (Görgényi) – Harghita (Hargita) volcanic chain, and is also known as Csomád in Hungarian. The
gorge of the
Olt River separates Ciomadul from the Harghita Mountains. The towns of
Băile Tușnad and
Bixad are close to the volcano, and a road leads up the volcano from the southeast and goes past the Mohoș swamp to
Lake Sfânta Ana. The basement of the volcano is formed by
flysch of
Cretaceous age and by older volcanics; in some places volcanic rocks overlie fluvial deposits. Places around Ciomadul were first mentioned in 1349; the Saxon mineralogist Johann Ehrenwert Fichtel was the first to interpret it as a volcano, in 1780. The idea that Ciomadul could be a still active volcano was first proposed in the same year on the basis of its young appearance and the release of gas. These discoveries drew scholars and visitors to the volcano and the first scientific analysis of the volcano was published just eight years later. While a publication in 1964 postulated that the
tuffs of Ciomadul were reworked
Pliocene volcanites, the late
Pleistocene age was established soon afterwards. The volcano is the youngest volcanic centre in the Carpathians and has a more rugged appearance than the surrounding mountains. Ciomadul is formed by a complex of
lava domes and other volcanic material that form a south-tilting ridge that rises above the surrounding Lower Ciuk Basin. Individual lava domes form cone-shaped hills, which reach heights of and widths of . Individual domes include Haramul Ierbos (Fű-Haram in Hungarian), Haramul Mare (Nagy-Haram), Haramul Mic (Kis-Haram), Vf. Cetății (Vár-tető), Vf. Comloș (Komlós-tető), Vf. Surduc (Szurdok-tető) and Dealul Mare southeast from the main complex. The central cluster of domes is elliptical and tectonic
faults influenced their growth. The highest point of the complex is Ciomadul Mare (Nagy-Csomád) with an altitude of . Some domes were later affected by
erosion,
explosive activity or
fumarolic alteration. The whole volcanic complex covers a surface area of , and is surrounded by a circular/semicircular plain made of volcanic debris. The lava dome complex contains two
craters, named Mohoș and Sfânta Ana. They were formed in the previously existing lava domes which form the western margin of the craters, while products of
explosive eruptions crop out in the east. The Sfânta Ana crater is wide and deep beneath the rim, comparable with the crater of
El Chichón volcano in
Mexico. This crater lacks a breach and is relatively unaffected by erosion. It contains a
crater lake, which once may have been over deep. This lake is known as Lake Sfânta Ana () and lies at an altitude of ; its ecosystem and environment has drawn the attention of scientists for two centuries. The Mohoș crater lies at an altitude of . It is larger than Sfânta Ana with a diameter of and not as deep with its bottom lying above sea level. It is filled with a and
Sphagnum peat bog and its rim is cut by the Sfânta Ana crater. Unlike Sfânta Ana, the Mohoș crater has been breached by erosion, causing the formation of an outlet valley. Both craters were formed by
explosive eruptions and distinguishing between the deposits of both is difficult. The existence of an even larger crater with a diameter of has been suggested, encompassing both Sfânta Ana and Mohoș.
Pyroclastic flow deposits generated by Ciomadul have been found on its northeastern, southern and western slopes. They reach a distance of as much as from the volcano. At Tușnad road, one of the flows has a thickness of . Tephra fall bed,
lapilli, and surge deposits are also found, and the flow deposits contain pumice blocks. One lapilli layer, thick, from Ciomadul has been identified east of the volcano. The whole pyroclastic formation has been subdivided into three classes known as "Early Phreatomagmatic + Plinian Activity", "Middle Plinian Activity" and "Latest Sfânta Ana Phreatomagmatic Activity". Each comprise a number of individual tephra layers that were erupted 42,000—40,000, around 31,500 and 29,000—28,000 years ago. Some of these eruptions may have dammed the Olt river; when the river returned on its course it produced
lahar deposits. Other
landforms at Ciomadul include
coulees and
lava flows. The total volume of the complex is about
dense rock equivalent. Drilling has identified the existence of an
intrusion at a depth of . Finally, volcanic erosion products and tephra occur all over the volcanic complex and up to east of it. Older volcanic centres extend northwest of Ciomadul. With increasing distance they are the 2.5—1.5 million-year-old Pilisca centre, the 2.8—2.2 million-year-old Cucu centre and the 4.3—3.6 million-year-old Luci-Lazu and Șumuleu-Ciuc volcanic centres. South of Ciomadul the Murgul
shoshonites were erupted 2.3—1.5 million years ago; they represent
cryptodomes.
Andesite lava flows from Pilisca underlie the Ciomadul deposits in some places.
Composition The principal rock is
dacite, which defines a
potassium-rich
calc-alkaline suite. The rocks have a
porphyric appearance and contain few vesicles. They are also very rich in crystals, with the dominant
phenocryst-forming minerals being
biotite,
hornblende and
plagioclase. Less important are
allanite,
apatite,
clinopyroxene,
olivine,
orthopyroxene,
quartz,
sphene and
zircon. The
groundmass contains
plagioclase,
pyroxene,
silicon dioxide and
oxides of
iron and
titanium. Clots formed by various
felsic crystals are common. The composition of Ciomadul's rocks has been fairly constant throughout its evolution albeit with two shifts 1 million and 650,000 years before present, and this diversity of its components indicate that the genesis of Ciomadul magmas involved mixing between
felsic and
mafic magma. The phenocryst compositions at Ciomadul are unlike these at other volcanoes in the Carpathians. The magmas derive from the
upper mantle lithosphere, which underwent
metasomatic alteration. Compositionally, the tephras of Ciomadul have been subdivided into two groups, one called Tușnad‐type and the other Bixad‐type. A large proportion of crystals in the rocks consists of
antecrysts and
xenocrysts, making
radiometric dating of the rocks difficult. These include
amphibole,
biotite,
feldspar and
zircon. The zircons formed almost continuously over hundred thousands of years within Ciomadul's magma chamber, indicating a steady crystallization of the chamber. Differences in magma temperature, crystal content and the participation of pre-existent crystal mushes determine whether an eruption will be effusive or explosive. The temperature of the
magma chamber has been estimated to be about , with heating of over occurring before some eruptions according to thermometry calculation. Volcanic activity was most likely triggered by the injection of
basaltic magma into the
felsic magma chamber before the actual eruption, as has been observed at other silicic volcanoes around the world, but the magma chamber probably kept being recharged even between eruptions. The
amphiboles in the rocks formed at depths of . The magma output of Ciomadul is about while magma chamber recharge may have reached . == Eruptive history ==