Lecture 1: Introduction, basic concepts. Tailoring Rydberg wavepackets Lecture 2: The kicked Rydberg atom In collaboration with THEORY: S. Yoshida, P. Kristofel, and J. Burgdrfer EXPERIMENT: M. Frey, B. Tannian, C. Stokely, and B. Dunning Why Rydberg atoms ?: (i.e. atoms in highly excited states) - unique arena to study classical quantum correspondence - high degree of control (experimentally) using current electromagnetic pulses Short designer pulses Coherent control. Non-linear dynamics. PASI lectures, Ushuaia, Argentina, October 2000 C.O. Reinhold
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Lecture 1: Introduction, basic concepts.Tailoring Rydberg wavepackets
Lecture 2: The kicked Rydberg atom
In collaboration with
THEORY: S. Yoshida, P. Kristofel, and J. Burgdörfer
EXPERIMENT: M. Frey, B. Tannian, C. Stokely, and B. Dunning
Why Rydberg atoms ?: (i.e. atoms in highly excited states)
- unique arena to study classical quantum correspondence
- high degree of control (experimentally) using current
electromagnetic pulses
Short designer
pulses Coherent control.
Non-linear dynamics.
PASI lectures, Ushuaia, Argentina, October 2000C.O. Reinhold
PROBLEM: Rydberg Atom in a classical time-dependent electric field F(t)
(t)F .r +H = H atom
�
�
V(r)2p H
2
atom +=Hydrogen: V(r) = -1/r Alkali: V(r) = -1/r + short
range potential
Atomic units: =1, me=1, e=1, rBohr=1, pBohr=1�
Atom in a given n levelEn=-1/(2n2)Torb= 2πn3 = 2π/(En+1-En)Forb = 1/<r2>= n-4
F(t)
DESIRED PULSES: Short pulses: duration < Torb
Strong pulses: field strength > Forb
n Torb Forb
1 0.15 fs 5 109 V/cm20 1.2 ps 3 104 V/cm400 10 ns 0.2 V/cm
Tp
t t
FpF(t)
Laser/microwave pulse Half-cycle pulse (HCP)
Collisional pulse at a large impact parameterv
qb
perpendicular field parallel field
Fp=q/b2
Tp=2b/v
tt
Designer pulsesFi
eld
time
time
Fiel
d
Single pulse
Two pulses
Trains of pulses
Fiel
d
time
HCP
Tp = 0.5psν ~ 1 THz
Jones et al, Noordam et al, Bucksbaum et al1993 Sub picosecond half-cycle pulses
1996
Orbital periodof H(n=15)
Nanosecond "designer" pulses
Dunning et al, Tp>0.5ns
0.0
0.4
0.8
100 200 300 400time (ns)
109ns0.0
0.2
0.4
0.6
Fiel
d (V
/cm
)
5 10 15 20time (ns)
25 30
2ns
Tp ~ 10ns (ν ~ 100MHz), Orbital period of H(n=400)
0.0 0.2 0.4 0.60.00.20.40.60.81.0
Surv
ival
pro
babi
lity
Fp / Forb
Experiment
Theory
µs
Prepare the Rydbergatom using a long laser pulse
ns
Actual field in an experiment
Typical result for a single HCP on K(388p)ionization threshold
F(t)
µs time
Manipulate theatom with a designer pulse F(t)
Analyze theproduct with aramped field
Typical experiment
How many atomswere not ionizedby F(t) ?
Typical calculations
H = Hatom + z . F(t)
State of the electron
Classical Liouville equation.Solvable using a Monte Carlo approach ==> Hamilton equations.
Initial Final
CLASSICAL f(r,p,t)Probability density in phase space
; Lz=Const. ==>
f(r,p,0) = Const δ[En-Hatom(r,p)] x χ
(l<L<l+1) x χ
(m<Lz<m+1)
QUANTUM | Ψ(t)�Wavefunction
Schrödinger equation.Solvable using an expansionin a finite basis set ==>finite set of coupled equations
| Ψ(0)� = |n,l,m�
Initial state
Dynamics
2D time-dependent problem
�∆p = - dt F(t)
Tp << Torbequivalent to a sudden impulse or ''kick''
Tp >> Torbequivalent to staticfield ionization
Threshold Fp ~Forb = n-4Threshold: ∆p ~ porb = n-1
�ψf | exp(i∆p.r) | ψ
i �Pif = | | 2
10% ionization thresholds for Na(nd), H(nd), K(np)
0.1
1
10
∆p/p
orb
0.01 0.1 1 10
Tp/Torb
quantum & classical
Dunning et al (1996-99)Jones et al (1993) *2.5
Ionization by a single pulse
scaled variables
σp σr > 1 (atomic units)
σp0 σr0 > n-1 0
n ∞
r r0 = r/rorb = r/n2
p p0 = p/porb = p nt t0 = t/Torb = t/2πn3
F F0 = F/Forb = Fn4
Classical scaling invariance for H(n)
Uncertainty principle
"scaled Planck constant" = n-1
Classical dynamics is only a function of scaled variables.Departures from scaling invariance ==> quantum dynamics
classical scalinginvariant curve
quantum
n=1n=5
n=10
classical suppression
Quantum result Classical limit
Correspondence principle for one kick
λ = 1/∆p << rorb=n2
∆p0 >> n-1
10-4
10-3
10-2
10-1
100
Ioni
zatio
n pr
obab
ility
10-1 100 101
∆p0
Producing and probing coherent states
Hfree
e -i (εk-εn) t�Ψ(t)|O| Ψ(t)� = Σ ak an �φn|O| φk�
quantum beating frequencies: ωkn = (εk - εn)
*
| Ψ(t)� = Σ ak | φk� e -i εk t
Probing the time evolution
PROBEPUMPFA(t) FB(t)
Hfree | φk� = εk | φk�
H(t) = Hfree + z FB(t)
Probe duration < (2π/ωkn)
Coherent state (wavepacket)
RADIAL WAVEPACKETS PRODUCED BY SHORT LASER PULSES
Stroud (UR), Noordam(FOM), Bucksbaum(UM) et al (1980s)
| Ψ(t)�
n=39,40,41
PROBEionizes the atomwhen r is small
Hfree=HatomPUMP PROBE
PUMP
| φi�
kick
Recent pump-probe schemes using designer pulses
Probes
train of kicks
probing the momentum
probing the z coordinate
Pumps
Dunning et al, Jones et al
field step
Coherent state produced by a sudden kick
� pz � t=0 = ∆p
e -i (En'-En) t� pz � t = Σ Ann'
E(n+1)-En ≈ n-3 : classical orbital frequency
Ionization
0.1
1
10
Prob
abili
ty d
ensi
ty
-1.5 -1.0 -0.5 0.0 0.5
E0=E / |En|
�∆E� = (∆p)2/2
beforethe kick,K(417p)
after akick with∆p0=0.5
quantum
2 4 6 80-0.5
-0.3
-0.1
0.1
0.3
0.5
�pz 0�
classical
∆p0 = -0.5 H(100s)
Short times: classical-quantum correspondenceCorrespondence principle for the time evolution
Long times: classical dephasing / quantum revivals
-0.5
-0.3
-0.1
0.1
0.3
0.5
�pz 0�
0 10 20 30 40 50 60t0=t/Torb
quantum revival
The correspondence "break" time
Why is there one ?
Classical: continuous energy spectrumQuantum: discrete energy spectrum
revival ==> time evolution phases exp(-iEn) can be in phase
Why is there break time long for Rydberg atoms ?
narrow width spectrum ==> harmonic spectrum
classical orbital frequency ωn = n-3, Torb=2π/ ωn
��
�
�
��
�
���
���
�+−=−+
2
nnδnn nδn2
2nn31δnωEE δ
orb2dephasing Tn3
4ntδ
=
orbrevival T3nt =
Probing the momentum with a sudden kick
Classical energy transfer
∆E = ∆Hatom = ( ∆p )2_____ 2
+ pz ∆p
Whether or not the atom is ionized depends on the value of pz
Quantum result
Before the kick, t=t-Hatom =
p2__ 2
+ V(r)
Immediately after the kick, t=t+
+ V(r)Hatom = ( p + ∆p z ^ )2
__________ 2
| Ψ(t+)� = e i z ∆p | Ψ(t-)�
� pz �t+ = � pz �t- ∆p
� Hatom �t+
- � Hatom �t- = ∆p � pz �t- + (∆p)2/2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
Surv
ival
pro
babi
lity
delayF(t)
F(t)
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
0 10 20 30 40 50
Delay time (ns)
experiment
theory
�pz�
Pump/probe experiment for K(417p) Dunning et al (1996)
-0.3
-0.2
-0.1
0.0
0.1
0.3
-0.4
0.2
0 10 20 30 40
Delay time (ns)
0.60
0.65
0.70
0.75
0.80
-0.2
-0.1
0.1
0.2
0.0 �z0�
�z0�
experiment
Surv
ival
pro
babi
lity
experiment
�pz�-0.2
-0.1
0.0
0.1
0.2
�pz 0�
0.6
0.6
0.8
0.8
1.0
0 10 20 30 40
Pump/probe experiments for Rb(390p) Dunning et al (2000)
delay
delay
H = Hatom
FDC
Whether or not the atom is ionized depends on the value of z
H = Hatom + z FDC
Probing the z coordinate with a field step
Ebarrier
V(r) + z FDC
H > Ebarrier
Before the field step
After the field step
| Ψ(t)� = Σ | φs� e -i εk t
DC pump
Short rise time ==> coherent superposition of Stark states
H0 = Hatom + z FDC
�φs|Ψ(0)�
H0 | φs� = εs | φs�
Hydrogen:1 3
2n2 2εs = εn,k = - + FDC n k
εs - εs' ≈ j ωorb + k ωStark
nearest neighbor spacing: ωStark = 3 FDC n
Using a field step to produce Stark wavepackets
1st
3rd
2nd
Stark dynamics
j1,2 = ( L ± n A ) / 2 ω = 2 ωStark
Field
j1
j2
Field
L: angular momentumA: Runge-Lenz vector
A
Angular momentum wavepacketH(17d) at t=0
Quantum
Classical
t/Torb
/t/Torb
Field
Ener
gy
delay
Probing Stark beats with a short half-cycle pulse
experiment K(388p)
ωorb
ωStark
0 100 200 300 400Delay time (ns)
0.4
0.6
0.8
1.0
Surv
ival
pro
babi
lity
0.5
0.7
0.9ωStark
FDC = 5mV/cm, FHCP= ± 80mV/cm
time
Fiel
d
DC pump
HCP probe
classical simulation
Stark map near n=100 of K(m=0)
350
370
390
410
430
450n=
(-2E)
1/2
0.00 0.01 0.02 0.03 0.04 0.05 0.06 0.07
F0
Diagram of extreme Stark states near n=400
field ionizationthreshold
n=450
n=350
n=399,400,401
FULL MIXINGchaotic spectrum
Raw nearest neighbor spacing density near n=100
Hydrogen:Poisson spectrum
Potassium:Wigner spectrumSp
ectr a
l den
s ity
∆E/(3FDC)
0 50 100 150
∆E/(3F DC)
0.00
0.05
0.10
0.15
Spec
tral d
ensi
ty
0.00
0.05
0.10
0.15
0.20
0.25
Step field ==> weighted spectrumweight= overlap with state prior to the step
Potassium
Hydrogen
Coherent states produced by a train of pulses
Fiel
d
time
PUMP
delay time
0 5 10 15 200.20
0.22
0.24
0.26
0.28
0.30
PROBE
100 pulses with scaled frequency ν0
0.25
0.27
0.29
0.31
0.33
0.35
0 5 10 15 20
Surv
ival
pro
babi
lity
Delay time (ns)
ν0=0.7
ν0=0.7
ν0=1.3
ν0=1.3
InitialEnergylevel
p0
q0
Tailoring Rydberg wavefunctions
Classical quantum correspondenceHigh n, large perturbations, short times
Producing and probing coherent states
Recent interesting studies
Information storage and retrieval with Rydberg atomsAhn, Weinacht, and Bucksbaum, Science (2000)
Rydberg antihydrogen production using a fast field stepWesdorp, Robicheaux, Noordam, Phys. Rev. Lett. 84, 3799 (2000
Tp
Torb= 2πn3
Forb= n-4F(t)
Half-cycle pulse (HCP) H(n)
Tp << Torb sudden momentum transfer or ''kick''
�∆p = - dt F(t)
F(t)
F(t) T
The kicked Rydberg atom
ν = 1/TH = Hatom + z F(t)
time
The kicked atom: linear superposition of HCPs
unidirectional
alternating
Ideal testing ground for quantum systems that may become chaotic in their classical limit
Simple driven systems
Experimental realizations
1980s-90s Rydberg atoms + microwave fieldKoch et al (Stony Brook), Bayfield (Pittsburgh)
1994 Atoms in a trap subject to a modulated standing waveRaizen et al (Austin)
1997 Rydberg electrons subject to trains ofhalf-cycle pulsesDunning et al (Rice)
H = Hatom + z F(t)
≈ p2 __ 2
_ 1 __ r
_ Σkz ∆p δ(t-kT)
The 1D periodically kicked atom
p2 __ 2
_ _ ΣkH = 1 __
qq ∆p δ(t-kT)
time dependentLz = Const ==> 2 1/2 degrees of freedom
1 1/2 degrees of freedom
U(kT,0) = Π k
UFree(Hatom,T) U
Kick(∆p)
e-iHatomT eiz∆p
(quantum)
Classical or quantumevolution operator
The 3D periodically kicked atom (unidirectional pulses)
Time evolution ==> simple discrete map
100 δ kicks
1000 δ kicks
finitewidthpulses
experiment
Scaled frequency, ν0 = ν/νorb
3D, n=390, 50 pulses 1D, n=50
Classicalstabilization !!0.6
1.92.1
ν0 = 1.3
3D, n=390
100 101 102 103 104 105 106
Number of pulses, N
10-3
10-2
10-1
100
Surv
ival
pro
babi
lity
0.7
delta kicks
0.1 1 10
0.1
1
How many atoms survive after many pulses ? Experiments and classical simulations
1 100.0
0.1
0.2
0.3
0.4
0.5
0.6
Surv
ival
pro
babi
lity
Isolating stable orbits
Consecutive intersections of a stable orbit with a plane yields a closed loop.
t=k/νp (k=1,2,...)ρ=Const.pρ=Const.
Hatom = + - (ρ2 + z2 )1/2
Lzpz + pρ2 2 2
1
2 2 ρ2 Lz = Const ~ 0
0.0 0.5 1.0 1.5 2.0 2.5 3.0z
-2
-1
0
1
2
p z
Hatom ~ pz
2__ 2
- 1___ | z |
Hatom = -0.5
Hatom = 0
Hatom = -2
Section for ∆p=0, ρ ~ 0, pρ ~ 0, Lz~0
stroboscopic Poincaresection
x
x
Section just before a kick, ρ=0, pρ=0, for ν0=1.3
∆E = ( ∆p )2_____ 2
+ pz ∆p = 0
pz=-∆p/2
Most stable periodic orbit
Fixedpoint
∆p
Correspondence between the 1D and 3D models
Structures in the classical survival probability
ν0=0.7 ν0=1.3
Initial energy level
p0
q0
0.1
1Su
rviv
al p
roba
bilit
y
0.1 1 10
Scaled frequency
1000 kicks
100 kicks
1D, n=50
0
20
0 q1
2p0.5E −=−=
Classical-quantum correspondence ?
1D kicked atom
∆p
1/q
Classical
Quantum
1D H(n=50) atom after 200 kicks
10-1 100 101Scaled frequency
10-1
100
Surv
ival
pro
babi
lity
1D ==> accurate quantum calculations can be be performed for large n
|Ψ(t)�
|Ψ(0)� = |Φi(t)� : initial state
- Boundary condition
- Dynamics: Schrödinger Equation
- State of the electron:
d|Ψ(t)�dt
i = H |Ψ(t)�
How can we compare classical and quantum dynamics in phase space ?
Husimi distributions:Quantum analog of classical phase space distributions:
Husimi disctributions of Floquet states
Quantum analog of Poincare sections
Usual quantum description of the electron
fw(q,p,t) = dy �q-y|Ψ(t)� �Ψ(t)|q+y� e2ipy
Weyl transform of the density matrix
�
dfwdt = Lqm fw
�1
fw (q,p,t): real quasi probability density (not positive definite)
�A� = dqdp fw(q,p,t) A(q,p)
�|�q|Ψ(t)�|2 = dp fw(q,p,t)
Classical limit: Lqm ≈ Lcl
State of the electron: Wigner function
Dynamics: quantum Liouville equation
π
Alternative quantum description of the electron
minimum uncertainty Gaussian wavepacket
classical
quantum
0.00
0.10
0.15
0.20
0.25
Prob
abili
ty d
ensi
ty
0.05
0.0 0.5 1.0 1.5 2.0 2.5 3.0p
Comparing classical and quantum densities
Husimi distribution: Gaussian smoothed Wigner function
Direct comparison with Wigner functions is difficult
fh (q,p,t) = | �gq,p|Ψ(t)�|2 > 0
gq,p(q') = C e-(q-q')2/a eipq'
Husimi distribution of the 1D n=50 level
__p02
2-0.5 = _ 1 __
q0
PCL ~ (p0)-1/2
probability maximizesat the outer turning point
classical
PQM(q,p)
q0
p0
0.00.5
1.01.5
2.02.5
-2
-1
0
1
2-0.05
-0.03
-0.01
0.01
0.03
0.05
Classical phase space vs quantum Husimi distributions
outgoing flux(norm not conserved)finite Hilbert
space
complex quasi eigenenergy period-oneevolution operator
Floquet analysis in a finite basis set
Floquet states:
Soft boudary conditions
U(T,0) |φk� = e-iεkT |φk�
Σ|Ψ(NT)� = ck e-iεkNT |φk�
k
Stable Floquet states: Im(εk) = 0
Husimi distributions of stable Floquet states for ν0=1.3
quantum
quantum
classical
Periodic orbits and fixed points
stable unstable
Any trace of unstable periodic orbits in quantum mechanics ?
∆p
Quantum localization for high frequencies
n=50, ν0=16.8, ∆p
0=-0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
Surv
ival
pro
babi
lity
1 10 100Number of kicks
classical
quantum
breaktime
-2.5-1.5
-0.50.5
1.5
2.5
0.00.5
1.0
1.5
2.0
Husimi distribution of a stable Floquet state for ν0=16.8
q0p0
Stable Floquet states ==> scarred statesHeller (1980s)
unstable periodic orbit
P(q,p)
Why does the survival probability oscillate ?
E=0
Localization in the continuum
Classical phase space
Initiallevel
�
Husimi distributions of stable Floquet states
X: classical fixed points : Unstable periodic orbits
Correspondence for high frequencies, ν0=16.8and strong perturbations, ∆p0=-0.3
Classical phase space
Initiallevel
�
Husimi distributions of stable Floquet states
X: classical fixed points
Lack of correspondence for weak perturbations, ∆p0=+0.01
n=50ν0=16.8
What do periodic orbits resemble ?
t)mcos(2π2FFkT)-δ(t ∆pF(t)1m
avavk
ν��≥
+==
t)mcos(2π2qFHH(t)1m
avStark ν�≥
−=
avatomStark qFHH −=
Fav=∆p/T = average field
Stark orbit
Coulomborbit
Localization in energy space
Direct excitation probabilities by all harmonicsTime averaged numerical resultDipole coupling
X
Occ
upat
ion
prob
abilit
yaf
ter 6
00 k
icks
Types of diffusionResonant diffusion � Non-linear level spacingClassical diffusion � Quantum uncertainty
Localization widths
What stops diffusion ?
Dipole coupling and driving frequencyEnergy excursion within the periodic orbit, ∆Eorbit
ω
Small ∆p � ∆Eorbit<<ω
Correspondence for the localization widthO
ccup
atio
n pr
obab
ility
afte
r 600
kic
ks ω
Large ∆p � ∆Eorbit> ω
Direct excitation probabilities by all harmonicsDipole coupling
∆Eorbit
The kicked Rydberg atom
Long timesClassical quantumCorrespondence
- short times- high n- large perturbations
Classical
quantum
Outlook
- Localization in 3D- Adding noise and other trains of pulses- Any train of pulses leading to long lived coherent states ?
Cross-disciplinary
Transport of atoms through solids
i
dissipative interactionwith the environment
= [Hatom,ρ] + R ρdρdt
+ V(r)p2
2Hatom =Screened ion field
STATE OF THE SYSTEM: ρcl(r,p,t)DYNAMICS: classical Liouville equation
STATE OF THE SYSTEM: reduced density matrix ρ(t)
DYNAMICS: quantum Liouville equation
CLASSICAL TRANSPORT:
Transmission of fast atoms through solids The randomlykicked atom
Microscopic interaction
Vint
)p(∆V~ i|e|f pd∆dtdP
intr.pi∆ ��
��
�∝
First order transition probability per unit time
Fourier transform: Probability distribution of kicks
Transition amplitudefor a given ∆p
Similarity to quantum optics
Microscopic approach: Langevin equation
kΣr .
1N Σ
N.u=1
ρ(t) = |Ψu(t)��Ψu(t)|quantum trajectory
Random multiple elastic and inelasticcollisions with particles in the solid.
H = Hatom ∆pk δ(t-tk)
Langevin equation: undeterministic Schrödinger equation
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