Planetary surfaces

Enceladus and the Icy Moons of Saturn

University of Arizona Press, 2018

Authors:

Paul M Schenk, Roger N Clark, Carly JA Howett, Anne J Verbiscer, J Hunter Waite

Abstract:

As a new volume in the Space Science Series, Enceladus and the Icy Moons of Saturn brings together nearly eighty of the world’s top experts writing more than twenty chapters to set the foundation for what we currently understand, while ...

Constraining the period of the ringed secondary companion to the young star J1407 with photographic plates

Astronomy and Astrophysics EDP Sciences 619:November 2018 (2018) A157

Authors:

Rt Mentel, Ma Kenworthy, Da Cameron, El Scott, Sn Mellon, R Hudec, Jl Birkby, Ee Mamajek, A Schrimpf, De Reichart, Jb Haislip, Vv Kouprianov, F-J Hambsch, T-G Tan, K Hills, Je Grindlay, Je Rodriguez, Mb Lund, Rb Kuhn

Abstract:

Context. The 16 Myr old star 1SWASP J140747.93-394542.6 (V1400 Cen) underwent a series of complex eclipses in May 2007, interpreted as the transit of a giant Hill sphere filling debris ring system around a secondary companion, J1407b. No other eclipses have since been detected, although other measurements have constrained but not uniquely determined the orbital period of J1407b. Finding another eclipse towards J1407 will help determine the orbital period of the system, the geometry of the proposed ring system and enable planning of further observations to characterize the material within these putative rings.

Aims. We carry out a search for other eclipses in photometric data of J1407 with the aim of constraining the orbital period of J1407b.

Methods. We present photometry from archival photographic plates from the Harvard DASCH survey, and Bamberg and Sonneberg Observatories, in order to place additional constraints on the orbital period of J1407b by searching for other dimming and eclipse events. Using a visual inspection of all 387 plates and a period-folding algorithm we performed a search for other eclipses in these data sets.

Results. We find no other deep eclipses in the data spanning from 1890 to 1990, nor in recent time-series photometry from 2012–2018.

Conclusions. We rule out a large fraction of putative orbital periods for J1407b from 5 to 20 yr. These limits are still marginally consistent with a large Hill sphere filling ring system surrounding a brown dwarf companion in a bound elliptical orbit about J1407. Issues with the stability of any rings combined with the lack of detection of another eclipse, suggests that J1407b may not be bound to J1407.

Spectroscopic direct detection of exoplanets

Chapter in Handbook of Exoplanets, Springer (2018) 1485-1508

Abstract:

The spectrum of an exoplanet reveals the physical, chemical, and biological processes that have shaped its history and govern its future. However, observations of exoplanet spectra are complicated by the overwhelming glare of their host stars. This chapter focuses on high-resolution spectroscopy (HRS) (R = 25, 000–100, 000), which helps to disentangle and isolate the exoplanet’s spectrum. At high spectral resolution, molecular features are resolved into a dense forest of individual lines in a pattern that is unique for a given molecule. For close-in planets, the spectral lines undergo large Doppler shifts during the planet’s orbit, while the host star and Earth’s spectral features remain essentially stationary, enabling a velocity separation of the planet. For slower-moving, wide-orbit planets, HRS, aided by high contrast imaging, instead isolates their spectra using their spatial separation. The lines in the exoplanet spectrum are detected by comparing them with high resolution spectra from atmospheric modelling codes; essentially a form of fingerprinting for exoplanet atmospheres. This measures the planet’s orbital velocity and helps define its true mass and orbital inclination. Consequently, HRS can detect both transiting and non-transiting planets. It also simultaneously characterizes the planet’s atmosphere, due to its sensitivity to the depth, shape, and position of the planet’s spectral lines. These are altered by the planet’s atmospheric composition, structure, clouds, and dynamics, including day-to-night winds and its rotation period. This chapter describes the HRS technique in detail, highlighting its successes in exoplanet detection and characterization, and concludes with the future prospects of using HRS to identify biomarkers on nearby rocky worlds and map features in the atmospheres of giant exoplanets.

Composition of Pluto’s small satellites: Analysis of New Horizons spectral images

Icarus Elsevier 315 (2018) 30-45

Authors:

Jason C Cook, Cristina M Dalle Ore, Silvia Protopapa, Richard P Binzel, Richard Cartwright, Dale P Cruikshank, Alissa Earle, William M Grundy, Kimberly Ennico, Carly Howett, Donald E Jennings, Allen W Lunsford, Catherine B Olkin, Alex H Parker, Sylvain Philippe, Dennis Reuter, Bernard Schmitt, John A Stansberry, S Alan Stern, Anne Verbiscer, Harold A Weaver, Leslie A Young

Methane distribution on Pluto as mapped by the New Horizons Ralph/MVIC instrument

Icarus Elsevier 314 (2018) 195-209

Authors:

Alissa M Earle, W Grundy, CJA Howett, CB Olkin, AH Parker, F Scipioni, RP Binzel, RA Beyer, JC Cook, DP Cruikshank, CM Dalle Ore, K Ennico, S Protopapa, DC Reuter, PM Schenk, B Schmitt, SA Stern, HA Weaver, LA Young, The New Horizons Surface Composition Theme Team