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Galileo Galilei ColloquiumUniversity of Pisa
1/15/09
What is relativity?From Galileo Galilei to Albert Einstein and beyond
Toshi TajimaLMU,MPQ
Acknowledgments for Advice and Collaboration: S. Bulanov, G. Mourou, T. Esirkepov, C. Barty, M. Fujiwara, M. Kando, K. Nakajima, A. Chao, Y.Fukuda, D. Habs, F. Krausz, M. Nozaki, T. Tauchi, K, Fujii, T. Takahashi, K. Homma, K. Ueda, K. Kawase, T. Omori, K. Yokoya, K. Kondo, F. Takasaki, A. Suzuki, Y .Kamiya、M. Hegelich, H. Gies, G. Dunne, T. Tanaka, V. Serbo, J. Rafelski, F. Pegoraro, M. Teshima, H. Sato, Y. Takahashi, G. Korn, P. Chen
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Galileo Galilei(1564-1642)
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The most famous site for experimental science, the birth place of (empirical) physics (as distinct fromAristotlean metaphysics): Pisa
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Challenges
compact, ultrastrong a atto-, zeptosecond
Frontier science driven by advanced accelerator
Can we meet the challenge?How can we meet it ?
(Suzuki,KEK,2007)
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Lasers
(Tajima,Mourou,2002)
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High Peak Power Laser• 100TW/10Hz system is on a commercial base.• 1PW with a low rep. rate system is also on a
commercial base.• 1PW/10Hz system could be possible with
improving 100TW/10Hz system.A larger aperture ceramic YAG could be used for
pumping the final Ti:S amplifier.• A large aperture deformable can be used for tight
focusing.→ 10^22 W/cm^2 has been already
achieved.・ now ELI ----- and other systems
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Ultra-high field workshopParis 07. 07. 08ELI ,
ELI laser (artist’s rendition)
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What is collective force?
Individual particle dynamics vs. Coherent movement
Collective acceleration (Veksler,1956; Tajima & Dawson,1979)Collective radiation (N2 radiation)
Collective ionization (N2 ionization)Collective deceleration (Tajima & Chao,2007; Kando et al,2008)
How can a Pyramid have been built?
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Kelvin’s Ship Wake
21
21
1cos 1 cos2
cos sin/ 2 / 2
x X
X
k
y
g
θ θ
θ θ
ω
π θ π
⎛ ⎞= −⎜ ⎟⎝ ⎠
=− < <
=
( )1 / 22
2 /
4 /
p p p p h p e
p e e
k k
n e m
λ π ω
ω π
= =
=
v
Laser Plasma Wake
Wake
ParaboloidalForm
of the Wake
N. H. Matlis et al, Nature Phys. (2006)
ne
Ex
Laser Pulse
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Laser-driven Bow and Wake
Bow Wave
M87
Wake Wave
0cr
depl las
Depletion lengthnl l an
=(Bulanov, Esirkepov) 10
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2 2 2 2 20 0 0 02 2 ,cr
phe
nE m c a m c an
γ⎛ ⎞
∆ ≈ = ⎜ ⎟⎝ ⎠20
2 ,crd p
e
nL an
λπ
⎛ ⎞= ⎜ ⎟
⎝ ⎠0
1 ,3
crp p
e
nL an
λπ
⎛ ⎞= ⎜ ⎟
⎝ ⎠
100
101
102
103
104
105
106
1015 1016 1017 1018 1019 1020 1021
∆E/
a 02 /mc2
ne (cm -3)51.60.5kJlaser pulse energy
2.30.740.23pspulse duration
2.22.22.2PWpeak power
32010032µmspot radius
290292.9macceleration length
5.7x10145.7x10155.7x1016cm-3plasma density
100010001000GeVenergy gain
13.210a0
case IIIcase IIcase I
Even 1PeV electrons (and gammas) are possible, albeit with lesser amount→ exploration of new physics such as the reach of relativity and beyond?
(laser energy of 50kJ, plasma density of 1016/cc)
Meeting Suzuki’s Challenge:Laser acceleration toward ultrahigh energies
(when 1D theory applies)
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Fundamental Physics following (and beyond)EinsteinLaser x Accelerator, Laser x Laser
→ ELI’s special unique capacity beyond any other infrastructure
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Quantum Gravity: “Why is the sky blue?”(for high energy gamma rays)
• Amelino-Camelia et al., Nature (1998)high energy γ has dispersion:ω = kc + (extra mass-like term?)
• May be regarded as scattering off quantum fluctuations of vacuum (gravitational origin).
• Other proposals, such as H. Sato (1972); Coleman-Glashow(1997), ….
breakdown of Lorentz invariance?
Non-luminosity paradigm possible (though in very high energies)?
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Superstrong acceleration a= superstrong gravity g
The horizon approaches:d = c2/a
Quantum gravity extra-dimension leaks out? →
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High energy cosmic gamma raysmay experience the texture of vacuum at that energy (or distance)
→
Possibility to change the Lorentztransformation, the speed of light c varying
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Observation of positron excess from high energy gamma rays (PAMELA observation)
O. Adriani, et al. (2008)(Pamela collaboration):
“Observation of an anomalouspositron abundance in thecosmic radiation”
Positron fraction
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One way Preparing for the Future following Galilei’s adventure
• Laser acceleration (and intense laser irradiation in ‘vacuum’): revolutionary step, 3-4 orders of magnitude leap in size and accuracy
• Collider paradigm (smaller and cheaper collider?)quantum mechanics ΔEΔt~ ħ → ℒ∽ E2
• Non-collider approachesrelativity: the higher the energy, the pronounced the effect
horizon ~ 1/ a (extradimensions?)a = g ?Unruh-Hawking radiation?special theory (no preferred frame?) vs Big Bangcoherence and macroscopic field effects---temporal
domainextreme field physics (merger of research on special and general
theories of relativity)property of vacuum ( QED, QCD(axion), dark energy,…)
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From an ELI Workshop talk (Gies, 2008)
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What is vacuum? What is relativity?
An observer in a crystal as vacuum Phonon is an excitation of vacuum Strong field breaks vacuum
↓ ↓ ↓
「色即是空」‘ “color (phenomena)” = vacuum’
「空即是色」‘vacuum = “color (matter)” ’
「(真)空」‘(true) vacuum’
Photon is a distortion of vacuum e+e- pair production out of vacuum
「Wiltanschauung of Buddhist」
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(original colors are red and black)
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Lucio Fontana (1961)Space Concept M364
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Check of Special and General Relativity
Check of Equivalence Principleby neutron interferometry→under small a
How far have we checked, can we check?
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More check of Equivalence Principle
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Check of Special Relativity
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The driver and source must carry 10 kJ and 30 J, respectively (Parameters on the order of ELI and HiPER Lasers)
Reflected intensity can approach the Schwinger limit
It becomes possible to investigate such the fundamental problems of nowadays physics, as e.g. the electron-positron pair creation in vacuum and the photon-photon scattering
Laser Energy & Power Required to Achieve the Schwinger Field
2 3e
Q E D
m cE
e=
( )L21
5 1416 64
F F F F F F F Fαβ αβ βγ δµαβ αβ αβ γδ
κπ π
⎡ ⎤= − −⎢ ⎥⎣ ⎦
The critical power for nonlinear vacuum effects is P2 22454QED
cr
cE λπα π
=
for it yields1 mλ µ= P 242.5 10cr W≈ ×Light compression and focusing with the FLYING MIRRORS yieldsfor with the driver power 2
0/ 4
phλ λ γ=
0 phγ=P P 30
phγ ≈ 10cr PW≈P
(Bulanov et al 2003)Laser self-focuses in vacuum with RE!
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4-wave mixing (Lundström et al (2006))
Electron-positron pair production in the laser interaction with the electron beame+ + nγ→γ, γ+nγ' → e+ + e-
(Bula et al (1996); Burke et al (1997))
Some on Horizon of High Field Science
Higher harmonic generation through quantum vacuum interaction(Fedotov & Narozhny (2006))
Unruh radiation (Chen&Tajima (1999))
aLarmor Radiation
E
Unruh Radiation
E
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Hawking radiation
What is ‘vacuum’? Does ‘something’ emerge from ‘nothing’?「空」=「色」? 「混沌」 「秩序」?
vacuum = ‘matter‘ ? chaos information ?
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Event Horizon Analog?,…..
T.Philbin et al., Science 319, 1367 (2008)
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+⎥⎦⎤
⎢⎣⎡ ++⎥⎦
⎤⎢⎣⎡ +−=+
− 22328
4222
4
21 )~(
213)(4
3151)~(
47)(
901)( FFFF
mFFF
mAL NLOLO
loop
πα
πα
παπ
πα
παπ
µ
∑=
+−
⎥⎦
⎤⎢⎣
⎡++
⎥⎦⎤
⎢⎣⎡ +−=+
dui
ss
i
i
aNLOLO
loop
GFFGFm
q
FFFm
GAL
,
222228
42
2224
21
)~(2
13)(123151
)~(47)(
901)(
πα
πα
πα
παπ
πα
παπ
µνµ
2222 FqGF s
πα
πα
πα
+→
944,5.15
21 22 ==±≈≈ dudu qqMeVmm
Euler-Heisenberg effective action in constant Abelian field U(1) can be expressed as
If U(1)→U(1) + condensed SU(3) due to self-interacting attractive force of gluons
Focus on only light-light scattering amplitude after the substitution
Check of Euler-Heisenberg yet to come. Any deviation from it? → axion field?; extended fields( such as dark energy, Tajima-Niu, 1997, etc.)?
∑=
±≈=−−
duie
i
i eGmm
qtermsttermnd
,
5.29248
42
724
12
παπ
QCD effect dominates pure QED 1-loop vacuum polarization to light-light scattering
Higher order QED and QCD hep-ph/9806389
422 10)3.03.2(00 GeVGs −±≈πα
<GG>
e-e+
q+q-
(K.Homma, 2007)
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Explore relativity with strong fieldsExplore relativity with strong fields((Unruh radiationUnruh radiation))
R. Schuetzhold Phys.Rev.Lett.97:121302, 2006
Larmor scatteringUnruh radiation
Correlatedpair radiation
Inertial frame
Rindler frame Strong correlation betweenabsorption and emissiondespite of causal disconnection
G. Unruh PRD 29 1047-1056, 1984
negative frequencymode in Rinder 2
Observerin RIndler 1
No correlated pairin background process
⇒=⇒≈⇒=
eVTkmVEcmWI
B 06.0]/[10]/[10 12217
~10eV (blue shift in lab. frame)
e- e-
(Chen, Tajima,1999)
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Homma proposes: experimental testHomma proposes: experimental test
2204 RneET πεγ
=
γνRt ≈∆
nRt
ncl
γβδ =∆≈
e-
Measure instantaneous variation of refractive indexin Electro-Optical crystal by external electric fields.
e-
z
z
xy y
x
γRx ≈∆
))5.0(tan(cos 3/11−≈∆ Ry
TEO Erfn )(=δ
Re
nrfln EO
λβεδδ
λπδ 3
02)(2
==Γ
R
Phase retardation
(Homma, 2007)
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Detection of (light) fields-particles missed by collider: exploring new fields such as
axion……
A.Chou et al.,PRL (2008) observed no signal so far (Note:claim of axion by PVLAS was withdrawn)
coup
ling
mass
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Experimentally available systemsExperimentally available systems
Log10(Energy Density) [GeV/fm3]
Log 1
0(S
yste
m S
ize)
[fm
]Horizon (h~0.7, Ω=1.0)
Rest protone+e-√S=1TeVif Re < 10-20 m
pp √S=14TeV(LHC)AuAu √S=40TeV(RHIC)
PW EM fieldλ~1µm ∆T~500fs
Gamma ray burstat 1010 LY
Anomalous dispersion relation due to quantum gravity effects?Uncontrollable. Nature393(1998)763
Size is too smallNo one argues
Size is still small andphenomena are too dynamical.
Possible size to arguemacroscopic propagation.Not dynamical andcontrollable.
(K.Homma)
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APJ, 464,L1(1996)Bennet et al.
Cosmic Microwave BackgroundRadiation (CMBR) red- andblue-shifted from our cluster
↓Unique frame (CMBR frame)in the cosmos?
Typical CMBR fluctuations showing the structure formation
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Sato:There may be a unique
frame of reference due tothe Big Bang. Theory of relativity may need to be modified
Einstein:
Relativity dictates nopreferred frame
Why is every frame ‘relative’?
(relativity’s cornerstone)
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Does gamma’s dispersion relationchange from ω = kc in high energies?
Does Lorentz transform change ijn high energies ?
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More on these topics
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more
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Our ponderation on relativitycontinues….
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40
Conclusions• Glalileo’s and Einstein’s relativity: Cornerstone of modern
science• Advance of rapid progress in ultrafast ultrastrong lasers
(particularly) ELI, poses special opportunities to extend the horizon of Galileo and Einstein.
• laser acceleration toward GeV TeV, PeV: new opportunities• Revolutionary (not evolutionary) technology apt for 21st Century
challenges, just like Galilei’s was in 17th
• Test Einstein’s (special and general) relativity in more extreme limits
• Is ‘relative’ frame really relative or some unique?• Does photon see vacuum differently when its energy is high or
its intensity high? Does the ‘Blue Sky’ appear also in vacuum with high energies? Does strong field warp space? Do we see vacuum structure and property with intense laser? Does ‘relativity’ hold (Lorentz transform as well as Equivalence Principle, and Hawking radiation etc.)?
• We learn a lot from Galilei 400 years later
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2009: International Year of Astronomy(400 year after Galilei’s invention of the Galilei telescope
and discovery of the moons of Jupiter)
Grazie!