The James Webb Space Telescope's Medium Resolution Spectrometer (MRS), will
offer nearly 2 orders of magnitude improvement in sensitivity and >3X
improvement in spectral resolution over our previous space-based mid-IR
spectrometer, the Spitzer IRS. In this paper, we make predictions for
spectroscopic pointed observations and serendipitous detections with the MRS.
Specifically, pointed observations of Herschel sources require only a few
minutes on source integration for detections of several star-forming and active
galactic nucleus lines, out to z$=$3 and beyond. But the same data will also
include tens of serendipitous 0$łesssim$z$łesssim$4 galaxies per field with
infrared luminosities ranging $\sim10^6-10^13$L$_ødot$. In particular, for
the first time and for free we will be able to explore the
$L_IR<10^9L_ødot$ regime out to $z\sim3$. We estimate that with
$\sim$100 such fields, statistics of these detections will be sufficient to
constrain the evolution of the low-$L$ end of the infrared luminosity function,
and hence the star formation rate function. The above conclusions hold for a
wide range in potential low-$L$ end of the IR luminosity function, and
accounting for the PAH deficit in low-$L$, low-metallicity galaxies.
Description
[1701.07239] Exploring the evolution of star formation and dwarf galaxy properties with JWST/MIRI serendipitous spectroscopic surveys
%0 Generic
%1 bonato2017exploring
%A Bonato, Matteo
%A Sajina, Anna
%A De Zotti, Gianfranco
%A McKinney, Jed
%A Baronchelli, Ivano
%A Negrello, Mattia
%A Marchesini, Danilo
%A Roebuck, Eric
%A Shipley, Heath
%A Kurinsky, Noah
%A Pope, Alexandra
%A Noriega-Crespo, Alberto
%A Yan, Lin
%A Kirkpatrick, Allison
%D 2017
%K JWST detection formation star
%T Exploring the evolution of star formation and dwarf galaxy properties
with JWST/MIRI serendipitous spectroscopic surveys
%U http://arxiv.org/abs/1701.07239
%X The James Webb Space Telescope's Medium Resolution Spectrometer (MRS), will
offer nearly 2 orders of magnitude improvement in sensitivity and >3X
improvement in spectral resolution over our previous space-based mid-IR
spectrometer, the Spitzer IRS. In this paper, we make predictions for
spectroscopic pointed observations and serendipitous detections with the MRS.
Specifically, pointed observations of Herschel sources require only a few
minutes on source integration for detections of several star-forming and active
galactic nucleus lines, out to z$=$3 and beyond. But the same data will also
include tens of serendipitous 0$łesssim$z$łesssim$4 galaxies per field with
infrared luminosities ranging $\sim10^6-10^13$L$_ødot$. In particular, for
the first time and for free we will be able to explore the
$L_IR<10^9L_ødot$ regime out to $z\sim3$. We estimate that with
$\sim$100 such fields, statistics of these detections will be sufficient to
constrain the evolution of the low-$L$ end of the infrared luminosity function,
and hence the star formation rate function. The above conclusions hold for a
wide range in potential low-$L$ end of the IR luminosity function, and
accounting for the PAH deficit in low-$L$, low-metallicity galaxies.
@misc{bonato2017exploring,
abstract = {The James Webb Space Telescope's Medium Resolution Spectrometer (MRS), will
offer nearly 2 orders of magnitude improvement in sensitivity and >3X
improvement in spectral resolution over our previous space-based mid-IR
spectrometer, the Spitzer IRS. In this paper, we make predictions for
spectroscopic pointed observations and serendipitous detections with the MRS.
Specifically, pointed observations of Herschel sources require only a few
minutes on source integration for detections of several star-forming and active
galactic nucleus lines, out to z$=$3 and beyond. But the same data will also
include tens of serendipitous 0$\lesssim$z$\lesssim$4 galaxies per field with
infrared luminosities ranging $\sim10^6-10^{13}$L$_{\odot}$. In particular, for
the first time and for free we will be able to explore the
$L_{IR}<10^{9}L_{\odot}$ regime out to $z\sim3$. We estimate that with
$\sim$100 such fields, statistics of these detections will be sufficient to
constrain the evolution of the low-$L$ end of the infrared luminosity function,
and hence the star formation rate function. The above conclusions hold for a
wide range in potential low-$L$ end of the IR luminosity function, and
accounting for the PAH deficit in low-$L$, low-metallicity galaxies.},
added-at = {2017-01-26T10:18:10.000+0100},
author = {Bonato, Matteo and Sajina, Anna and De Zotti, Gianfranco and McKinney, Jed and Baronchelli, Ivano and Negrello, Mattia and Marchesini, Danilo and Roebuck, Eric and Shipley, Heath and Kurinsky, Noah and Pope, Alexandra and Noriega-Crespo, Alberto and Yan, Lin and Kirkpatrick, Allison},
biburl = {https://www.bibsonomy.org/bibtex/235a098aa1c089bfb7b3162695b8e725f/miki},
description = {[1701.07239] Exploring the evolution of star formation and dwarf galaxy properties with JWST/MIRI serendipitous spectroscopic surveys},
interhash = {d6d10ba3ac7cb4a6618a84f229fa1fd8},
intrahash = {35a098aa1c089bfb7b3162695b8e725f},
keywords = {JWST detection formation star},
note = {cite arxiv:1701.07239Comment: 31 pages, 12 figures, accepted for publication in ApJ},
timestamp = {2017-01-26T10:18:10.000+0100},
title = {Exploring the evolution of star formation and dwarf galaxy properties
with JWST/MIRI serendipitous spectroscopic surveys},
url = {http://arxiv.org/abs/1701.07239},
year = 2017
}