Andrew Yee
July 20th 05, 04:39 PM
Public Relations Office
University of Oxford
Oxford, U.K.
For more information contact:
Dr Roberto Trotta, tel: +44 1865 283016
or
Dr Alessandro Melchiorri, tel: +39 06 49914052
15 June 2005
Ripples in cosmic neutrino background measured for the first time
Astrophysicists from the Universities of Oxford and Rome have for the
first time found evidence of ripples in the Universe's primordial sea of
neutrinos, confirming the predictions of both Big Bang theory and the
Standard Model of particle physics.
Neutrinos are elementary particles with no charge and very little mass,
which are extremely difficult to study due to their very weak interaction
with matter. Yet pinning down the physical properties of neutrinos is of
paramount importance to scientists attempting to understand the
fundamental building blocks of Nature. According to the standard Big Bang
model, neutrinos permeate the Universe at a density of about 150 per cm3.
The Earth is therefore immersed in an ocean of neutrinos, without us ever
noticing. Although it is impossible to measure this 'Cosmic Neutrino
Background' directly with present-day technology, physicists predict that
ripples or waves in it have an impact on the growth of structures in the
Universe.
In research to be published in the journal Physical Review Letters, Dr
Roberto Trotta, Lockyer Fellow of the Royal Astronomical Society at
Oxford's Department of Physics and Dr Alessandro Melchiorri of La Sapienza
University in Rome were able to demonstrate for the first time the
existence of ripples of primordial origin in the Cosmic Neutrino
Background. The discovery, made by combining data produced by the NASA
WMAP (Wilkinson Microwave Anisotropy Probe) satellite and the Sloan
Digital Sky Survey, confirms the predictions of both the Big Bang theory
and the Standard Model of particle physics. The research has important
implications for the study of neutrinos, showing that theories of the
infinitely large (cosmology) and the infinitely small (particle physics)
are in agreement.
Dr Trotta said: "This research provides important new evidence in favour
of the current cosmological model, unifying it with fundamental physics
theories. Cosmology is becoming a more and more powerful laboratory where
physics not easily accessible on Earth can be tested and verified. The
high quality of recent cosmological data allows us to investigate
neutrinos in the cosmological framework, obtaining measurements which are
competitive with -- if not superior to -- particle accelerator findings."
Notes to Editors
* "Indication for Primordial Anisotropies in the Neutrino Background from
WMAP and SDSS" by Roberto Trotta and Alessandro Melchiorri has been
accepted for publication in Physical Review Letters and is available
online at
http://www-astro.physics.ox.ac.uk/~rxt/pdf/CNB.pdf
* Further diagrams representing the findings are available at
http://www-astro.physics.ox.ac.uk/%7Erxt/pdf/CompositeFig.jpg
* WMAP is a NASA Explorer mission measuring the temperature of the cosmic
background radiation over the full sky with unprecedented accuracy. This
map of the remnant heat from the Big Bang provides answers to fundamental
questions about the origin and fate of the Universe. For more information
see
http://map.gsfc.nasa.gov/
* The Sloan Digital Sky Survey, conducted using telescopes at the Apache
Point Observatory in the US, aims to systematically map one-quarter of the
entire sky, producing a detailed image of it and determining the positions
and absolute brightnesses of more than 100 million celestial objects. It
will also measure the distances to more than a million galaxies and
quasars. For more information see
http://www.sdss.org/
University of Oxford
Oxford, U.K.
For more information contact:
Dr Roberto Trotta, tel: +44 1865 283016
or
Dr Alessandro Melchiorri, tel: +39 06 49914052
15 June 2005
Ripples in cosmic neutrino background measured for the first time
Astrophysicists from the Universities of Oxford and Rome have for the
first time found evidence of ripples in the Universe's primordial sea of
neutrinos, confirming the predictions of both Big Bang theory and the
Standard Model of particle physics.
Neutrinos are elementary particles with no charge and very little mass,
which are extremely difficult to study due to their very weak interaction
with matter. Yet pinning down the physical properties of neutrinos is of
paramount importance to scientists attempting to understand the
fundamental building blocks of Nature. According to the standard Big Bang
model, neutrinos permeate the Universe at a density of about 150 per cm3.
The Earth is therefore immersed in an ocean of neutrinos, without us ever
noticing. Although it is impossible to measure this 'Cosmic Neutrino
Background' directly with present-day technology, physicists predict that
ripples or waves in it have an impact on the growth of structures in the
Universe.
In research to be published in the journal Physical Review Letters, Dr
Roberto Trotta, Lockyer Fellow of the Royal Astronomical Society at
Oxford's Department of Physics and Dr Alessandro Melchiorri of La Sapienza
University in Rome were able to demonstrate for the first time the
existence of ripples of primordial origin in the Cosmic Neutrino
Background. The discovery, made by combining data produced by the NASA
WMAP (Wilkinson Microwave Anisotropy Probe) satellite and the Sloan
Digital Sky Survey, confirms the predictions of both the Big Bang theory
and the Standard Model of particle physics. The research has important
implications for the study of neutrinos, showing that theories of the
infinitely large (cosmology) and the infinitely small (particle physics)
are in agreement.
Dr Trotta said: "This research provides important new evidence in favour
of the current cosmological model, unifying it with fundamental physics
theories. Cosmology is becoming a more and more powerful laboratory where
physics not easily accessible on Earth can be tested and verified. The
high quality of recent cosmological data allows us to investigate
neutrinos in the cosmological framework, obtaining measurements which are
competitive with -- if not superior to -- particle accelerator findings."
Notes to Editors
* "Indication for Primordial Anisotropies in the Neutrino Background from
WMAP and SDSS" by Roberto Trotta and Alessandro Melchiorri has been
accepted for publication in Physical Review Letters and is available
online at
http://www-astro.physics.ox.ac.uk/~rxt/pdf/CNB.pdf
* Further diagrams representing the findings are available at
http://www-astro.physics.ox.ac.uk/%7Erxt/pdf/CompositeFig.jpg
* WMAP is a NASA Explorer mission measuring the temperature of the cosmic
background radiation over the full sky with unprecedented accuracy. This
map of the remnant heat from the Big Bang provides answers to fundamental
questions about the origin and fate of the Universe. For more information
see
http://map.gsfc.nasa.gov/
* The Sloan Digital Sky Survey, conducted using telescopes at the Apache
Point Observatory in the US, aims to systematically map one-quarter of the
entire sky, producing a detailed image of it and determining the positions
and absolute brightnesses of more than 100 million celestial objects. It
will also measure the distances to more than a million galaxies and
quasars. For more information see
http://www.sdss.org/