Your search keyword '"Hardcastle, M J"' showing total 4 results

1. Chandra X-Ray Detection of the Radio Hot Spots of 3C 295

Author

Harris, D. E., Nulsen, P., Ponman, T. J., Bautz, M., Cameron, R. A., David, L. P., Donnelly, R. H., Forman, W. R., Grego, L., Hardcastle, M. J., Henry, J. P., Jones, C., Leahy, J. P., Markevitch, M., Martel, A. R., McNamara, B. R., Mazzotta, P., Tucker, W., Virani, S. N., Vrtilek, J., Harris, D. E., Nulsen, P., Ponman, T. J., Bautz, M., Cameron, R. A., David, L. P., Donnelly, R. H., Forman, W. R., Grego, L., Hardcastle, M. J., Henry, J. P., Jones, C., Leahy, J. P., Markevitch, M., Martel, A. R., McNamara, B. R., Mazzotta, P., Tucker, W., Virani, S. N., and Vrtilek, J.

Abstract

An observation of the radio galaxy 3C 295 during the calibration phase of the Chandra X-Ray Observatory reveals X-ray emission from the core of the galaxy, from each of the two prominent radio hot spots, and from the previously known cluster gas. We discuss the possible emission processes for the hot spots and argue that a synchrotron self-Compton (SSC) model is preferred for most or all of the observed X-ray emission. SSC models with near-equipartition fields thus explain the X-ray emission from the hot spots in the two highest surface brightness FR II radio galaxies, Cygnus A and 3C 295. This lends weight to the assumption of equipartition and suggests that relativistic protons do not dominate the particle energy density.

Published

2000

2. Chandra X-Ray Detection of the Radio Hot Spots of 3C 295

Author

Harris, D. E., Nulsen, P., Ponman, T. J., Bautz, M., Cameron, R. A., David, L. P., Donnelly, R. H., Forman, W. R., Grego, L., Hardcastle, M. J., Henry, J. P., Jones, C., Leahy, J. P., Markevitch, M., Martel, A. R., McNamara, B. R., Mazzotta, P., Tucker, W., Virani, S. N., Vrtilek, J., Harris, D. E., Nulsen, P., Ponman, T. J., Bautz, M., Cameron, R. A., David, L. P., Donnelly, R. H., Forman, W. R., Grego, L., Hardcastle, M. J., Henry, J. P., Jones, C., Leahy, J. P., Markevitch, M., Martel, A. R., McNamara, B. R., Mazzotta, P., Tucker, W., Virani, S. N., and Vrtilek, J.

Abstract

An observation of the radio galaxy 3C 295 during the calibration phase of the Chandra X-Ray Observatory reveals X-ray emission from the core of the galaxy, from each of the two prominent radio hot spots, and from the previously known cluster gas. We discuss the possible emission processes for the hot spots and argue that a synchrotron self-Compton (SSC) model is preferred for most or all of the observed X-ray emission. SSC models with near-equipartition fields thus explain the X-ray emission from the hot spots in the two highest surface brightness FR II radio galaxies, Cygnus A and 3C 295. This lends weight to the assumption of equipartition and suggests that relativistic protons do not dominate the particle energy density.

Published

2000

3. Chandra X-Ray Detection of the Radio Hot Spots of 3C 295

Author

Harris, D. E., Nulsen, P., Ponman, T. J., Bautz, M., Cameron, R. A., David, L. P., Donnelly, R. H., Forman, W. R., Grego, L., Hardcastle, M. J., Henry, J. P., Jones, C., Leahy, J. P., Markevitch, M., Martel, A. R., McNamara, B. R., Mazzotta, P., Tucker, W., Virani, S. N., Vrtilek, J., Harris, D. E., Nulsen, P., Ponman, T. J., Bautz, M., Cameron, R. A., David, L. P., Donnelly, R. H., Forman, W. R., Grego, L., Hardcastle, M. J., Henry, J. P., Jones, C., Leahy, J. P., Markevitch, M., Martel, A. R., McNamara, B. R., Mazzotta, P., Tucker, W., Virani, S. N., and Vrtilek, J.

Abstract

An observation of the radio galaxy 3C 295 during the calibration phase of the Chandra X-Ray Observatory reveals X-ray emission from the core of the galaxy, from each of the two prominent radio hot spots, and from the previously known cluster gas. We discuss the possible emission processes for the hot spots and argue that a synchrotron self-Compton (SSC) model is preferred for most or all of the observed X-ray emission. SSC models with near-equipartition fields thus explain the X-ray emission from the hot spots in the two highest surface brightness FR II radio galaxies, Cygnus A and 3C 295. This lends weight to the assumption of equipartition and suggests that relativistic protons do not dominate the particle energy density.

Published

2000

4. Chandra X-Ray Detection of the Radio Hot Spots of 3C 295

Author

Harris, D. E., Nulsen, P., Ponman, T. J., Bautz, M., Cameron, R. A., David, L. P., Donnelly, R. H., Forman, W. R., Grego, L., Hardcastle, M. J., Henry, J. P., Jones, C., Leahy, J. P., Markevitch, M., Martel, A. R., McNamara, B. R., Mazzotta, P., Tucker, W., Virani, S. N., Vrtilek, J., Harris, D. E., Nulsen, P., Ponman, T. J., Bautz, M., Cameron, R. A., David, L. P., Donnelly, R. H., Forman, W. R., Grego, L., Hardcastle, M. J., Henry, J. P., Jones, C., Leahy, J. P., Markevitch, M., Martel, A. R., McNamara, B. R., Mazzotta, P., Tucker, W., Virani, S. N., and Vrtilek, J.

Abstract

An observation of the radio galaxy 3C 295 during the calibration phase of the Chandra X-Ray Observatory reveals X-ray emission from the core of the galaxy, from each of the two prominent radio hot spots, and from the previously known cluster gas. We discuss the possible emission processes for the hot spots and argue that a synchrotron self-Compton (SSC) model is preferred for most or all of the observed X-ray emission. SSC models with near-equipartition fields thus explain the X-ray emission from the hot spots in the two highest surface brightness FR II radio galaxies, Cygnus A and 3C 295. This lends weight to the assumption of equipartition and suggests that relativistic protons do not dominate the particle energy density.

Published

2000