Rubin-LSST

MIGHTEE: The MeerKAT International GHz Tiered Extragalactic Exploration

IOP Conference Series Materials Science and Engineering IOP Publishing 198:1 (2017) 012014

Authors:

A Russ Taylor, Matt Jarvis

Transforming Libraries and Archives through Crowdsourcing

D-Lib Magazine CNRI Acct 23:5/6 (2017)

Authors:

Victoria Van Hyning, Samantha Blickhan, Laura Trouille, Chris Lintott

Performance of algorithms that reconstruct missing transverse momentum in √s = 8 TeV proton–proton collisions in the ATLAS detector

European Physical Journal C Spinger Verlag 77:241 (2017) 1-46

Authors:

G Aad, B Abbott, J Abdallah, G Artoni, AJ Barr, K Becker, JK Behr, L Beresford, AM Cooper-Sarkar, M Crispin Ortuzar, A Dafinca, E Davis, JA Frost, EJ Gallas, S Gupta, C Gwenlan, D Hall, CP Hays, J Henderson, J Howard, TB Huffman, C Issever, CW Kalderon, LA Kogan, A Lewis, K Nagi, RB Nickerson, MA Pickering, NC Ryder, JC-L Tseng, GHA Viehjauser, AR Weidberg, J Zhong, J Zhong

Abstract:

The reconstruction and calibration algorithms used to calculate missing transverse momentum ([Formula: see text] ) with the ATLAS detector exploit energy deposits in the calorimeter and tracks reconstructed in the inner detector as well as the muon spectrometer. Various strategies are used to suppress effects arising from additional proton-proton interactions, called pileup, concurrent with the hard-scatter processes. Tracking information is used to distinguish contributions from the pileup interactions using their vertex separation along the beam axis. The performance of the [Formula: see text] reconstruction algorithms, especially with respect to the amount of pileup, is evaluated using data collected in proton-proton collisions at a centre-of-mass energy of 8 [Formula: see text] during 2012, and results are shown for a data sample corresponding to an integrated luminosity of [Formula: see text]. The simulation and modelling of [Formula: see text]  in events containing a Z boson decaying to two charged leptons (electrons or muons) or a W boson decaying to a charged lepton and a neutrino are compared to data. The acceptance for different event topologies, with and without high transverse momentum neutrinos, is shown for a range of threshold criteria for [Formula: see text] , and estimates of the systematic uncertainties in the [Formula: see text]  measurements are presented.

Extreme Jet Ejections from the Black Hole X-ray Binary V404 Cygni

(2017)

Authors:

AJ Tetarenko, GR Sivakoff, JCA Miller-Jones, EW Rosolowsky, G Petitpas, M Gurwell, J Wouterloot, R Fender, S Heinz, D Maitra, SB Markoff, S Migliari, MP Rupen, AP Rushton, DM Russell, TD Russell, CL Sarazin

Galaxy Zoo: the interplay of quenching mechanisms in the group environment

Monthly Notices of the Royal Astronomical Society Oxford University Press 469:3 (2017) 3670-3687

Authors:

Rebecca J Smethurst, Christopher Lintott, SP Bamford, RE Hart, Sandor J Kruk, KL Masters, RC Nichol, BD Simmons

Abstract:

Does the environment of a galaxy directly influence the quenching history of a galaxy? Here we investigate the detailed morphological structures and star formation histories of a sample of SDSS group galaxies with both classifications from Galaxy Zoo 2 and NUV detections in GALEX. We use the optical and NUV colours to infer the quenching time and rate describing a simple exponentially declining SFH for each galaxy, along with a control sample of field galaxies. We find that the time since quenching and the rate of quenching do not correlate with the relative velocity of a satellite but are correlated with the group potential. This quenching occurs within an average quenching timescale of ∼2.5 Gyr from star forming to complete quiescence, during an average infall time (from ∼10R200 to 0.01R200) of ∼2.6 Gyr. Our results suggest that the environment does play a direct role in galaxy quenching through quenching mechanisms which are correlated with the group potential, such as harassment, interactions or starvation. Environmental quenching mechanisms which are correlated with satellite velocity, such as ram pressure stripping, are not the main cause of quenching in the group environment. We find that no single mechanism dominates over another, except in the most extreme environments or masses. Instead an interplay of mergers, mass & morphological quenching and environment driven quenching mechanisms dependent on the group potential drive galaxy evolution in groups.