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Transcript 
Sensitivity on Earth Core and
Mantle densities using
Atmospheric Nu's
Ofelia Pisanti
Dipartimento di Scienze Fisiche and INFN - Napoli
The Earth mass
Eratostene
(273-192 b.C.)
First measure of the Earth circumference
(and then of the Earth radius)
Galilei
(1564-1642)
Determination of the acceleration due to
gravity
Newton
(1642-1727)
Formulation of the law of gravitation
Cavendish
(1731-1810)
Determination of GN
Calculation of the Earth mass and then
of its average density:
rav ~ 5.5 g cm-3
O. Pisanti - TAUP 2009, July 1-5, 2009
The Earth internal structure
On the other side, the Earth
crust density is about 2.7-2.8
g cm-3 (direct observations
arrive to ~20 km). Information
from samples brought to the
surface by volcanic activity
and by measuring the travel
times of earthquake waves to
seismograph stations. It is
found that:
• the velocity generally increases gradually with depth in Earth, due to
increasing pressure and rigidity of the rocks
• however, there are abrupt velocity changes at certain depths,
indicating layering
O. Pisanti - TAUP 2009, July 1-5, 2009
The utility of earthquakes…
In solids, the P waves generally travel almost twice as fast as S waves and can
travel through any type of material. S waves can travel only through solids, as
fluids (liquids and gases) do not support shear stresses.
v (km s-1)
bulk
modulus
modulus
of rigidity
depth (km)
CMB
PKP (P’)
O. Pisanti - TAUP 2009, July 1-5, 2009
Limits of seismic tomography
• Global seismic tomography is limited by the irregularity in
time and space of the source, and by the incomplete
coverage of recording stations. The primary source is
earthquakes, which are impossible to predict and only occur
at certain locations around the world. In addition, the global
coverage of recording stations is limited due to economic and
political reasons. Because of these limitations, seismologists
must work with data that contains crucial gaps.
• Free-oscillation data only reveal 1-dimensional structure.
O. Pisanti - TAUP 2009, July 1-5, 2009
Limits of seismic tomography
• Global seismic tomography is limited by the irregularity in
time and space of the source, and by the incomplete
this stations.
information
more source is
coverage Although
of recording
The isprimary
precise
than
we can
earthquakes,
which
are what
impossible
to realistically
predict and only occur
at certain expect
locations
around
the world.
In addition,
from
neutrino
radiography
in the global
coverage the
of recording
stations
is limited
dueglobal
to economic and
near future,
aspects
of the
political reasons.
Because
limitations,
seismologists
structure
of of
thethese
earth
require
must workconfirmation.
with data that contains crucial gaps.
• Free-oscillation data only reveal 1-dimensional structure.
O. Pisanti - TAUP 2009, July 1-5, 2009
Earth radiography by neutrinos
λ=
1
σν N ρ N A
λ ~ 2 Rearth ⇔ E ~ 20 TeV
Askaryan, Usp. Fiz. Nauk 144, 523 (1984)
Phys. Rep. 99, 341 (1983)
First proposal to use neutrino beams for Earth radiography by De
Rujula, Glashow, Wilson, and Charpak in 1983: a neutrino moving in
rock produces a shower which ionizes the medium and generates an
acustic signal. Moreover, the muons accompanying the neutrino
beam can be detected at the point of emergence from the Earth.
O. Pisanti - TAUP 2009, July 1-5, 2009
Which ν’s for Earth radiography?
Neutrinos
Astrop. Phys. 20 (2004) 507
Neutrinos are one of the
(almost)
components of cosmic radiation.
isotropic n flux
The atmospheric and the
extragalactic contributions, which
are mainly isotropic, dominates
on the galactic component in two
energy regimes. In particular, for
5
E<10
GeV the statistics of
~
atmospheric ν is larger than that
expected from other cosmic
sources.
O. Pisanti - TAUP 2009, July 1-5, 2009
isotropic n
flux
PREM versus homogeneous
Gonzales-Garcia, Halzen, Maltoni, Tanaka, PRL100 (2008) 061802
up vertical
horizontal
For high Eth the attenuation factor due to the earth density becomes relevant
O. Pisanti
- TAUP
2009,information
July 1-5, 2009 on the earth density.
and the number of detected
events
gives
Neutrinos through the Earth
a simplified parametrization of Earth
radial density profile (sPREM)
a homogeneous
Earth would have
r~ 5.5 g cm-3
14
10
ρcore~11 g cm-3
8
crust
km3
mantle
A
C
12
r HrL Hg cm-3 L
•
B
ρmantle~4.5 g cm-3
6
4
2
ρcrust~2.7 g cm-3
1000
2000
3000
4000
rHkmL
5000
6000
7000
O. Pisanti - TAUP 2009, July 1-5, 2009
core
Neutrinos through the Earth
•
•
•
a simplified parametrization of Earth
radial density profile (sPREM)
three different type of tracks
crossing the fiducial volume
(described by a Digital Elevation
Map)
crust
km3
mantle
A
C
B
neutrinos injected at one side of
the tracks according to known
spectrum
Honda et al., PR D75:043006 (2007)
O. Pisanti - TAUP 2009, July 1-5, 2009
core
Summary of simulation details
•
•
•
•
•
•
e and µ (anti)neutrinos injected according to the
atmospheric ν flux in the range 1÷102 TeV (Honda et
al., 2007). Negligible oscillation -> no τ contribution
CC neutrino interaction and neutrino regeneration by
NC processes
µ energy loss in matter (ionization, bremsstrahlung,
pair production, nuclear interaction)
detectable events: track and contained events
energy thresholds of 1 TeV
no details of the experimental apparatus, except for
the request of a minimal track length of 300 m in the
NT
O. Pisanti - TAUP 2009, July 1-5, 2009
Likelihood analysis
4≤ρm/(g cm-3)≤5
9≤ρc/(g cm-3)≤12
We consider 5 angular bins for the interval cosθ = 1 (upgoing) to cosθ =
0 (horizontal) and make the analysis integrating the muons at different
energies in the case Eth = 1 TeV.
Observables N i produced for a grid of 20 theoretical models of densities. Then, likelihood analysis with likelihood function
− χ 2 2 and
L∝e
∆ξ
ξ=0.25
overall uncertainty on φ and σ
5
χ 2 ( ρ m , ρ c , ξ ,η ) = ∑
[N ( ρ
i
0
ρ
ξ
η
ϑ
,
)(
1
+
)(
1
−
cos
)
−
N
m
c
i
i
N i0
i =1
]
2
2
 ξ   η 
 + 

+ 
 ∆ξ   ∆η 
∆η
η =0.05
uncertainty between h. and v. φ
expected counts for the sPREM
O. Pisanti - TAUP 2009, July 1-5, 2009
2
Likelihood analysis
Eth=1 TeV
2% (5%) uncertainty
on ρm (ρ
ρc) at 2σ
σ
10 years of observations
O. Pisanti - TAUP 2009, July 1-5, 2009
Conclusions
• study of the sensitivity of a NT to Earth interior for a
simplified Earth model (sPREM)
• 2% (5%) uncertainties (at 2σ level) on ρm (ρc) for 10
years of observations and Eth=1 TeV
• no details of the experimental apparatus
• low number of model parameters ⇒ good level of
sensitivity in their determination
O. Pisanti - TAUP 2009, July 1-5, 2009
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