Nikkola et al. The Brattaskjól olivine and clinopyroxene macro- crysts are often embayed and have thin composition- ally zoned rims in contact with fine-grained ground- mass mineralogy (Figure 1b). In Hvammsmúli sam- ples, conversely, the groundmass is coarse and olivine and clinopyroxene macrocrysts have broad composi- tionally zoned rims that commonly enclose ground- mass plagioclase near the macrocryst edges (Figure 1c). In addition to the zonation near crystal edges, clinopyroxene macrocrysts in both localities exhibit complex oscillatory and convolute zoning, while sec- tor zoning was not identified. The Brattaskjól olivine macrocrysts are com- monly devoid of spinel and melt inclusions. When present, the Brattaskjól melt inclusions are found in the cores of the crystals as primary or pseudosec- ondary inclusions (following the nomenclature of Roedder, 1984). Their size varies between 20 and 250µm and they are partially crystallized, containing dominantly clinopyroxene daughter minerals, silicate glass and a large bubble phase. These inclusions may also contain opaque phases, which are generally acci- dentally trapped spinel crystals. Spinel and melt in- clusions are more common in the Hvammsmúli sam- ples, and some Hvammsmúli olivines have small (usu- ally <1µm) oxide exsolutions. The textural appear- ance of melt inclusions is similar to those observed in olivine grains from Brattaskjól. These inclusions con- tain abundant clinopyroxene, minor orthopyroxene, il- menite and spinel daughter minerals, a vapour phase and interstitial silicate glass (see Björnsson, 2019). In backscattered electron images, we commonly observe a bright Fe-rich diffusion halo in olivine around the melt inclusions in Hvamsmmúli samples. This halo is missing around Brattaskjól melt inclusions. ANALYTICAL AND EXPERIMENTAL METHODS Melt inclusion homogenization experiments As melt inclusions from both localities were partially crystalline, we tried to homogenize them. Handpicked olivine crystals were placed in a graphite crucible and mixed with graphite powder in order to avoid oxi- dation during the heating experiments. We carried out three sets of experiments at temperatures of 1200, 1220 and 1240◦C. The precision of the temperature reading, calibrated to the melting points of Au, Ag and NaCl, was ±5◦C. Crucibles were placed in the high- temperature oven at the target temperature and kept there for 5 minutes. After 5 minutes, the samples were quenched in room temperature water. Olivine was re- covered after quenching and mounted in epoxy. Melt inclusions were exposed by manual polishing and in- spected under the polarizing microscope. More than 90% of the melt inclusions from Brattaskjól were ho- mogenized at 1200±5◦C, and all of them at 1220◦C. By contrast, a few crystals were observed in Hvamms- múli melt inclusions even after heating to 1240◦C. Electron microprobe analysis We separated olivine and clinopyroxene macrocrysts from crushed and sieved (Ø = 0.1–4.0 mm) rock sam- ples and determined their major and minor element compositions using a JEOL JXA-8230 electron mi- croprobe at the University of Iceland. Clinopyrox- ene was analysed in a thin section made from the Hvammsmúli sample. In total, we analysed 192 olivine and 51 clinopyroxene crystals for their core compositions, 38 spinel and 21 melt inclusions in olivine, and 47 concentration profiles (with 4–10µm spacing between analysis spots) across olivine zona- tion. Acceleration voltage and a beam current of 15 keV and 20 nA, respectively, were used for analysis of clinopyroxene, spinel and olivine zonation, whereas 10 nA beam current was used for analyses of melt in- clusions. For the high-precision trace element analy- ses of olivine cores, we used a modified version of the analysis protocol by Batanova et al. (2015) with ac- celeration voltage of 20 keV and a high beam current of 500 nA (see Nikkola et al., 2019; for details). Crys- tals of known composition were analysed to check for instrumental drift. The mineral and melt compositions are available from the authors on request. EBSD analysis Crystallographic orientations of olivine macrocrysts were resolved with electron backscatter diffraction (EBSD, Prior et al., 1999) using FEI Quanta SEM at the University of Leeds (UK). The EBSD analy- ses were performed to constrain the crystallographic 86 JÖKULL No. 69, 2019

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