Rubin-LSST

Predicting the water content of interstellar objects from galactic star formation histories

Astrophysical Journal Letters IOP Science 294 (2021) 1

Authors:

Christopher Lintott, Michele Bannister, Ted Mackereth

Abstract:

Planetesimals inevitably bear the signatures of their natal environment, preserving in their composition a record of the metallicity of their system's original gas and dust, albeit one altered by the formation processes. When planetesimals are dispersed from their system of origin, this record is carried with them. As each star is likely to contribute at least 10¹² interstellar objects (ISOs), the Galaxy's drifting population of ISOs provides an overview of the properties of its stellar population through time. Using the EAGLE cosmological simulations and models of protoplanetary formation, our modeling predicts an ISO population with a bimodal distribution in their water mass fraction: objects formed in low-metallicity, typically older, systems have a higher water fraction than their counterparts formed in high-metallicity protoplanetary disks, and these water-rich objects comprise the majority of the population. Both detected ISOs seem to belong to the lower water fraction population; these results suggest they come from recently formed systems. We show that the population of ISOs in galaxies with different star formation histories will have different proportions of objects with high and low water fractions. This work suggests that it is possible that the upcoming Vera C. Rubin Observatory Legacy Survey of Space and Time will detect a large enough population of ISOs to place useful constraints on models of protoplanetary disks, as well as galactic structure and evolution.

Building high accuracy emulators for scientific simulations with deep neural architecture search

Machine Learning: Science and Technology IOP Science 3:1 (2021) 015013

Authors:

MF Kasim, D Watson-Parris, L Deaconu, S Oliver, Peter Hatfield, DH Froula, Gianluca Gregori, M Jarvis, Samar Khatiwala, J Korenaga, Jonas Topp-Mugglestone, E Viezzer, Sam Vinko

Abstract:

Computer simulations are invaluable tools for scientific discovery. However, accurate simulations are often slow to execute, which limits their applicability to extensive parameter exploration, large-scale data analysis, and uncertainty quantification. A promising route to accelerate simulations by building fast emulators with machine learning requires large training datasets, which can be prohibitively expensive to obtain with slow simulations. Here we present a method based on neural architecture search to build accurate emulators even with a limited number of training data. The method successfully emulates simulations in 10 scientific cases including astrophysics, climate science, biogeochemistry, high energy density physics, fusion energy, and seismology, using the same super-architecture, algorithm, and hyperparameters. Our approach also inherently provides emulator uncertainty estimation, adding further confidence in their use. We anticipate this work will accelerate research involving expensive simulations, allow more extensive parameters exploration, and enable new, previously unfeasible computational discovery.

The Simons Observatory: a new open-source power spectrum pipeline applied to the Planck legacy data

(2021)

Authors:

Zack Li, Thibaut Louis, Erminia Calabrese, Hidde Jense, David Alonso, J Richard Bond, Steve K Choi, Jo Dunkley, Giulio Fabbian, Xavier Garrido, Andrew H Jaffe, Mathew S Madhavacheril, P Daniel Meerburg, Umberto Natale, Frank J Qu

MeerKAT radio detection of the Galactic black hole candidate Swift J1842.5−1124 during its 2020 outburst

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 510:1 (2021) 1258-1263

Authors:

X Zhang, W Yu, SE Motta, R Fender, P Woudt, JCA Miller-Jones, GR Sivakoff

The Hobby-Eberly Telescope Dark Energy Experiment (HETDEX) survey design, reductions, and detections

Astrophysical Journal American Astronomical Society 923:2 (2021) 217

Authors:

Karl Gebhardt, Erin Mentuch Cooper, Robin Ciardullo, Matthew Jarvis, Gavin Dalton

Abstract:

We describe the survey design, calibration, commissioning, and emission-line detection algorithms for the Hobby-Eberly Telescope Dark Energy Experiment (HETDEX). The goal of HETDEX is to measure the redshifts of over a million Lyα emitting galaxies between 1.88 < z < 3.52, in a 540 deg2 area encompassing a co-moving volume of 10.9 Gpc3. No pre-selection of targets is involved; instead the HETDEX measurements are accomplished via a spectroscopic survey using a suite of wide-field integral field units distributed over the focal plane of the telescope. This survey measures the Hubble expansion parameter and angular diameter distance, with a final expected accuracy of better than 1%. We detail the project’s observational strategy, reduction pipeline, source detection, and catalog generation, and present initial results for science verification in the COSMOS, Extended Groth Strip, and GOODS-N fields. We demonstrate that our data reach the required specifications in throughput, astrometric accuracy, flux limit, and object detection, with the end products being a catalog of emission-line sources, their object classifications, and flux-calibrated spectra.