Your search keyword '"Peng Oh, S."' showing total 11 results

1. Cosmic ray-driven galactic winds: streaming or diffusion?

Author

Wiener, Joshua, primary, Pfrommer, Christoph, additional, and Peng Oh, S., additional

Published

2017

2. Interaction of Cosmic Rays with Cold Clouds in Galactic Halos

Author

Wiener, Joshua, primary, Peng Oh, S., additional, and Zweibel, Ellen G., additional

Published

2017

3. High β effects on cosmic ray streaming in galaxy clusters.

Author

Wiener, Joshua, Zweibel, Ellen G., and Peng Oh, S.

Subjects

COSMIC rays, GALAXY clusters, GAMMA rays, MAGNETOHYDRODYNAMICS, MAGNETIC fields

Abstract

Diffuse, extended radio emission in galaxy clusters, commonly referred to as radio haloes, indicate the presence of high energy cosmic ray (CR) electrons and cluster-wide magnetic fields. We can predict from theory the expected surface brightness of a radio halo, given magnetic field and CR density profiles. Previous studies have shown that the nature of CR transport can radically effect the expected radio halo emission from clusters (Wiener, Oh & Guo 2013). Reasonable levels of magnetohydrodynamic (MHD) wave damping can lead to significant CR streaming speeds. But a careful treatment of MHD waves in a high β plasma, as expected in cluster environments, reveals damping rates may be enhanced by a factor of β1/2. This leads to faster CR streaming and lower surface brightnesses than without this effect. In this work, we re-examine the simplified, 1D Coma cluster simulations (with radial magnetic fields) of Wiener et al. (2013) and discuss observable consequences of this high β damping. Future work is required to study this effect in more realistic simulations. [ABSTRACT FROM AUTHOR]

Published

2018

4. The distribution of bubble sizes during reionization.

Author

Yin Lin, Peng Oh, S., Furlanetto, Steven R., and Sutter, P. M.

Subjects

*PROBABILITY density function, *MONTE Carlo method, *PROBABILITY in quantum mechanics, *IONIZING radiation, *RADIOACTIVITY

Abstract

A key physical quantity during reionization is the size of H II regions. Previous studies found a characteristic bubble size which increases rapidly during reionization, with apparent agreement between simulations and analytic excursion set theory. Using four different methods, we critically examine this claim. In particular, we introduce the use of the watershed algorithm - widely used for void finding in galaxy surveys - which we show to be an unbiased method with the lowest dispersion and best performance on Monte Carlo realizations of a known bubble size probability density function (PDF).We find that a friends-of-friends algorithm declares most of the ionized volume to be occupied by a network of volume-filling regions connected by narrow tunnels. For methods tuned to detect the volume-filling regions, previous apparent agreement between simulations and theory is spurious, and due to a failure to correctly account for the window function of measurement schemes. The discrepancy is already obvious from visual inspection. Instead, H II regions in simulations are significantly larger (by factors of 10-1000 in volume) than analytic predictions. The size PDF is narrower, and evolves more slowly with time, than predicted. It becomes more sharply peaked as reionization progresses. These effects are likely caused by bubble mergers, which are inadequately modelled by analytic theory. Our results have important consequences for high-redshift 21 cm observations, the mean free path of ionizing photons, and the visibility of Lyα emitters, and point to a fundamental failure in our understanding of the characteristic scales of the reionization process. [ABSTRACT FROM AUTHOR]

Published

2016

5. The flatness and sudden evolution of the intergalactic ionizing background.

Author

Munoz, Joseph A., Peng Oh, S., Davies, Frederick B., and Furlanetto, Steven R.

Subjects

*INTERSTELLAR medium, *IONIZING radiation, *COSMIC background radiation, *GALACTIC evolution, *REDSHIFT, UNIVERSE

Abstract

The ionizing background of cosmic hydrogen is an important probe of the sources and absorbers of ionizing radiation in the post-reionization universe. Previous studies showthat the ionization rate should be very sensitive to changes in the source population: as the emissivity rises, absorbers shrink in size, increasing the ionizing mean free path and, hence, the ionizing background. By contrast, observations of the ionizing background find a very flat evolution from z ~ 2-5, before falling precipitously at z ~ 6. We resolve this puzzling discrepancy by pointing out that, at z ~ 2-5, optically thick absorbers are associated with the same collapsed haloes that host ionizing sources. Thus, an increasing abundance of galaxies is compensated for by a corresponding increase in the absorber population, which moderates the instability in the ionizing background. However, by z~5-6, gas outside of haloes dominates the absorption, the coupling between sources and absorbers is lost, and the ionizing background evolves rapidly. Our halo-based model reproduces observations of the ionizing background, its flatness and sudden decline, as well as the redshift evolution of the ionizing mean free path. Our work suggests that, through much of their history, both star formation and photoelectric opacity in the universe track halo growth. [ABSTRACT FROM AUTHOR]

Published

2016

6. Foregrounds for 21-cm observations of neutral gas at high redshift

Author

Peng Oh, S., primary and Mack, Katherine J., additional

Published

2003

7. Sunyaev--Zeldovich fluctuations from the first stars?

Author

Peng Oh, S., primary, Cooray, A., additional, and Kamionkowski, M., additional

Published

2003

8. The abundance of dark galaxies

Author

Verde, Licia, primary, Peng Oh, S., additional, and Jimenez, Raul, additional

Published

2002

9. The effect of Galactic foreground subtraction on redshifted 21-cm observations of quasar H ii regions.

Author

Geil, Paul M., Wyithe, J. Stuart B., Petrovic, Nada, and Peng Oh, S.

Subjects

GALAXY formation, REDSHIFT, IONIZED gases, RADIO sources (Astronomy), ASTRONOMICAL research

Abstract

We assess the impact of Galactic synchrotron foreground removal on the observation of high-redshift quasar H ii regions in redshifted 21-cm emission. We consider the case where a quasar is observed in an intergalactic medium (IGM) whose ionization structure evolves slowly relative to the light crossing time of the H ii region, as well as the case where the evolution is rapid. The latter case is expected towards the end of the reionization era where the highest redshift luminous quasars will be observed. In the absence of foregrounds, the fraction of neutral hydrogen in the IGM could be measured directly from the contrast between the H ii region and surrounding IGM. However, we find that foreground removal lowers the observed contrast between the H ii region and the IGM. This indicates that measurement of the neutral fraction would require modelling to correct for this systematic effect. On the other hand, foreground removal does not modify the most prominent features of the 21-cm maps. Using a simple algorithm, we demonstrate that measurements of the size and shape of observed H ii regions will not be affected by continuum foreground removal. Moreover, measurements of these quantities will not be adversely affected by the presence of a rapidly evolving IGM. [ABSTRACT FROM AUTHOR]

Published

2008

10. Lyman α radiative transfer in a multiphase medium.

Author

Hansen, Matthew and Peng Oh, S.

Subjects

*REDSHIFT, *ASTROPHYSICS, *RADIATIVE transfer, *MONTE Carlo method, *SCATTERING (Physics)

Abstract

Hydrogen Lyman α (Lyα) is our primary emission-line window into high-redshift galaxies. Despite an extensive literature, Lyα radiative transfer in the most realistic case of a dusty, multiphase medium has received surprisingly little detailed theoretical attention. We investigate Lyα resonant scattering through an ensemble of dusty, moving, optically thick gas clumps. We treat each clump as a scattering particle and use Monte Carlo simulations of surface scattering to quantify continuum and Lyα surface scattering angles, absorption probabilities, and frequency redistribution, as a function of the gas dust content. This atomistic approach speeds up the simulations by many orders of magnitude, making possible calculations which are otherwise intractable. Our fitting formulae can be readily adapted for fast radiative transfer in numerical simulations. With these surface scattering results, we develop an analytic framework for estimating escape fractions and line widths as a function of gas geometry, motion, and dust content. Our simple analytic model shows good agreement with full Monte Carlo simulations. We show that the key geometric parameter is the average number of surface scatters for escape in the absence of absorption, , and we provide fitting formulae for several geometries of astrophysical interest. We consider the following two interesting applications. (i) Equivalent widths ( EWs). Lyα can preferentially escape from a dusty multiphase interstellar medium if most of the dust lies in cold neutral clouds, which Lyα photons cannot penetrate. This might explain the anomalously high EWs sometimes seen in high-redshift/submillimetre sources. (ii) Multiphase galactic outflows. We show the characteristic profile is asymmetric with a broad red tail, and relate the profile features to the outflow speed and gas geometry. Many future applications are envisaged. [ABSTRACT FROM AUTHOR]

Published

2006

11. Entropy injection as a global feedback mechanism.

Author

Peng Oh, S. and Benson, Andrew J.

Subjects

*ENTROPY, *COOLING

Abstract

ABSTRACT Both pre-heating of the intergalactic medium and radiative cooling of low entropy gas have been proposed to explain the deviation from self-similarity in the cluster L[sub X]–T[sub X] relation and the observed entropy floor in these systems. However, severe overcooling of gas in groups is necessary for radiative cooling alone to explain the observations. Non-gravitational entropy injection must therefore still be important in these systems. We point out that, on scales of groups and below, gas heated to the required entropy floor cannot cool in a Hubble time, regardless of its subsequent adiabatic compression. Pre-heating therefore shuts off the gas supply to galaxies, and should be an important global feedback mechanism for galaxy formation. Constraints on global gas cooling can be placed from the joint evolution of the comoving star formation rate and neutral gas density. Pre-heating at high redshift can be ruled out; however, the data do not rule out passive gas consumption without inflow as z∼ 2 . Because for pre-heated gas t[sub cool] > t[sub dyn] , we speculate that pre-heating could play a role in determining the Hubble sequence; at a given mass scale, high σ peaks in the density field collapse early to form ellipticals, while low σ peaks collapse late and quiescently accrete pre-heated gas to form spirals. The entropy produced by large-scale shock-heating of the intergalatic medium is significant only at late times, z < 1 , and cannot produce these effects. [ABSTRACT FROM AUTHOR]

Published

2003