1. TNSA laser driven ion acceleration
Claudio Perego
21/09/2018
TNSA laser driven ion acceleration
Theoretical modeling and analytical predictions
Claudio Perego
Dottorato in Fisica ed Astronomia:
Seminario conclusivo 2° Anno
Dipartimento di Fisica
Università degli Studi Milano-Bicocca
25 Ottobre 2011
TNSA Laser Driven Ion Acceleration

2. Outline Introduction to TNSA Analytical Modeling
Claudio Perego
21/09/2018
Outline
Target Normal Sheath Acceleration Effective Modeling
Introduction to TNSA
Analytical Modeling
Different Descriptions
Passoni-Lontano Model
New Insights
Target Thickness Dependence
Experiments
Mass-limited targets
Conclusions and Perspectives
Intro – Parte generale sulla modellizzazione – Parte più specifica sullo spessore
Target Normal Sheath Acceleration Effective Modeling

3. Outline Introduction to TNSA Analytical Modeling
Claudio Perego
21/09/2018
Outline
Target Normal Sheath Acceleration Effective Modeling
Introduction to TNSA
Analytical Modeling
Different Descriptions
Passoni-Lontano Model
New Insights
Target Thickness Dependence
Experiments
Mass-limited targets
Conclusions and Perspectives
Target Normal Sheath Acceleration Effective Modeling

4. Multi-MeV ion beams normal to the target surface
Claudio Perego
21/09/2018
Introduction
Target Normal Sheath Acceleration Effective Modeling
Ultra-intense & Ultra-short Laser Pulse
Focused on a thin solid target Conductor or insulator
Multi-MeV ion beams normal to the target surface
E.L. Clark et al., Phys. Rev. Lett. 84 (2000)
A. Maksimchuk et al., Phys. Rev. Lett. 84 (2000)
R. A. Snavely et al. Phys. Rev. Lett. 85 (2000)
Ion Beam Features
Normal direction
Exponential spectrum with Multi-MeV cut-off
High ion-per-bunch number > 1012
Low longitudinal (< eVs) and transverse emittance (< 10-8 mrad)
Low divergence < 15°
Target Normal Sheath Acceleration Effective Modeling

5. Foreseen Applications
Claudio Perego
21/09/2018
Foreseen Applications
Target Normal Sheath Acceleration Effective Modeling
L.Romagnani, et al. Phys. Rev. Lett. 95 (2005)
Proton radiography
Hadron-therapy
Fast ignition
PET isotopes …
We need to control the beam parameters t
S. V. Bulanov, et al. Phys. Lett. A 299 (2002)
Target
Need for Theoretical
modeling
M.Roth, et al. Phys. Rev. Lett. 86 (2001)
Target Normal Sheath Acceleration Effective Modeling

6. Ions from target surface and substrate are accelerated up to MeV
Claudio Perego
21/09/2018
Target Normal Sheath
Acceleration (TNSA)
Target Normal Sheath Acceleration Effective Modeling
S.C. Wilks et al. Phys. Plasmas. 8 (2001)
Front (Vacuum)
Target
Rear (Vacuum)
Hot e- current
Return current
Accelerated Ions
e- sheath - +
Accelerated Ions + -
Laser Pulse
Espansione elettroni
Nuvole elettroniche, separazione di carica, campi elettrici
Accelerazione ioni
1)Faccia avanti e dietro
2)Protoni da strato di impurità + ioni
Ions from target surface and substrate are accelerated up to MeV
Target Normal Sheath Acceleration Effective Modeling

7. TNSA Theoretical Modeling
Claudio Perego
21/09/2018
TNSA Theoretical Modeling
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
We need a reliable theoretical description of:
Laser-Matter Interaction
Hot Electrons Transport
Ion Acceleration
Target
2 possible ways: - + + -
Numerical Simulation of Vlasov System
Quite complete description of the physics
Very high computational load, hardly feasible with a set of realistic parameters
Simplified Models
Analytical or semi-analytical solutions
Prediction of Scaling Laws
Lack of detail in the description of the system
Target Normal Sheath Acceleration Effective Modeling

8. Outline Introduction to TNSA Analytical Modeling
Claudio Perego
21/09/2018
Outline
Target Normal Sheath Acceleration Effective Modeling
Introduction to TNSA
Analytical Modeling
Different Descriptions
Passoni-Lontano Model
New Insights
Target Thickness Dependence
Experiments
Mass-limited targets
Conclusions and Perspectives
Target Normal Sheath Acceleration Effective Modeling

9. Claudio Perego
21/09/2018
TNSA Models (I)
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
Among the TNSA models we can find some common features:
The description is focused on the acceleration phase
Laser-matter interaction and hot electron transport phases set up the initial conditions:
Hot electron distribution, usually Maxwell-Boltzmann
Hot electron temperature, usually ponderomotive scaling
Assumption of planar symmetry: 1-dimensional description
Target Normal Sheath Acceleration Effective Modeling

10. TNSA Models (II) Fluid Approach Quasi-static Approach Hybrid Models
Claudio Perego
21/09/2018
TNSA Models (II)
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
Fluid Approach
Target described as a fluid plasma
The hot electron fast expansion drives the motion of the ion population
J.E. Crow et al., J. Plasma Phys. 14 (1975)
P. Mora, Phys. Rev. Lett. 90 (2003)
P. Mora, Phys. Rev. E 72 (2005)
T. Grysmayer et al. Phys. Rev. E. 77 (2008)
Quasi-static Approach
Bulk i+
Fixed Bulk Ions and thermal hot electrons
Accelerated test Ions in a static electric field
Only the first stages of the process described
Anticipo già che i modelli tendono a descrivere solo la fase di accelerazione. Le fasi antecedenti sono tenute in considerazione dalle ipotesi del modello (distribuzione e temperatura elettroni caldi) +
Hot e- cloud + + +
M. Passoni & M. Lontano, Laser & Part. Beams, 22 (2004)
M. Lontano & M. Passoni, Phys. Plasmas, 13 (2006)
J. Schreiber et al., Phys. Rev. Lett 97 (2006)
Hybrid Models
A.P.L. Robinson et al., Phys. Rev. Lett. 96 (2006)
B.J. Albright et al., Phys. Rev. Lett. 97 (2006)
TNSA Laser Driven Ion Acceleration

11. Models Compared Remarks: Input Parameters
Claudio Perego
21/09/2018
Models Compared
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
A database of experimental measurements of the peak ion energy have been compared to the theoretical predictions provided by six different models
C. Perego et Al., Nucl. Instr. & Methods A, 653 (2011)
Remarks:
Mora Isothermal
Mora Adiabatic
Schreiber
Input Parameters
Some are provided by the experimental papers
Some others cannot be measured and need to be estimated
Results depending on the arbitrary choice of the estimates
Passoni-Lontano
Albright Scaling
Robinson
Interaction and Transport Phases
No complete or reliable modeling of such physical processes
The models describe TNSA starting from simple assumptions
Need to improve the connection to those two phases
Experimental
Theoretical
Target Normal Sheath Acceleration Effective Modeling

12. Passoni-Lontano Quasi-Static Model Maximum Ion Energy Relativistic
Claudio Perego
21/09/2018
Passoni-Lontano
Quasi-Static Model
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
M. Lontano & M. Passoni, Phys. Plasmas, 13 (2006)
M. Passoni & M. Lontano, Phys. Rev. Lett 101 (2008)
M. Passoni et al., New J. Phys. 12 (2010)
1D, Ion fixed, static longitudinal field
Sheath truncation Issue, divergent potential
Solution of Poisson equation with bound electrons charge density
Finite potential difference, analytical prediction for the peak energy
Most energetic electrons lost by the system
e- lost
e- bound + + + +
Relativistic
Non-Relativistic
Maximum Ion Energy
Target Normal Sheath Acceleration Effective Modeling

13. Quasi-Static Model (II)
Claudio Perego
21/09/2018
Passoni-Lontano
Quasi-Static Model (II)
Target Normal Sheath Acceleration Effective Modeling
9/21/2018 QN
Plasma
Left Boundary
Depends only on:
The hot electron temperature
The bounded electron maximum kinetic energy
Estimates:
Ponderomotive Scaling
S.C. Wilks et al. Phys. Rev. Lett 69 (1992)
Empirical Scaling
M. Passoni et al., Phys. Rev. Lett 101 (2008)
Concludo dicendo che cerchiamo quindi di aggiungere dettaglio alla parte iniziale del processo
We need further detail in the description of laser-matter interaction and hot electron transport phases
Target Normal Sheath Acceleration Effective Modeling

14. A constraint at the left boundary of Poisson equation is provided
Claudio Perego
21/09/2018
Further Hypotesis
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
1-Laser-Matter Interaction
The laser energy is partially absorbed and distributed among the hot electrons QN
Plasma
2-Electron Transport
The hot electron population expand through the target reaching the quasi-static equilibrium
3-Ion Acceleration
A constraint at the left boundary of Poisson equation is provided
A relation for is obtained:
Target Normal Sheath Acceleration Effective Modeling

15. Theoretical Result Relativistic Result Observations:
Claudio Perego
21/09/2018
Theoretical Result
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
Relativistic Result
Observations:
Physical support to the behavior
A connection to key parameters is provided
The modeling of such parameters could open some interesting paths
The normalization is still unknown, the system is not closed yet, we need to use the empirical scaling for .
Target Normal Sheath Acceleration Effective Modeling

16. Partial Conclusions: TNSA Modeling has been presented and investigated
Claudio Perego
21/09/2018
Partial Conclusions:
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
TNSA Modeling has been presented and investigated
Theoretical models quantitative comparison:
The Passoni-Lontano quasi-static model turns out to be a convenient scheme to predict the peak energy
Limited knowledge on interaction and transport phases
Passoni-Lontano quasi-static description
Introduction of further details in the theoretical basis of the model
New relation for the parameter , which connects the model to some key parameters of the system as
Modeling of such parameters can extend the model predicting capability
Target Normal Sheath Acceleration Effective Modeling

17. Outline Introduction to TNSA Analytical Modeling
Claudio Perego
21/09/2018
Outline
Target Normal Sheath Acceleration Effective Modeling
Introduction to TNSA
Analytical Modeling
Different Descriptions
Passoni-Lontano Model
New Insights
Target Thickness Dependence
Experiments
Mass-limited targets
Conclusions and Perspectives
Target Normal Sheath Acceleration Effective Modeling

18. Target Thickness Energy Dependence
Claudio Perego
21/09/2018
Target Thickness Energy Dependence
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
Optimum thickness
Targets thicker than the optimum
Targets thinner than the optimum
High contrast
M. Kaluza et al. Phys. Rev. Lett. 93 (2004)
I. Spencer et al. Phys. Rev. E 67 (2003)
J. Fuchs et al. Nat. Phys. 48 (2006)
D. Neely et al. Appl. Phys. Lett. 89 (2006)
T. Ceccotti et al. Phys. Rev. Lett. 99 (2007)
Target Normal Sheath Acceleration Effective Modeling

19. Transport model (I) The laser pulse heats up electrons
Claudio Perego
21/09/2018
Transport model (I)
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
The laser pulse heats up electrons
The electrons expand through the target with almost collisionless dynamics
The divergence of the hot electron beams has been studied experimentally
Estimating the volume occupied by the hot electrons we can evaluate the hot electron density at the accelerating surface
Target Normal Sheath Acceleration Effective Modeling

20. Claudio Perego
21/09/2018
Transport model (II)
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
Due to the charge separation, the fast electron reflux back into the target while the quasi-static equilibrium is reached
This affects the hot electron density at the accelerating sheath
The minimum time required for the formation of the accelerating field is
We assume that the electrons travel at speed , and that the rise time of the electro-static field is
For thin targets ( ) the electron reflux is more effective
Target Normal Sheath Acceleration Effective Modeling

21. Claudio Perego
21/09/2018
Transport model (III)
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
In an infinite target the electrons cover a longitudinal distance during the field formation
We evaluate the density of hot electrons for the infinite target
In the real target the volume is longitudinally shrinked and the actual density is multiplied by the factor
The description can be strongly refined
Target Normal Sheath Acceleration Effective Modeling

22. Claudio Perego
21/09/2018
Results (I)
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
It is now possible to predict the thickness dependence with the quasi-static model
We obtained the hot electron density at the sheath as a function of divergence angle and target thickness
depends on and via the equation (relativistic)
Now we can evaluate and compare it to the experimental measurements
The normalization is still unknown. We need to evaluate it imposing that the scaling holds for some thickness
Target Normal Sheath Acceleration Effective Modeling

23. Claudio Perego
21/09/2018
Results (II)
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
J. Fuchs et al. Nat. Phys. 48 (2006)
The agreement with the experimental measurements is remarkable in some cases
may depend on the reflux dynamics
The normalization issue should be solved to perform more reliable comparisons
T. Ceccotti et al. Phys. Rev. Lett. 99 (2007)
M. Kaluza et al. Phys. Rev. Lett. 93 (2004)
Electron
Divergence
15°
30°
45°
Target Normal Sheath Acceleration Effective Modeling

24. The physical description can be improved in many ways …
Claudio Perego
21/09/2018
Results (III)
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
D. Neely et al. Appl. Phys. Lett. 89 (2006)
In other cases the agreement is not satisfactory
The electron divergence angle doesn’t affect heavily the dependence
No domain of applicability is pointed out from the comparisons
LOA Experimental Campaign April-June 2011
Electron
Divergence
15°
30°
45°
The physical description can be improved in many ways …
Target Normal Sheath Acceleration Effective Modeling

25. Possible Improvements
Claudio Perego
21/09/2018
Possible Improvements
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
Collisional and radiative effects can influence the hot electron distribution even at such short timescales.
Collisional and radiative stopping power
Target material information
The hot electrons density profile can be modeled in longitudinal and transverse direction
Gaussian or Breit-Wigner transverse profile
Exponential attenuation in the longitudinal direction
The refluxing electrons may be re-heated up by the laser
…Other key aspects of the hot electron dynamics cannot be described in a straightforward way (instabilities, magnetic effects…)
Target Normal Sheath Acceleration Effective Modeling

26. Rear Face Thermal Emission
Claudio Perego
21/09/2018
Mass-Limited Targets
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
It has been shown that using mass-limited targets the acceleration can be more effective
Maximum proton energy and conversion as well as the hot electron temperature increase reducing the surface area of the target
This can be the effect of transverse reflux of the electrons at the target boundaries
S. Bouffechoux et Al., Phys. Rev. Lett, 105 (2010)
Rear Face Thermal Emission
Target Normal Sheath Acceleration Effective Modeling

27. Claudio Perego
21/09/2018
Lateral Reflux model
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
Hot electrons are confined by the target lateral surface
The hot electron density is amplified by a factor
Measurements show a temperature increase which should be taken into account
Target Normal Sheath Acceleration Effective Modeling

28. Outline Introduction to TNSA Analytical Modeling
Claudio Perego
21/09/2018
Outline
Target Normal Sheath Acceleration Effective Modeling
Introduction to TNSA
Analytical Modeling
Different Descriptions
Passoni-Lontano Model
New Insights
Target Thickness Dependence
Experiments
Mass-limited targets
Conclusions and Perspectives
Target Normal Sheath Acceleration Effective Modeling

29. Conclusions A simple hot electron transport model has been proposed
Claudio Perego
21/09/2018
Conclusions
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
A simple hot electron transport model has been proposed
Informations about target thickness and electrons divergence are implemented in Passoni-Lontano predictions
The experimental results are partially reproduced
Mass-limited targets can improve TNSA acceleration
Our model for the electron transport can explain such an effect
The measured energy increase is greater than our predictions
The description needs to be improved
Further physical details can be implemented while some aspects of the dynamics require numerical studies
A consistent way to close the system is still needed
The laser-matter interaction modeling is neither precise nor reliable
Target Normal Sheath Acceleration Effective Modeling

30. Perspectives Analytical Work Numerical and Experimental Work
Claudio Perego
21/09/2018
Perspectives
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
Analytical Work
Hot electrons stopping power effects and density profiling implementation
Laser-matter interaction description
Stable and reliable initial conditions
3D solution of the electrostatic problem (Poisson-Boltzmann theory)
Consistent closure of the system
Numerical and Experimental Work
Parametric studies to understand the dependencies
New scaling laws for the initial conditions
Weight of instabilities and magnetic effects
Validation of the Analytical results
Target Normal Sheath Acceleration Effective Modeling

31. Thank You!!! The End Claudio Perego 21/09/2018
Target Normal Sheath Acceleration Effective Modeling
21/09/2018
Thank You!!!
Target Normal Sheath Acceleration Effective Modeling

32. LOA Experiment (II) Pre-Heating Results Pump Energy:
Claudio Perego
21/09/2018
LOA Experiment (II)
Target Normal Sheath Acceleration Effective Modeling
9/21/2018
Pre-Heating Results
Pump Energy:
Pre-heating Beam Energy:
Pre-heating Beam Intensity:
Al targets different thicknesses: s
The results for different thicknesses show a similar behavior
Energy drop up to ps delay
Slight increase for higher delays
Strong instability with preheating
…Simulation being performed
Target Normal Sheath Acceleration Effective Modeling