Your search keyword '"Jerius, D."' showing total 19 results

1. Deep Chandra Observations of Edges and Bubbles in the NGC 5846 Galaxy Group

Author

Machacek, M. E., Jerius, D., Kraft, R. P., Forman, W. R., Jones, C., Randall, S., Giancintucci, S., and Sun, M.

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We use a combined 120 ks Chandra exposure to analyze X-ray edges produced by non-hydrostatic gas motions (sloshing) from galaxy collisions, and cavities formed by AGN activity. Evidence for gas sloshing is seen in the spiral morphology and multiple cold front edges in NGC 5846's X-ray surface brightness distribution, while lack of spiral structure in the temperature map suggests the perturbing interaction was not in the plane of the sky. Density and spectral modeling across the edges indicate the relative motion of gas in the cold fronts is at most transonic. Evidence for AGN activity is seen in two inner bubbles at 0.6 kpc, filled with 5 GHz and 1.5 GHz radio plasma and coincident with Halpha emission, and in a ghost bubble at 5.2 kpc west of NGC 5846's nucleus. The outburst energy and ages for the inner (ghost) bubbles are ~10^{55} ergs and ~2 Myr (~ 5 x 10^{55} ergs and 12 Myr), respectively, implying an AGN duty cycle of 10 Myr. The inner bubble rims are threaded with 9 knots, whose total 0.5-2 keV X-ray luminosity is 0.3 x10^{40} ergs, a factor ~2-3 less than that of the surrounding rims, and 0.7 keV mean temperature is indistinguishable from that of the rims. We suggest that the knots may be transient clouds heated by the recent passage of a shock from the last AGN outburst. We also observe gas stripping from a cE galaxy, NGC 5846A, in a 0.5 kpc long (~10^5 Msolar) hot gas tail, as it falls towards NGC 5846., Comment: 18 pages, 26 figures, ApJ, in press

Published

2011

2. High-resolution x-ray telescopes

Author

O'Dell, S. L., Brissenden, R. J., Davis, W. N., Elsner, R. F., Elvis, M., Freeman, M., Gaetz, T., Gorenstein, P., Gubarev, M. V., Jerius, D., Juda, M., Kolodziejczak, J. J., Murray, S., Petre, R., Podgorski, W., Ramsey, B. D., Reid, P. B., Saha, T., Schwartz, D. A., Trolier-McKinstry, S., Weisskopf, M. C., Wilke, R. H. T., Wolk, S., and Zhang, W. W.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

High-energy astrophysics is a relatively young scientific field, made possible by space-borne telescopes. During the half-century history of x-ray astronomy, the sensitivity of focusing x-ray telescopes-through finer angular resolution and increased effective area-has improved by a factor of a 100 million. This technological advance has enabled numerous exciting discoveries and increasingly detailed study of the high-energy universe-including accreting (stellar-mass and super-massive) black holes, accreting and isolated neutron stars, pulsar-wind nebulae, shocked plasma in supernova remnants, and hot thermal plasma in clusters of galaxies. As the largest structures in the universe, galaxy clusters constitute a unique laboratory for measuring the gravitational effects of dark matter and of dark energy. Here, we review the history of high-resolution x-ray telescopes and highlight some of the scientific results enabled by these telescopes. Next, we describe the planned next-generation x-ray-astronomy facility-the International X-ray Observatory (IXO). We conclude with an overview of a concept for the next next-generation facility-Generation X. The scientific objectives of such a mission will require very large areas (about 10000 m2) of highly-nested lightweight grazing-incidence mirrors with exceptional (about 0.1-arcsecond) angular resolution. Achieving this angular resolution with lightweight mirrors will likely require on-orbit adjustment of alignment and figure., Comment: 19 pages, 11 figures, SPIE Conference 7803 "Adaptive X-ray Optics", part of SPIE Optics+Photonics 2010, San Diego CA, 2010 August 2-5

Published

2010

3. A small X-ray corona of the narrow-angle tail radio galaxy NGC 1265 soaring through the Perseus cluster

Author

Sun, M., Jerius, D., and Jones, C.

Subjects

Astrophysics

Abstract

A deep Chandra observation of NGC 1265 (3C 83.1B), the prototype for the narrow-angled-tailed (NAT) radio galaxy, reveals a small cool X-ray thermal corona (~ 0.6 keV) embedded in the hot ICM of the Perseus cluster (~ 6.7 keV). The corona is asymmetric with a sharp edge (~ 2.2'', or 0.8 kpc from the nucleus) to the south and an extension to the north (at least ~ 8'' from the nucleus), which is interpreted as the action of ram pressure while solely the static ICM confinement is unable to explain. We estimate that the corona is moving with a velocity of ~ 2.4 - 4.2 times the local sound speed to the south. The presence of the sharp edge for this small corona indicates that the transport processes are largely suppressed by the magnetic field there. The magnetic field around the corona also suppresses heat conduction by at least a factor of ~ 60 across the corona boundary. We conclude that it is unrealistic to study the interaction of the small X-ray coronae with the hot ICM without the consideration of the roles that magnetic field plays, a factor not included in current simulations. An absorbed (N_H=1.5-3x10^22 cm^-2) nucleus is also detected, which is not usual for FR I radio galaxies. Weak X-ray emission from three inner radio knots in the jets is also detected. Indentations at the east and west of the corona indicate interaction between the jets and the X-ray corona. Narrow jets carry great amounts of energy out of the central AGN and release the energy outside the corona, preserving the tiny and vulnerable corona. This case reveals that the inner kpc core of the corona of massive galaxies can survive both high-speed stripping and powerful AGN feedback. Thus, the cooling of the X-ray coronae potentially provides fuel to the central SMBH in rich environments where the amount of the galactic cold gas is at a minimum., Comment: revised version, 11 pages, 4 figures, emulateapj5.sty, accepted by ApJ, for the version with high-resolution figures (http://hea-www.harvard.edu/~msun/n1265.ps)

Published

2005

4. Bow shock and radio halo in the merging cluster A520

Author

Markevitch, M., Govoni, F., Brunetti, G., and Jerius, D.

Subjects

Astrophysics

Abstract

Chandra observations of the merging galaxy cluster A520 reveal a prominent bow shock with M=2.1+0.4-0.3. This is only the second clear example of a substantially supersonic merger shock front in clusters. Comparison of the X-ray image with that of the previously known radio halo reveals a coincidence of the leading edge of the halo with the bow shock, offering an interesting experimental setup for determining the role of shocks in the radio halo generation. The halo in A520 apparently consists of two spatially distinct parts, the main turbulence-driven component and a cap-like forward structure related to the shock, where the latter may provide pre-energized electrons for subsequent turbulent re-acceleration. The radio edge may be caused by electron acceleration by the shock. If so, the synchrotron spectrum should have a slope of 1.2 right behind the edge with quick steepening further away from the edge. Alternatively, if shocks are inefficient accelerators, the radio edge may be explained by an increase in the magnetic field and density of pre-existing relativistic electrons due to gas compression. In the latter model, there should be radio emission in front of the shock with the same spectrum as that behind it, but 10-20 times fainter. If future sensitive radio measurements do not find such pre-shock emission, then the electrons are indeed accelerated (or re-accelerated) by the shock, and one will be able to determine its acceleration efficiency. We also propose a method to estimate the magnetic field strength behind the shock, based on measuring the dependence of the radio spectral slope upon the distance from the shock. In addition, the radio edge provides a way to constrain the diffusion speed of the relativistic electrons., Comment: 6 pages (emulateapj style), color figures. Minor text clarifications, improved figure. ApJ in press

Published

2004

5. Optics Requirements For The Generation-X X-Ray Telescope

Author

O'Dell, S., Elsner, R. F, Kolodziejczak, J. J, Ramsey, B. D, Weisskopf, M. C, Zhang, W. W, Content, D. A, Petre, R, Saha, T. T, Reid, P. B, Schwartz, D. A, Brissenden, R. J, Elvis, M, Freeman, M, Gaetz, T, Gorenstein, P, Jerius, D, Juda, M, Murray, S. S, Podgorski, W. A, Wolk, S. J, and Trolier-McKinstry, S

Subjects

Optics

Abstract

US, European, and Japanese space agencies each now operate successful X-ray missions -- NASA s Chandra, ESA s XMM-Newton, and JAXA s Suzaku observatories. Recently these agencies began a collaboration to develop the next major X-ray astrophysics facility -- the International X-ray Observatory (IXO) -- for launch around 2020. IXO will provide an order-of-magnitude increase in effective area, while maintaining good (but not sub-arcsecond) angular resolution. X-ray astronomy beyond IXO will require optics with even larger aperture areas and much better angular resolution. We are currently conducting a NASA strategic mission concept study to identify technology issues and to formulate a technology roadmap for a mission -- Generation-X (Gen-X) -- to provide these capabilities. Achieving large X-ray collecting areas in a space observatory requires extremely lightweight mirrors.

Published

2008

6. Absolute Effective Area of the Chandra High-Resolution Mirror Assembly

Author

Schwartz, D. A, David, L. P, Donnelly, R. H, Edgar, R. J, Gaetz, T. J, Jerius, D, Juda, M, Kellogg, E. M, McNamara, B. R, and Dewey, D

Subjects

Astronomy

Abstract

The Chandra X-ray Observatory was launched in July 1999, and is returning exquisite sub-arcsecond x-ray images of star groups, supernova remnants, galaxies, quasars, and clusters of galaxies. In addition to being the premier X-ray observatory in terms of angular and spectral resolution, Chandra is the best calibrated X-ray facility ever flown. We discuss here the calibration of the effective area of the High Resolution Mirror Assembly. Because we do not know the absolute X-ray flux density of any celestial source, this must be based primarily on ground measurements and on modeling. In particular, we must remove the calibrated modeled responses of the detectors and gratings to obtain the mirror area. For celestial sources which may be assumed to have smoothly varying spectra, such as the Crab Nebula, we may verify the continuity of the area calibration as a function of energy. This is of significance in energy regions such as the Ir M-edges, or near the critical grazing angle cutoff of the various mirror shells.

Published

2000

7. Orbital Verification of the CXO High-Resolution Mirror Assembly Alignment and Vignetting

Author

Gaetz, T. J, Jerius, D, Edgar, R. J, VanSpeybroeck, L. P, Schwartz, D. A, Markevitch, M, and Schulz, N. S

Subjects

Astronomy

Abstract

Prior to launch, the High Resolution Mirror Assembly (HRMA) of the Chandra X-ray Observatory underwent extensive ground testing at the X-ray Calibration Facility (XRCF) at the Marshall Space Flight Center in Huntsville. Observations made during the post-launch Orbital Activation and Calibration period, allow the on-orbit condition of the X-ray optics to be assessed. Based on these ground-based and on-orbit data, we examine the alignment of the x-ray optics based on the PSF, and the boresight and alignment of the optical axis alignment relative to the detectors. We examine the vignetting and the single reflection ghost suppression properties of the telescope. Slight imperfections in alignment lead to a small azimuthal dependence of the off-axis area; the morphology of off-axis images also shows an additional small azimuthal dependence varying as 1/2 the off-axis azimuth angle.

Published

2000

8. Orbital Measurement and Verification of the Chandra X-Ray Observatory's PSF

Author

Jerius, D, Edgar, R. J, Gaetz, T. J, McNamara, B. R, Schwartz, D. A, and VanSpeybroeck, L. P

Subjects

Astronomy

Abstract

The recently launched Chandra x-ray Observatory (CXO) was designed to have the sharpest angular resolution yet of any x-ray telescope. Detailed modeling and metrology of the optics followed by extensive testing at the X-ray Calibration Facility at the Marshall p Space Flight Center in Huntsville, Alabama, indicated that the optics were performing exceedingly well, within our ability to account for distortion of the mirrors due to gravity, and the effects of finite distance and size of the x-ray generator. Thus it was only on-orbit that we expected to directly observe the specified half arcsecond performance. We present here results of the on-orbit calibration of the point spread function (PSF), comparing it with our predictions. We discuss how the PSF varies with source location in the telescope field of view, as well as with the spectral energy distribution of the source.

Published

2000

9. Absolute Calibration of the AXAF Telescope Effective Area

Author

Kellogg, E, Cohen, L, Edgar, R, Evans, I, Freeman, M, Gaetz, T, Jerius, D, McDermott, W. C, McKinnon, P, Murray, S, Podgorski, W, Schwartz, D, VanSpeybroeck, L, Wargelin, B, Zombeck, M, Weisskopf, M, Elsner, R, ODell, S, Tennant, A, and Kolodziejczak, J

Subjects

Optics

Abstract

The prelaunch calibration of AXAF encompasses many aspects of the telescope. In principle, all that is needed is the complete point response function. This is, however, a function of energy, off-axis angle of the source, and operating mode of the facility. No single measurement would yield the entire result. Also, any calibration made prior to launch will be affected by changes in conditions after launch, such as the change from one g to zero g. The reflectivity of the mirror and perhaps even the detectors can change as well, for example by addition or removal of small amounts of material deposited on their surfaces. In this paper, we give a broad view of the issues in performing such a calibration, and discuss how they are being addressed in prelaunch preparation of AXAF. As our title indicates, we concentrate here on the total throughput of the observatory. This can be thought of as the integral of the point response function, i.e. the encircled energy, out ot the largest practical solid angle for an observation. Since there is no standard x-ray source in the sky whose flux is known to the -1% accuracy we are trying to achieve, we must do this calibration on the ground. we also must provide a means for monitoring any possible changes in this calibration from pre-launch until on-orbit operation can transfer the calibration to a celestial x-ray source whose emission is stable. In this paper, we analyze the elements of the absolute throughput calibration, which we call Effective Area. We review the requirements for calibrations of components or subsystems of the AXAF facility, including mirror, detectors, and gratings. We show how it is necessary to calibrate this ground-based detection system at standard man-made x-ray sources, such as electron storage rings. We present the status of all these calibrations, with indications of the measurements remaining to be done, even though the measurements on the AXAF flight optics and detectors will have been completed by the time this paper is presented. We evaluate progress toward the goal of making 1% measurements of the absolute x-ray flux from astrophysical sources, so that comparisons can be made with their emission at other wavelengths, in support of observations such as the Sunyaev-Zeldovitch effect, which can give absolute distance measurements independent of the traditional distance measuring techniques in astronomy.

Published

1997

10. Predictions of the On-Orbit Performance of AXAF's Optics

Author

Jerius, D, Zhao, P, VanSpeybroeck, L, Tennant, A, Swartz, D, Schwartz, D. A, Podgorski, W. A, Harris, B, Graessle, D. E, Gaetz, T. J, Freeman, M. D, Elsner, R, Edgar, R. J, and Cohen, L. M

Subjects

Optics

Abstract

The AXAF optics and science instruments have recently undergone a battery of tests at the Marshall Space Flight Center X-Ray Calibration Facility to determine their spatial and spectral performance. We have combined these data, detailed maps of the optics, surfaces, precise measurements of surface roughness and reflectivity, and detailed mechanical models of the optics and their support structures to arrive at predictions of the optics' on-orbit performance. We present on- and off-axis effective areas, encircled energies, and PSFS.

Published

1997

11. HRMA calibration handbook: EKC gravity compensated XRCF models

Author

Tananbaum, H. D, Jerius, D, and Hughes, J

Subjects

Astronomy

Abstract

This document, consisting of hardcopy printout of explanatory text, figures, and tables, represents one incarnation of the AXAF high resolution mirror assembly (HRMA) Calibration Handbook. However, as we have envisioned it, the handbook also consists of electronic versions of this hardcopy printout (in the form of postscript files), the individual scripts which produced the various figures and the associated input data, the model raytrace files, and all scripts, parameter files, and input data necessary to generate the raytraces. These data are all available electronically as either ASCII or FITS files. The handbook is intended to be a living document and will be updated as new information and/or fabrication data on the HRMA are obtained, or when the need for additional results are indicated. The SAO Mission Support Team (MST) is developing a high fidelity HRMA model, consisting of analytical and numerical calculations, computer software, and databases of fundamental physical constants, laboratory measurements, configuration data, finite element models, AXAF assembly data, and so on. This model serves as the basis for the simulations presented in the handbook. The 'core' of the model is the raytrace package OSAC, which we have substantially modified and now refer to as SAOsac. One major structural modification to the software has been to utilize the UNIX binary pipe data transport mechanism for passing rays between program modules. This change has made it possible to simulate rays which are distributed randomly over the entrance aperture of the telescope. It has also resulted in a highly efficient system for tracing large numbers of rays. In one application to date (the analysis of VETA-I ring focus data) we have employed 2 x 10(exp 7) rays, a substantial improvement over the limit of 1 x 10(exp 4) rays in the original OSAC module. A second major modification is the manner in which SAOsac incorporates low spatial frequency surface errors into the geometric raytrace. The original OSAC included the ability to use Legendre-Fourier polynomials to describe deviations from the basic optical prescription. To this we have added bicubic splines to address a deficiency in the handling of the sharper deformations in the areas of mirror support pads. SAO has developed software (TRANS-FIT) to translate the most common finite element analysis models into these forms for incorporation into the raytrace program.

Published

1994

12. Influence of the equilibration process in supernova remnant shocks on their X-ray and coronal iron surface brightnesses

Author

Jerius, D and Teske, R. G

Subjects

Astrophysics

Abstract

SNR model computation results have been obtained which indicate that the radial distribution of soft X-ray and forbidden coronal Fe surface brightnesses in adiabatic, middle-aged SNRs can be used as a basis of discrimination for whether the equilibration time is short or long, by comparison with the ionization time-scale. These models are based on a grid of Sedov-Taylor models with time-dependent, nonequilibrium collisional ionization of 13 chemical elements; the two extreme equilibration conditions assumed are T(ion) = T(e) and a Coulomb equilibration of ion and electron temperatures. The models are compared with data taken from X-ray images of the Cygnus Loop and Puppis A.

Published

1988

13. A Small X‐Ray Corona of the Narrow‐Angle Tail Radio Galaxy NGC 1265 Soaring through the Perseus Cluster

Author

Sun, M., primary, Jerius, D., additional, and Jones, C., additional

Published

2005

14. Bow Shock and Radio Halo in the Merging Cluster A520

Author

Markevitch, M., primary, Govoni, F., additional, Brunetti, G., additional, and Jerius, D., additional

Published

2005

15. Deconvolving the Nucleus of Centaurus A Using Chandra PSF Library

Author

Karovska, Margarita, primary, Aldcroft, T., additional, Elvis, M.S., additional, Evans, I.N., additional, Fabbiano, G., additional, Gaetz, T.J., additional, Isobe, T., additional, Jerius, D., additional, Jones, C., additional, Juda, M., additional, Kenter, A., additional, Kim, D.W., additional, Kraft, R.P., additional, Murray, S.S., additional, Prestwich, A H., additional, Primini, F., additional, Schwartz, D.A., additional, Cui, W., additional, and Schreier, E.J., additional

Published

2001

16. A [ITAL]Chandra[/ITAL] High-Resolution X-ray Image of Centaurus A

Author

Kraft, R. P., primary, Forman, W., additional, Jones, C., additional, Kenter, A. T., additional, Murray, S. S., additional, Aldcroft, T. L., additional, Elvis, M. S., additional, Evans, I. N., additional, Fabbiano, G., additional, Isobe, T., additional, Jerius, D., additional, Karovska, M., additional, Kim, D.-W., additional, Prestwich, A. H., additional, Primini, F. A., additional, Schwartz, D. A., additional, Schreier, E. J., additional, and Vikhlinin, A. A., additional

Published

2000

17. The Chandra X-ray Observatory PSF Library

Author

Karovska, M., Beikman, S. J., Elvis, M. S., Flanagan, J. M., Gaetz, T., Glotfelty, K. J., Jerius, D., Jonathan McDowell, and Rots, A. H.

18. The Influence of Equilibration on the X-ray Intensity of Sedov Models

Author

Jerius, D., primary and Teske, R.G., additional

Published

1988

19. A Chandra High-Resolution X-ray Image of Centaurus A.

Author

Kraft, R. P., Forman, W., Jones, C., Kenter, A. T., Murray, S. S., Aldcroft, T. L., Elvis, M. S., Evans, I. N., Fabbiano, G., Isobe, T., Jerius, D., Karovska, M., Kim, D. -W, Prestwich, A. H., Primini, F. A., Schwartz, D. A., Schreier, E. J., and Vikhlinin, A. A.

Published

2000