Your search keyword '"Genge MJ"' showing total 5 results

1. Electrostatic levitation of volcanic ash into the ionosphere and its abrupt effect on climate

Author

Genge, MJ and Science and Technology Facilities Council (STFC)

Subjects

Geochemistry & Geophysics, PLUME, Science & Technology, PINATUBO ERUPTION, IMPACT, Physical Sciences, 04 Earth Sciences, DUST LEVITATION, Geology, ELECTRIFICATION

Abstract

Large volcanic eruptions cause short-term climate change owing to the convective rise of fine ash and aerosols into the stratosphere. Volcanic plumes are, however, also associated with large net electrical charges that can also influence the dynamics of their ash particles. Here I show that electrostatic levitation of ash from plumes with a net charge is capable of injecting volcanic particles

Published

2018

2. Diagenetically altered fossil micrometeorites suggest cosmic dust is common in the geological record

Author

Suttle, M, Genge, MJ, and Science and Technology Facilities Council (STFC)

Subjects

Geochemistry & Geophysics, Science & Technology, SEA, 02 Physical Sciences, METEORITES, 04 Earth Sciences, DIAGENESIS, replacement, CLASSIFICATION, ATMOSPHERIC ENTRY, ORDOVICIAN, ACCRETION RATE, ROCKS, Physical Sciences, fossil micrometeorites, iron silicide, cosmic spherule, I-type, SEDIMENTS, SPHERULES

Abstract

We report the discovery of fossil micrometeorites from Late Cretaceous chalk. Seventy-six cosmic spherules were recovered from Coniacian (87±1 Ma) sediments of the White Chalk Supergroup. Particles vary from pristine silicate and iron-type spherules to pseudomorphic spherules consisting of either single-phase recrystallized magnetite or Fe-silicide. Pristine spherules are readily identified as micrometeorites on the basis of their characteristic mineralogies, textures and compositions. Both magnetite and silicide spherules contain dendritic crystals and spherical morphologies, testifying to rapid crystallisation of high temperature iron-rich metallic and oxide liquids. These particles also contain spherical cavities, representing weathering and removal of metal beads and irregular cavities, representing vesicles formed by trapped gas during crystallization; both features commonly found among modern Antarctic Iron-type (I-type) cosmic spherules. On the basis of textural analysis, the magnetite and Fe-silicide spherules are shown to be I-type cosmic spherules that have experienced complete secondary replacement during diagenesis (fossilization). Our results demonstrate that micrometeorites, preserved in sedimentary rocks, are affected by a suite of complex diagenetic processes, which can result in disparate replacement minerals, even within the same sequence of sedimentary beds. As a result, the identification of fossil micrometeorites requires careful observation of particle textures and comparisons with modern Antarctic collections. Replaced micrometeorites imply that geochemical signatures the extraterrestrial dust are subject to diagenetic remobilisation that limits their stratigraphic resolution. However, this study demonstrates that fossil, pseudomorphic micrometeorites can be recognised and are likely common within the geological record.

Published

2017

3. An urban collection of modern-day large micrometeorites: Evidence for variations in the extraterrestrial dust flux through the Quaternary

Author

Genge, MJ, Larsen, J, Van Ginneken, M, Suttle, M, and Science and Technology Facilities Council (STFC)

Subjects

Geochemistry & Geophysics, Science & Technology, COSMIC SPHERULES, Physical Sciences, 04 Earth Sciences, Geology, Géologie, QE515

Abstract

We report the discovery of significant numbers (500) of large micrometeorites (>100 mm) from rooftops in urban areas. The identification of particles as micrometeorites is achieved on the basis of their compositions, mineralogies, and textures. All particles are silicate-dominated (S type) cosmic spherules with subspherical shapes that form by melting during atmospheric entry and consist of quench crystals of magnesian olivine, relict crystals of forsterite, and iron-bearing olivine within glass. Four particles also contain Ni-rich metal-sulfide beads. Bulk compositions are chondritic apart from depletions in the volatile, moderately volatile, and siderophile elements, as observed in micrometeorites from other sources. The reported particles are likely to have fallen on Earth in the past 6 yr and thus represent the youngest large micrometeorites collected to date. The relative abundance ratio of barred olivine to cryptocrystalline spherule types in the urban particles of 1.45 is shown to be higher than a Quaternary average of ~0.9, suggesting variations in the extraterrestrial dust flux over the past 800 k.y. Changes in the entry velocities of dust caused by quasi-periodic gravitational perturbation during transport to Earth are suggested to be responsible. Variations in cosmic spherule abundance within the geologic column are thus unavoidable and can be a consequence of dust transport as well as major dust production events., SCOPUS: ar.j, info:eu-repo/semantics/published

Published

2017

4. Vesicle dynamics during the atmospheric entry heating of cosmic spherules

Author

Genge, MJ and Science and Technology Facilities Council (STFC)

Subjects

Geochemistry & Geophysics, Science & Technology, ICE, TRANSANTARCTIC MOUNTAINS, DUST, RECORD, Condensed Matter::Soft Condensed Matter, MODEL, 0201 Astronomical And Space Sciences, SILICATE MELTS, 0403 Geology, LIQUIDS, ANTARCTIC MICROMETEORITES, Physical Sciences, 0402 Geochemistry, COLLECTION

Abstract

Cosmic spherules are unique igneous objects that form by melting due to gas drag heating during atmospheric entry heating. Vesicles are an important component of many cosmic spherules since they suggest their precursors had finite volatile contents. Vesicle abundances in spherules decrease through the series porphyritic, glassy, barred, to cryptocrystalline spherules. Anomalous hollow spherules, with large off-centre vesicles occur in both porphyritic and glassy spheres. Numerical simulation of the dynamic behaviour of vesicles during atmospheric flight is presented that indicates vesicles rapidly migrate due to deceleration and separate from non-porphyritic particles. Modest rotation rates of tens of radians s-1 are, however, sufficient to impede loss of vesicles and may explain the presence of small solitary vesicles in barred, cryptocrystalline and glassy spherules. Rapid rotation at spin rates of several thousand radians s-1 are required to concentrate vesicles at the rotational axis and leads to rapid growth by coalescence and either separation or retention depending on the orientation of the rotational axis. Complex rapid rotations that concentrate vesicles in the core of particles are proposed as a mechanism for the formation of hollow spherules. High vesicle contents in porphyritic spherules suggest volatile-rich precursors, however, calculation of volatile retention indicates these have lost >99.9% of volatiles to degassing prior to melting. The formation of hollow spherules, by rapid spin, necessarily implies pre-atmospheric rotations of several thousand radians s-1. These particles are suggested to represent immature dust, recently released from parent bodies, in which rotations have not been slowed by magnetic damping.

Published

2016

5. The Origins of I-type Spherules and the Atmospheric Entry of Iron Micrometeoroids

Author

Genge, MJ and Science and Technology Facilities Council (STFC)

Subjects

Geochemistry & Geophysics, PLATINUM-GROUP NUGGETS, Science & Technology, DEEP-SEA SEDIMENTS, METEORITES, NICKEL, ICE, DUST, OXYGEN, 0201 Astronomical And Space Sciences, 0403 Geology, COSMIC SPHERULES, ANTARCTIC MICROMETEORITES, Physical Sciences, 0402 Geochemistry, COLLECTION

Abstract

The Earth's extraterrestrial dust flux includes a wide variety of dust particles that include FeNi metallic grains. During their atmospheric entry iron micrometeoroids melt and oxidize to form cosmic spherules termed I-type spherules. These particles are chemically resistant and readily collected by magnetic separation and are thus the most likely micrometeorites to be recovered from modern and ancient sediments. Understanding their behavior during atmospheric entry is crucial in constraining their abundance relative to other particle types and the nature of the zodiacal dust population at 1 AU. This paper presents numerical simulations of the atmospheric entry heating of iron meteoroids in order to investigate the abundance and nature of these materials. The results indicate that iron micrometeoroids experience peak temperatures 300-800K higher than silicate particles explaining the rarity of unmelted iron particles which can only be present at sizes of

Published

2016