Notes: Abstract The Miocene-Pliocene Macusani ash-flow tuffs from SE Peru, containing magmatic andalusite and muscovite, have homogeneous major element compositions, with a narrow range of SiO2 (71–74 wt%), high Al2O3 (normative corundum 〉2%; A/CNK〉1.2) and alkalis, and low FeOt, MgO, CaO, TiO2. P2O5, F, Li2O, and B2O3 are also high. The associated obsidian glasses are more felsic and peraluminous and extremely enriched in F, P, Li and B compared to the ash-flow tuffs. These are compositionally similar to Himalayan or Hercynian two-mica granites and the obsidian glasses to some rare fractionated members of the two-mica granite series. Both ash-flow tuffs and obsidian glasses show enrichments in lithophile trace elements (Be, Zn, As, Rb, Nb, Sn, Sb, Cs, Ta, W, U) and depletions in Cl, S, Sc, V, Cr, Co, Ni, Cu, Y, Mo, Hf. REE patterns for the ash-flow tuffs are fractionated (La/Lu n =13-26) with a moderate Eu anomaly and they contrast with patterns for the obsidian glasses characterized by lower total REE, lower La/Lu n and Eu/Eu*. Sr(87Sr/86Sr initial ratio= 0.721–0.726), Pb (206Pb/204Pb=18.74–19.45; 207P/204Pb= 15.66–15.72) and Nd isotopic compositions (ɛ Nd=-8.96 to-9.35) are typically crustal. Oxygen isotopic compositions are high in 18O (glasses:δ18O=+12‰; quartz:δ18O=+ 11.5 to +12.7‰). Batch melting of isotopically heterogeneous source rocks is suggested by the Sr and Pb data. In contrast to major elements, trace elements demonstrate compositional differences between erupted magmas. The last erupted magmas are less fractionated relative to the first erupted. The Macusani magmas are direct products of crustal melting. There is no evidence for mixing or assimilation by a foreign, meta- to sub-aluminous magma, although mafic magmas are considered to be likely sources of heat for melting. Source rocks dominantly consisted of metapelites. Models of magma generation based on external control of $$a_{H_2 O}$$ (H2O for melting being supplied by aqueous fluids percolating in the source region) fail to account for a number of features of the Macusani magmas. $$a_{H_2 O}$$ was internally controlled and magma generation resulted essentially from fluid-absent melting of F-muscovite combined with incipient biotite dehydration. Fluid-absent melting of F-rich muscovite occurs at higher temperatures than for pure OH-muscovite and generates a H2O-undersaturated melt. Incipient melting of biotite resulted from high heat flux and elevated temperatures (up to 800° C) in the source region. The Macusani magmas are generated as low melt fraction batches (15 vol%).

Notes: Abstract The Miocene-Pliocene Macusani volcanics, SE Peru, outcrop in three separate tectonic intermontane basins developed on a Paleozoic-Mesozoic volcano-sedimentary sequence. Several ignimbrite sheets are recognized and K-Ar dates record at least semi-continuous volcanic activity from 10 to 4 Ma in the Macusani field. The volcanics in the Macusani basin comprise crystal-rich (45% crystals) ash-flow tuffs and rare obsidians glasses, both with unusual mineralogy, similar to two-mica peraluminous leucogranites. The mineralogical assemblage (quartz, sanidine Or69–75, plagioclase, biotite, muscovite and andalusite (both coexisting in the entire volcanic field), sillimanite, schörl-rich tourmaline, cordierite-type phases, hercynitic spinel, fluor-apatite, ilmenite, monazite, zircon, niobian-rutile) is essentially constant throughout the entire Macusani field. Two distinct generations of plagioclase are recognized, viz. group I (An10–20) and group II (An30–45). Sillimanite forms abundant inclusions in nearly all phases and is earlier than andalusite which occurs as isolated phenocrysts. Biotite (Al-, Ti-, Fe- and F-rich) shows pronounced deficiencies in octahedral cations. Muscovite is also F-rich and displays limited biotitic and celadonitic substitutions. There is no systematic variation in mineral chemistry with stratigraphic position. The mineralogical data provide a basis for distinction between an early magmatic and a main magmatic stage. The early stage corresponds to the magmatic evolution at or near the source region and includes both restites and early phenocrysts. Some biotites (with textures of disequilibrium melting to Fe — Zn spinel), part of the sillimanite, apatite and monazite, possibly some tourmaline and cordierite-type phases are restites. However, the restite content of the magma was low (5 vol. % maximum). The group II plagioclase are interpreted as early phenocrysts. During this stage, temperatures were as high as 800° C, pressure was no more than 5–7.5 kbar, $$f_{O_2 }$$ was intermediate between WM and QFM and $$a_{H_2 O}$$ was low. The biotite melting textures and the coexistence of restites and early phenocrysts imply fast heating rates in the source region. The transition between the early and the main magmatic stage was abrupt (andalusite crystallization in place of sillimanite, group I vs. group II plagioclases) and suggests rapid ascent of the magma from its source region. During the main crystallization stage, temperature was 650° C or lower at a pressure of 1.5–2 kbar. $$a_{H_2 O}$$ (calculated from equilibrium between muscovite, quartz, sanidine and andalusite) are around 1, suggesting conditions close to H2O-saturation. f HF is around 1 bar but the $${{f_{H_2 O} } \mathord{\left/{\vphantom {{f_{H_2 O} } {f_{HF} }}} \right.\kern-\nulldelimiterspace} {f_{HF} }}$$ ratios are significantly different between samples. $$f_{H_2 }$$ ranges between 138 and 225 bar. This study shows that felsic, strongly peraluminous, leucogranitic magmas having andalusite and muscovite phenocrysts may be generated under H2O-undersaturated conditions.