Author Archives: anthonyrushton

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January 9, 2016

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e-MERLIN detection of compact radio emission from V404 Cyg

Renewed activity in the Black hole binary V404 Cyg has been reported in December 2015 (e.g. ATels #8453, #8454, #8455, #8457, #8458, #8459, #8462), following on from a giant outburst seen early in the year. Radio monitoring of the source suggested renewed jet activity (Atel #8454) with a short radio flare appearing to reach over 70 mJy with RATAN-600 around MJD 57387.4 (2015-Dec-31; Atel #8482). Sub-mm emission also showed new activity and was detected at a level of ~41 mJy (at 350 GHz) on 2015-Jan-01 (Atel #8499). Furthermore, around these observations, it was reported that a possible hard to soft transition might be occurring (Atel #8500). To investigate the presence of resolved ejecta, we triggered high-resolution radio observations using the e-MERLIN telescope.

T_2024+3352..ICL001.5

 

Radio observations of V404 Cyg were taken with e-MERLIN on 2016-Jan-05 between 06:30-22:00 UTC at a central frequency of 5.07 GHz and bandwidth of 444 MHz. A compact point-like source was detected with a peak flux density of 0.95 +/- 0.05 mJy/bm; this is a factor of ~2 above the long-term quiescent radio level of V404, which is ~0.4 mJy (Gallo, Fender & Hynes 2005). The synthesised beam had a minimum FWHM of 48 by 35 mas, suggesting most (or all) of the radio flux was constrained to within ~50 mas or ~100 AU (at a distance of 2.4 kpc).

 

We thank the eMERLIN staff for their rapid response to the event and to observatory’s director for approval of the project. eMERLIN is an STFC facility that has been built and operated by the University of Manchester.

 

We also thank the ERC for supporting this project through the 4 PI SKY grant.

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September 24, 2015

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Software

4 PI SKY goes hunting for more transients

This week, members from the 4 PI SKY team visited the AMI telescope in Cambridge, UK, in search of even more transients.

Members of the 4 PI SKY team visiting the AMI teelscope

Members of the 4 PI SKY team visiting the AMI telescope. Shown (from left to right): Clare Rumsey, Richard Saunders, Anthony Rushton, Tim Staley, Kunal Mooley, Rob Fender and Richard Armstrong.

The Universities of Oxford and Cambridge already have a very succesful partnership of following up astronomical transients at 15 GHz using the AMI large array. Gamma-ray alerts from the Swift-BAT space telescope robotically send messages back to earth-based servers, which in-turn automatically command AMI to slew to transient location in the sky (effectively eliminating the need of human intervention). However, when the array isn’t chasing high-energy explosions it spends a significant amount of time surveying galaxy clusters looking for Sunyaev-Zel’dovich (SZ) effects.

AMI recently completed the Tenth Cambridge Survey (10C; AMI Consortium: Davies et al. 2011; AMI Consortium: Franzen et al. 2011) at 15.7 GHz creating the deepest high-frequency (10 GHz) radio survey, complete to 1mJy in 10 different fields covering a total of≈27 deg^2. These data could contain radio transients that haven’t previously been found at other wavelengths and it is our goal to search the entire archive for historic events.

AMI-SA correlator

A new correlator that will power high-spectral resolution observations with AMI

In the mean-time, the AMI telescope is undergoing a major upgrade to the correlator. The original correlator was a lag-based system, which suffered from large errors in correlator lag spacing  and was prone to man-made radio frequency interferences (RFI) particularly at low declinations due to geostationary satellites.

The new AMI Digital Correlator (AMIDC), pictured right, will have a highly channelized digital correlator system giving more flexibility within the radio band and a much more uniform response across it, which would provide the potential to avoid or mitigate to a large extent many of the problems with the current system. This will significantly improve the sensitivity of the array.

Ultimately, we would like to use the new system to detect radio transients in near real-time and produce rapid VOEvent alerts that can help coordinate follow-up observations.

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August 6, 2015

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Robotizing high-resolution radio observations to transient alerts

The 4 PI SKY team has been granted time on the European VLBI Network (EVN) to use a new mode to rapidly hunt transient events (PI Rushton). From 2015 we will use Automated triggers to override e-VLBI sessions if we detect outbursts from objects like flare stars and Gamma-ray bursts (GRBs). The system will quickly generate new scheduling programs for each participating EVN antenna and we aim to robotically slew the whole array to the event after few 10’s of minutes.

Radio emission from transients can start to rise after just a few minutes of being detected at high-energy. It is important to rapidly slew to the source and begin monitoring at high-resolution in order to localise the emission. We will also be able to search for outflows and proper motion caused by jets of plasma. This will give us unique insight to the causes of the most energetic events in our Galaxy and the wider Universe.

eVLBI_autoV3

Credit: Paul Boven (JIVE), AMI (Uni. Cambridge), Swift and VisibleEarth (NASA)

Our network currently uses VOevent alerts from NASA’s Swift space-based telescope to robotically trigger the Arcminute Microkelvin Imager large array (AMI-LA) in Cambridge, UK. The AMI-LA telescope in rapid response mode (ALARRM) can respond to a new outburst of gamma-rays after a few minutes and will help trigger observations at high-resolution with the EVN.

Developing automatic generic triggers for the EVN has been a joint effort including JIVE, Onsala Space Observatory, EVN TOG CBD and PC. In particular we thank the efforts of Simon Casey, Mark Kettenis and Zsolt Paragi. The project includes team members from University Oxford, Instituto de Astrofísica de Andalucía, Space Telescope Science Institute and Caltech.