E. J. Daw
University of Sheffield
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Featured researches published by E. J. Daw.
Classical and Quantum Gravity | 2011
Darren White; E. J. Daw; V. S. Dhillon
We present a list of galaxies within 100 Mpc, which we call the Gravitational Wave Galaxy Catalogue (GWGC), that is currently being used in follow-up searches of electromagnetic counterparts from gravitational wave searches. Due to the time constraints of rapid follow-up, a locally available catalogue of reduced, homogenized data is required. To achieve this we used four existing catalogues: an updated version of the Tully Nearby Galaxy Catalog, the Catalog of Neighboring Galaxies, the V8k catalogue and HyperLEDA. The GWGC contains information on sky position, distance, blue magnitude, major and minor diameters, position angle, and galaxy type for 53 255 galaxies. Errors on these quantities are either taken directly from the literature or estimated based on our understanding of the uncertainties associated with the measurement method. By using the PGC numbering system developed for HyperLEDA, the catalogue has a reduced level of degeneracies compared to catalogues with a similar purpose, and is easily updated. We also include 150 Milky Way globular clusters. Finally, we compare the GWGC to previously used catalogues, and find the GWGC to be more complete within 100 Mpc due to our use of more up-to-date input catalogues and the fact that we have not made a blue luminosity cut.
Physical Review Letters | 2018
N. Du; N. Force; R. Khatiwada; E. Lentz; R. S. Ottens; L.J. Rosenberg; G. Rybka; G. Carosi; N. Woollett; D. Bowring; A. S. Chou; A. Sonnenschein; W. Wester; C. Boutan; N. S. Oblath; Richard Bradley; E. J. Daw; A. V. Dixit; John Clarke; S. O’Kelley; N. Crisosto; J. Gleason; S. Jois; P. Sikivie; I. Stern; N. S. Sullivan; D. B. Tanner; G. C. Hilton
This Letter reports the results from a haloscope search for dark matter axions with masses between 2.66 and 2.81 μeV. The search excludes the range of axion-photon couplings predicted by plausible models of the invisible axion. This unprecedented sensitivity is achieved by operating a large-volume haloscope at subkelvin temperatures, thereby reducing thermal noise as well as the excess noise from the ultralow-noise superconducting quantum interference device amplifier used for the signal power readout. Ongoing searches will provide nearly definitive tests of the invisible axion model over a wide range of axion masses.
Astronomy and Astrophysics | 2012
T. E. Hassall; B. W. Stappers; J. W. T. Hessels; M. Kramer; A. Alexov; K. Anderson; T. Coenen; A. Karastergiou; E. F. Keane; V. I. Kondratiev; K. Lazaridis; J. van Leeuwen; A. Noutsos; M. Serylak; C. Sobey; J. P. W. Verbiest; P. Weltevrede; K. Zagkouris; R. P. Fender; R. A. M. J. Wijers; L. Bähren; M. E. Bell; J. Broderick; S. Corbel; E. J. Daw; V. S. Dhillon; J. Eislöffel; H. Falcke; Jean-Mathias Grießmeier; P. G. Jonker
Dispersion in the interstellar medium is a well known phenomenon that follows a simple relationship, which has been used to predict the time delay of dispersed radio pulses since the late 1960s. We performed wide-band simultaneous observations of four pulsars with LOFAR (at 40-190 MHz), the 76-m Lovell Telescope (at 1400 MHz) and the Effelsberg 100-m Telescope (at 8000 MHz) to test the accuracy of the dispersion law over a broad frequency range. In this paper we present the results of these observations which show that the dispersion law is accurate to better than 1 part in 100000 across our observing band. We use this fact to constrain some of the properties of the ISM along the line-of-sight and use the lack of any aberration or retardation effects to determine upper limits on emission heights in the pulsar magnetosphere. We also discuss the effect of pulse profile evolution on our observations, and the implications that it could have for precision pulsar timing projects such as the detection of gravitational waves with pulsar timing arrays.
Physical Review D | 2016
J. Hoskins; N. Crisosto; J. Gleason; P. Sikivie; I. Stern; N. S. Sullivan; D. B. Tanner; C. Boutan; M. Hotz; R. Khatiwada; D. Lyapustin; A. Malagon; R. S. Ottens; L.J. Rosenberg; G. Rybka; J.V. Sloan; A. Wagner; D. Will; G. Carosi; D. Carter; Leanne D. Duffy; Richard Bradley; John Clarke; S. O’Kelley; K. van Bibber; E. J. Daw
Non-virialized dark-matter axions may be present in the Milky Way halo in the form of low-velocity-dispersion flows. The Axion Dark Matter eXperiment performed a search for the conversion of these axions into microwave photons using a resonant cavity immersed in a strong, static magnetic field. The spread of photon energy in these measurements was measured at spectral resolutions of the order of 1 Hz and below. If the energy variation were this small, the frequency modulation of any real axion signal due to the orbital and rotational motion of the Earth would become non-negligible. Conservative estimates of the expected signal modulation were made and used as a guide for the search procedure. The photon frequencies covered by this search are 812
Astronomy and Astrophysics | 2012
T. E. Hassall; B. W. Stappers; J. W. T. Hessels; M. Kramer; A. Alexov; K. Anderson; T. Coenen; A. Karastergiou; E. F. Keane; V. I. Kondratiev; K. Lazaridis; J. van Leeuwen; A. Noutsos; M. Serylak; C. Sobey; J. P. W. Verbiest; P. Weltevrede; K. Zagkouris; R. P. Fender; R. A. M. J. Wijers; L. Bähren; M. E. Bell; J. Broderick; S. Corbel; E. J. Daw; V. S. Dhillon; J. Eisloeffel; H. Falcke; J. M. Griessmeier; C. J. Law
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Astronomy and Astrophysics | 2012
T. E. Hassall; B. W. Stappers; J. W. T. Hessels; M. Kramer; A. Alexov; K. Anderson; T. Coenen; A. Karastergiou; E. F. Keane; V. I. Kondratiev; K. Lazaridis; J. van Leeuwen; A. Noutsos; M. Serylak; C. Sobey; J. P. W. Verbiest; P. Weltevrede; K. Zagkouris; R. P. Fender; R. A. M. J. Wijers; L. Bähren; M. E. Bell; J. Broderick; S. Corbel; E. J. Daw; V. S. Dhillon; J. Eisloeffel; H. Falcke; J.-M. Griessmeier; C. J. Law
852 and 858
Astronomy and Astrophysics | 2011
B. W. Stappers; J. W. T. Hessels; A. Alexov; K. Anderson; T. Coenen; T. E. Hassall; A. Karastergiou; V. I. Kondratiev; M. Kramer; J. van Leeuwen; Jan David Mol; Aris Noutsos; John W. Romein; P. Weltevrede; R. P. Fender; R. A. M. J. Wijers; L. Bähren; M. E. Bell; John Broderick; E. J. Daw; V. S. Dhillon; J. Eislöffel; H. Falcke; J.-M. Griessmeier; C. J. Law; Sera Markoff; J. C. A. Miller-Jones; B. Scheers; H. Spreeuw; J. Swinbank
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Physics of the Dark Universe | 2016
J.V. Sloan; M. Hotz; C. Boutan; Richard Bradley; G. Carosi; D. Carter; John Clarke; N. Crisosto; E. J. Daw; J. Gleason; J. Hoskins; R. Khatiwada; D. Lyapustin; A. Malagon; S. O’Kelley; R.S. Ottens; L.J. Rosenberg; G. Rybka; I. Stern; N. S. Sullivan; D. B. Tanner; K. van Bibber; A. Wagner; D. Will
892 MHz, which correspond to an axion mass of 3.36
Classical and Quantum Gravity | 2010
V. Predoi; J. Clark; T. D. Creighton; E. J. Daw; S. Fairhurst; I. S. Heng; J. Kanner; T. Regimbau; P. Shawhan; X. Siemens; P. J. Sutton; A. Vecchio; D. J. White; G. Woan
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International conference on critique of the source of dark matter in the universe, Bel Air, CA (United States), 16-18 Feb 1994 | 1994
K. Van Bibber; C. Hagmann; W. Stoeffl; E. J. Daw; L. Rosenberg; P. Sikivie; N. S. Sullivan; D. B. Tanner; D. M. Moltz; R. Tighe
3.52 and 3.55
