HEAPOW: High Energy Ghost Particles ... (2013 May 20)

[bystander]

HEAPOW: High Energy Ghost Particles from Outer Space (2013 May 20)

Neutrinos are subatomic particles first postulated by Wolfgang Pauli and Enrico Fermi in the 1930's and first detected in 1956. Neutrinos are sometimes called "ghost particles" because they travel at the speed of light but rarely interact with normal matter. Billions of neutrinos, generated by the thermonuclear processes in the sun or other local high energy processes, pass through earth every second, but leave hardly a trace. Detection of even small numbers of neutrinos has had great cosmic significance, from casting fundamental doubt on the way the Sun shines to helping to support theories about the deaths of massive stars. But neutrino detection requires enormous amounts of target material to catch even a few neutrinos. The IceCube neutrino detector in Antarctica uses 5000 detectors suspended throughout a cubic kilometer of Antarctic ice looking for those rare interactions between outer-space neutrinos and ice molecules. IceCube has recently reported the detection of 28 extremely high energy neutrinos, two of which have energies exceeding a thousand times the highest neutrino energy ever achieved on earth. It is as yet a mystery as to what could have generated neutrinos at these astonishing energies.

IceCube: First Evidence for Extraterrestrial High-Energy Neutrinos

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Author: Dr. Michael F. Corcoran

[bystander]

IceCube neutrinos came from outer space
Nature News | Eugenie Samuel Reich | 2013 Apr 22

Scientists in Antarctica Find Invading Neutrinos from Another Galaxy!
Slate Blogs | Bad Astronomy | 2013 Apr 25

First Evidence for Extraterrestrial High-Energy Neutrinos
IceCube Neutrino Observatory | Univ of Wisconsin, Madison | 2013 May 15

First observation of PeV-energy neutrinos with IceCube - IceCube Collaboration

• arXiv.org > astro-ph > arXiv:1304.5356 > 19 Apr 2013

http://asterisk.apod.com/viewtopic.php?t=28337
http://asterisk.apod.com/viewtopic.php?t=28311

[neufer]

<<The Standard Model of particle physics assumed that neutrinos are massless.
However, the experimentally established phenomenon of neutrino oscillation requires neutrinos to have nonzero masses.

The strongest upper limit on the masses of neutrinos comes from cosmology: the Big Bang model predicts that there is a fixed ratio between the number of neutrinos and the number of photons in the cosmic microwave background. If the total energy of all three types of neutrinos exceeded an average of 50 eV per neutrino, there would be so much mass in the universe that it would collapse.

A much more stringent constraint comes from a careful analysis of cosmological data, such as the cosmic microwave background radiation, galaxy surveys, and the Lyman-alpha forest. These indicate that the summed masses of the three neutrino varieties must be less than 0.3 eV. In July 2010 the 3-D MegaZ DR7 galaxy survey reported that they had measured a limit of the combined mass of the three neutrino varieties to be less than 0.28 eV. A tighter upper bound yet for this sum of masses, 0.23 eV, was reported in March of 2013 by the Planck collaboration.>>

A 1 PeV (= 10¹⁵ eV) neutrino of rest mass < 0.1 eV

has a relativistic Lorentz factor:

> 10¹⁶

--------------------------------------------------------------------------
A 1 PeV neutrino from the big bang would arrive less than
0.7 µm behind (an unperturbed) big bang photon and it would
have lived less than a minute within it's time delay frame of reference.
--------------------------------------------------------------------------

<<IceCube is sensitive mostly to high energy neutrinos, in the range of 10¹¹ to about 10²¹ eV
Estimates predict a neutrino event about every 20 minutes in the fully constructed IceCube detector.

IceCube is more sensitive to muons than other charged leptons, because they are the most penetrating and thus have the longest tracks in the detector. Thus, of the neutrino flavors, IceCube is most sensitive to muon neutrinos. Electron neutrinos typically scatter several times before losing enough energy to fall below the Cherenkov threshold; this means that they cannot typically be used to point back to sources, but they are more likely to be fully contained in the detector, and thus they can be useful for energy studies. These events are more spherical, or "cascade"-like, than "track"-like; muon neutrinos are more track-like.

Taus can also create cascade events; but are short-lived and cannot travel very far before decaying, and are thus usually indistinguishable from electron cascades. A tau could be distinguished from an electron with a "double bang" event, where a cascade is seen both at the tau creation and decay. This is only possible with very high energy taus. Hypothetically, to resolve a tau track, the tau would need to travel at least from one DOM to an adjacent DOM (17 m) before decaying. As the average lifetime of a tau is 2.9×10⁻¹³ s, a tau traveling at near the speed of light would require 20 TeV of energy for every meter traveled. Realistically, an experimenter would need more space than just one DOM to the next to distinguish two cascades, so double bang searches are centered at PeV scale energies. Such searches are under way but have not so far isolated a double bang event from background events.

However, there is a large background of muons created not by neutrinos from astrophysical sources but by cosmic rays impacting the atmosphere above the detector. There are about 10⁶ times more cosmic ray muons than neutrino-induced muons observed in IceCube. Most of these can be rejected using the fact that they are traveling downwards. Most of the remaining (up-going) events are from neutrinos, but most of these neutrinos are from cosmic rays hitting the far side of the Earth; some unknown fraction may come from astronomical sources, and these neutrinos are the key to IceCube point source searches. Estimates predict the detection of about 75 upgoing neutrinos per day in the fully constructed IceCube detector. The arrival directions of these astrophysical neutrinos are the points with which the IceCube telescope maps the sky. To distinguish these two types of neutrinos statistically, the direction and energy of the incoming neutrino is estimated from its collision by-products. Unexpected excesses in energy or excesses from a given spatial direction indicate an extraterrestrial source.>>

[neufer]

Each dot is an IceCube optical sensor that observed Cherenkov light
from the charged particles produced in the neutrino interaction.
The colors show when the light arrived at the sensor (red = earliest,
then yellow, green, blue...), and the size of the circle indicates
the number of photons that were observed

• Bert and Ernie Step Out
  by Spencer Klein, April 25, 2013

<<Last August, I posted a piece about two high energy (PeV, 10¹⁵ eV neutrinos that IceCube had observed. The neutrinos had been announced at Neutrino 2012, the main scientific conference for neutrino enthusiasts. Now, we (IceCube) has written a paper about the two events, which has been posted to the Cornell preprint server at http://arxiv.org/pdf/1304.5356v1. The events have not changed much, but we have spent the intervening months refining the reconstructions and evaluating the backgrounds. We now know the energies much more accurately: 1.04 and 1.14 PeV respectively, with a 15% uncertainty. 1 PeV = 1,000,000,000,000,000 electron volts, compared to 120 electron volts for an electron moving through the wires in your house.

We are also hard at work at follow-up studies, but we're not ready to present these yet. The two events have been given catchy names, which have been featured in a number of news & blog reports about the events. The two event displays show the two events. .>>

[wonderboy]

say we do get better at locating these blighters, is this not the answer to our energy prayers?

[neufer]

say we do get better at locating these blighters, is this not the answer to our energy prayers?

• No: 6,250 PeV neutrinos per second ~ 1 watt.

The total energy flux of ALL cosmic rays amounts to only about 4 watts per square kilometer.

<<The magnitude of the energy of cosmic ray flux in interstellar space is very comparable to that of other deep space energies: cosmic ray energy density averages about one electron-volt per cubic centimeter of interstellar space, or ~1 eV/cm³, which is comparable to the energy density of visible starlight at 0.3 eV/cm³, or the cosmic microwave background (CMB) radiation energy density at ~ 0.25 eV/cm³.>>

[geckzilla]

My DNA is thankful for that.