Adrian Martindale (on behalf of MIXS team) University of Leicester

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Presentation transcript:

Adrian Martindale (on behalf of MIXS team) University of Leicester Future observations of Mercury with the Mercury Imaging X-ray Spectrometer Adrian Martindale (on behalf of MIXS team) University of Leicester

Contents Instrument Science themes MIXS / XRS Performance MIXS Flight Model Instrument Science themes MIXS / XRS “XRS baseline” Complementarity Combination of data Performance Spectral Coverage Key questions 16-18/06/2015

MIXS Instrument MIXS is a dual-channel X-ray imaging spectrometer designed to operate at two spatial resolutions to measure the: 1) – Global/local surface composition 2) – Surface-magnetosphere/ magnetosphere-exosphere interactions MIXS-T is a Wolter-I X-ray telescope with high spatial resolution (~few km) MIXS-C is a profiled collimator designed for large grasp (high signal) on 100s km scales 16-18/06/2015

MIXS / XRS MIXS and XRS are complementary XRS has provided: Excellent coverage in the N-hemisphere Strong constraints on major rock-forming elements ID of unexpected species (e.g. 2-5wt% S) MIXS will provide: Global coverage at improved resolution (orbit & instrumentation) Provide higher sensitivity (reduced background and better spectral resolution) Provide high resolution and/or higher sensitivity during bright flares More measurable elements Lower energies & more resolvable lines 16-18/06/2015

Cross-calibration of data sets Discussing with MERTIS calibration on same samples We are interested to try to link the MIXS and XRS datasets by experimentation with ground reference models. Observe common sample(s) in controlled conditions. Discussion with XRS team needed. Wieder et.al. Icarus 235 (2014) 170–186 16-18/06/2015

Science themes Surface elemental composition mapping More elements More spatial resolution, particularly in S (orbit & design) Remote sensing the Environment Magnetospheric effects Night-side observations offer major science SWCX Off-pointings Magnetic equator Equator 16-18/06/2015

MESSENGER XRS (gas proportional counter) spectrum of Mercury Science Performance MIXS flight model spectrum of terrestrial basalt sample from recent calibration tests MESSENGER XRS (gas proportional counter) spectrum of Mercury Weider et.al. 2012 (JGR) Note here on main points to make… The novelty of the MIXS optics and mechanical design allows use of a state-of-the-art silicon detector with greatly improved sensitivity to geological composition. 16-18/06/2015

Science Performance Note here on main points to make… 16-18/06/2015

Key questions - surface What is the composition distribution in the S-hemisphere? How does elemental abundance vary within single geological units? What does this tell us about variation in magma sources? High resolution imaging & high sensitivity we want to build on XRS results What is the darkening agent in LRM? Cometary carbon proposed… What composition changes occur at the edges of the perplexing high magnesium region? What volatile species are implicated in; hollow formations? explosive volcanic eruption? What is the distribution of lower abundance elements? E.g. is there a strong spatial distribution of the 2-5% S revealed by XRS? Is there evidence of surface modification? e.g. polar Na abundance changes reported by Peplowski. What is the elemental composition of the diffuse red spots associated with volcanic vents? Can we confirm the presence of Cl (~0.1-0.3wt%) and the planetary scale variations in Cl and K observed by GRS (e.g. Evans 2015) 16-18/06/2015

Trace elements? Na P Cl Data up to 15keV available Requires adjustment of instrument configuration 16-18/06/2015

Key questions - Environment What is the mechanism that leads to “magnetospheric (a)symmetries” in the night-side X-ray signal? MIXS will offer higher sensitivity More comprehensive coverage of the S-hemisphere. More “uncontaminated” X-ray lines making it easier to distinguish instrumental background from planetary signal (e.g. no Mg filter). Can we make multi-point measurements of the precipitating particles e.g. with particle instruments on MPO and MMO as well as the remote location on the planet? Can we get composition of permanently shadowed craters from precipitating ions? Can we observe the X‐ray spectrum originating from the exosphere in tangential geometry over the limb? Off-pointings needed Exospheric species via absorption lines in background-sky measurements? Solar wind ions  charge exchange lines ~0.57keV Energy range currently extends down to <200eV with good spectral resolution but the tight spectroscopy requirements to measure CX mean success depends on radiation damage. 16-18/06/2015