Your search keyword '"Coppejans, D."' showing total 6 results

1. Luminous Radio Emission from the Superluminous Supernova 2017ens at 3.3 years after explosion

Author

Margutti, Raffaella, Bright, J. S., Matthews, D. J., Coppejans, D. L., Alexander, K. D., Berger, E., Bietenholz, M., Chornock, R., DeMarchi, L., Drout, M. R., Eftekhari, T., Jacobson-Galan, W. V., Laskar, T., Milisavljevic, D., Murase, K., Nicholl, M., Omand, C. M. B., Stroh, M., Terreran, G., and VanderLey, A. Z.

Subjects

High Energy Astrophysical Phenomena (astro-ph.HE), Astrophysics - Solar and Stellar Astrophysics, FOS: Physical sciences, Astrophysics - High Energy Astrophysical Phenomena, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

We present the results from a multi-year radio campaign of the superluminous supernova (SLSN) 2017ens, which yielded the earliest radio detection of a SLSN to date at the age of $\sim$3.3 years after explosion. SN2017ens was not detected at radio frequencies in the first $\sim$300\,d of evolution but reached $L_{\nu}\approx 10^{28}\,\rm{erg\,s^{-1}\,cm^{-2}}$ at $\nu\sim 6$ GHz, $\sim1250$ days post-explosion. Interpreting the radio observations in the context of synchrotron radiation from the supernova shock interaction with the circumstellar medium (CSM), we infer an effective mass-loss rate of $\approx 10^{-4}\,\rm{M_{\odot}yr^{-1}}$ at $r\sim 10^{17}$ cm from the explosion's site, for a wind speed of $v_w=50-60\,\rm{km\,s^{-1}}$ measured from optical spectra. These findings are consistent with the spectroscopic metamorphosis of SN2017ens from hydrogen-poor to hydrogen-rich $\sim190$ d after explosion reported by Chen et al., 2018. SN2017ens is thus an addition to the sample of hydrogen-poor massive progenitors that explode shortly after having lost their hydrogen envelope. The inferred circumstellar densities, implying a CSM mass up to $\sim0.5\,\rm{M_{\odot}}$, and low velocity of the ejection point at binary interactions (in the form of common envelope evolution and subsequent envelope ejection) playing a role in shaping the evolution of the stellar progenitors of SLSNe in the $\lesssim 500$ yr preceding core collapse., Comment: 9 pages, 4 figures, 1 table

Published

2023

2. Late-Time Radio and Millimeter Observations of Superluminous Supernovae and Long Gamma Ray Bursts: Implications for Obscured Star Formation, Central Engines, and Fast Radio Bursts

Author

Eftekhari, T., Margalit, B., Omand, C. M. B., Berger, E., Blanchard, P. K., Demorest, P., Metzger, B. D., Murase, K., Nicholl, M., Villar, V. A., Williams, P. K. G., Alexander, K. D., Chatterjee, S., Coppejans, D. L., Cordes, J. M., Gomez, S., Hosseinzadeh, G., Hsu, B., Kashiyama, K., Margutti, R., and Yin, Y.

Subjects

High Energy Astrophysical Phenomena (astro-ph.HE), Astrophysics::High Energy Astrophysical Phenomena, FOS: Physical sciences, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics - High Energy Astrophysical Phenomena, Astrophysics::Galaxy Astrophysics

Abstract

We present the largest and deepest late-time radio and millimeter survey to date of superluminous supernovae (SLSNe) and long duration gamma-ray bursts (LGRBs) to search for associated non-thermal synchrotron emission. Using the Karl G. Jansky Very Large Array (VLA) and the Atacama Large Millimeter/submillimeter Array (ALMA), we observed 43 sources at 6 and 100 GHz on a timescale of $\sim 1 - 19$ yr post-explosion. We do not detect radio/mm emission from any of the sources, with the exception of a 6 GHz detection of PTF10hgi (Eftekhari et al. 2019), as well as the detection of 6 GHz emission near the location of the SLSN PTF12dam, which we associate with its host galaxy. We use our data to place constraints on central engine emission due to magnetar wind nebulae and off-axis relativistic jets. We also explore non-relativistic emission from the SN ejecta, and place constraints on obscured star formation in the host galaxies. In addition, we conduct a search for fast radio bursts (FRBs) from some of the sources using VLA Phased-Array observations; no FRBs are detected to a limit of $16$ mJy ($7\sigma$; 10 ms duration) in about 40 min on source per event. A comparison to theoretical models suggests that continued radio monitoring may lead to detections of persistent radio emission on timescales of $\gtrsim {\rm decade}$., Comment: 30 pages; 12 figures; accepted to ApJ

Published

2020

3. Achieving Transformative Understanding of Extreme Stellar Explosions with ELT-enabled Late-time Spectroscopy

Author

Milisavljevic, D., Margutti, R., Chornock, R., Rest, A., Graham, M., DePoy, D., Marshall, J., Golkhou, V. Z., Williams, G., Rho, J., Street, R., Skidmore, W., Haojing, Y., Bloom, J., Starrfield, S., Lee, C. -H., Cowperthwaite, P. S., Stringfellow, G., Coppejans, D., Terreran, G., Sravan, N., Fox, O., Mauerhan, J., Long, K. S., Blair, W. P., Winkler, P. F., Drout, M. R., Andrews, J., Kerzendorf, W., Wheeler, J. C., Filippenko, A. V., Smith, N., Metzger, B. D., Modjaz, M., Fesen, R. A., Berger, E., Garnavich, P., and Chevalier, R. A.

Subjects

High Energy Astrophysical Phenomena (astro-ph.HE), Astrophysics::High Energy Astrophysical Phenomena, Astrophysics::Solar and Stellar Astrophysics, FOS: Physical sciences, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics - High Energy Astrophysical Phenomena, Astrophysics::Galaxy Astrophysics

Abstract

Supernovae are among the most powerful and influential explosions in the universe. They are also ideal multi-messenger laboratories to study extreme astrophysics. However, many fundamental properties of supernovae related to their diverse progenitor systems and explosion mechanisms remain poorly constrained. Here we outline how late-time spectroscopic observations obtained during the nebular phase (several months to years after explosion), made possible with the next generation of Extremely Large Telescopes, will facilitate transformational science opportunities and rapidly accelerate the community towards our goal of achieving a complete understanding of supernova explosions. We highlight specific examples of how complementary GMT and TMT instrumentation will enable high fidelity spectroscopy from which the line profiles and luminosities of elements tracing mass loss and ejecta can be used to extract kinematic and chemical information with unprecedented detail, for hundreds of objects. This will provide uniquely powerful constraints on the evolutionary phases stars may experience approaching a supernova explosion; the subsequent explosion dynamics; their nucleosynthesis yields; and the formation of compact objects that may act as central engines., Comment: 9 pages, 3 figures, Astro2020 Science White Paper

Published

2019

4. Target of Opportunity Observations of Gravitational Wave Events with LSST

Author

Margutti, R., Cowperthwaite, P., Doctor, Z., Mortensen, K., Pankow, C. P., Salafia, O., Villar, V. A., Alexander, K., Annis, J., Andreoni, I., Baldeschi, A., Balmaverde, B., Berger, E., Bernardini, M. G., Berry, C. P. L., Bianco, F., Blanchard, P. K., Brocato, E., Carnerero, M. I., Cartier, R., Cenko, S. B., Chornock, R., Chomiuk, L., Copperwheat, C. M., Coughlin, M. W., Coppejans, D. L., Corsi, A., D'Ammando, F., Datrier, L., D'Avanzo, P., Dimitriadis, G., Drout, M. R., Foley, R. J., Fong, W., Fox, O., Ghirlanda, G., Goldstein, D., Grindlay, J., Guidorzi, C., Haiman, Z., Hendry, M., Holz, D., Hung, T., Inserra, C., Jones, D. O., Kalogera, V., Kilpatrick, C. D., Lamb, G., Laskar, T., Levan, A., Mason, E., Maguire, K., Melandri, A., Milisavljevic, D., Miller, A., Narayan, G., Nielsen, E., Nicholl, M., Nissanke, S., Nugent, P., Pan, Y. -C., Pasham, D., Paterson, K., Piranomonte, S., Racusin, J., Rest, A., Righi, C., Sand, D., Seaman, R., Scolnic, D., Siellez, K., Singer, L., Szkody, P., Smith, M., Steeghs, D., Sullivan, M., Tanvir, N., Terreran, G., Trimble, V., Valenti, S., Transient, with the support of the LSST, and Collaboration, Variable Stars

Subjects

High Energy Astrophysical Phenomena (astro-ph.HE), FOS: Physical sciences, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics - High Energy Astrophysical Phenomena, Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM), Astrophysics::Galaxy Astrophysics

Abstract

The discovery of the electromagnetic counterparts to the binary neutron star merger GW170817 has opened the era of GW+EM multi-messenger astronomy. Exploiting this breakthrough requires increasing samples to explore the diversity of kilonova behaviour and provide more stringent constraints on the Hubble constant, and tests of fundamental physics. LSST can play a key role in this field in the 2020s, when the gravitational wave detector network is expected to detect higher rates of merger events involving neutron stars ($\sim$10s per year) out to distances of several hundred Mpc. Here we propose comprehensive target-of-opportunity (ToOs) strategies for follow-up of gravitational-wave sources that will make LSST the premiere machine for discovery and early characterization for neutron star mergers and other gravitational-wave sources., Comment: White paper for LSST cadence optimization- ToOs

Published

2018

5. YSE/Pan-STARRS1 Transient Discovery Report for 2020-01-31

Author

Jones, D. O., French, K. D., Adriano Agnello, Angus, C. R., Zoe Ansari, Arendse, N., Christa Gall, Claudio Grillo, Bruun, S. H., Cecilie Cold, Jens Hjorth, Luca Izzo, Korhonen, H., Sandra Raimundo, Ramanah, D. K., Arkaprabha Sarangi, Radoslaw Wojtak, Chambers, K. C., Huber, M. E., Magnier, E. A., Boer, T. J. L. D., Fairlamb, J. R., Lin, C. C., Wainscoat, R. J., Lowe, T., Willman, M., Bulger, J., Schultz, A. S. B., Engel, A., Gagliano, A., Narayan, G., Soraisam, M., Wang, Q., Rest, A., Smartt, S. J., Smith, K. W., Alexander, K., Baldeschi, A., Blanchard, P., Coppejans, D., Demarchi, L., Hajela, A., Jacobson-Galan, W., Margutti, R., Matthews, D., Stauffer, C., Stroh, M., Terreran, G., Drout, M., Katie Auchettl, and Young Supernova Experiment (YSE)

6. Target of Opportunity Observations of Gravitational Wave Events with LSST

Author

Margutti, Raffaella, Cowperthwaite, P., Doctor, Z., Mortensen, K., Pankow, C. P., Salafia, O., Villar, V. A., Alexander, K., Annis, J., Andreoni, I., Baldeschi, A., Balmaverde, B., Berger, E., Bernardini, M. G., Christopher Berry, Bianco, F., Blanchard, P. K., Brocato, E., Carnerero, M. I., Cartier, R., Cenko, S. B., Chornock, R., Chomiuk, L., Copperwheat, C. M., Coughlin, M. W., Coppejans, D. L., Corsi, A., D Ammando, F., Datrier, L., D Avanzo, P., Dimitriadis, G., Drout, M. R., Foley, R. J., Fong, W., Fox, O., Ghirlanda, G., Goldstein, D., Grindlay, J., Guidorzi, C., Haiman, Z., Hendry, M., Holz, D., Hung, T., Inserra, C., Jones, D. O., Kalogera, V., Kilpatrick, C. D., Lamb, G., Laskar, T., Levan, A., Mason, E., Maguire, K., Melandri, A., Milisavljevic, D., Miller, A., Narayan, G., Nielsen, E., Nicholl, M., Nissanke, S., Nugent, P., Pan, Y. -C, Pasham, D., Paterson, K., Piranomonte, S., Racusin, J., Rest, A., Righi, C., Sand, D., Seaman, R., Scolnic, D., Siellez, K., Singer, L., Szkody, P., Smith, M., Steeghs, D., Sullivan, M., Tanvir, N., Terreran, G., Trimble, V., and Valenti, S.