SMALL CLUSTERS OF para- HYDROGEN
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SMALL CLUSTERS OF para-HYDROGEN Jesús Navarro and Rafael Guardiola IFIC and Universidad de Valencia 14 th International Conference on Recent Progress in Many Body Theories Barcelona, July 16-20 2007
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SMALL CLUSTERS OF para- HYDROGEN. Jesús Navarro and Rafael Guardiola IFIC and Universidad de Valencia 14 th International Conference on Recent Progress in Many Body Theories Barcelona, July 16-20 2007. The Hydrogen molecule. Bound system of two hydrogen atoms Two species: - PowerPoint PPT Presentation
Transcript of SMALL CLUSTERS OF para- HYDROGEN
SMALL CLUSTERS OF
para-HYDROGEN
Jesús Navarroand
Rafael GuardiolaIFIC and Universidad de
Valencia
14 th International Conference on Recent Progressin Many Body Theories
Barcelona, July 16-20 2007
The Hydrogen molecule Bound system of two hydrogen atoms Two species: >Para-Hydrogen : nuclear spins
coupled to S=0, so space symmetric >Ortho-Hydrogen: Nuclear spins
coupled to S=1, so space antisymmetric
As an elementary constituent, both cases correspond to a BOSON
Properties of the molecule Mass : 2.0198 amu Equilibrium distance: R=1.4 bohr Electronic binding energy (without lowest
vibrational correction) D=38293.04 cm-1
Dissociation energy (including zero-point motion) Theory: D=36118.06 cm-1 L.
Wolniewicz, J. Chem. Phys. 103, 1792 (1995) Experiment: 36118.062(10) cm-1
Y.P. Zhang, C.H. Cheng, J.T. Kim, J. Stanojevic, and E.E. Eyler, Phys. Rev. Lett. 92, 203003 (2004).
Rovibrational spectrumDunham formula of a vibrating rotorJ.L. Dunham, Phys. Rev. 41 , 721 (1932)
l=1, m=0 4401.21
l=2, m=0 -121.34
l=0, m=1 60.853
l=1, m=1 -3.062
l=3, m=0 0.813
Y (cm-1)
Molecular spectrum
Q means DJ=0
S means DJ=2
Transitions depleted because of Bose symmetry and Spin. Dipolar transitions do not exist and higher electromagnetic orders are requested
Properties of the extended system
The energy difference between oH and pH is 170.50 K: at room temperature equilibrium hydrogen is 75% ortho and 25% para
Enrichment of para-H is slow, requires magnetic anisotropies to change the ortho spin (magnetically active catalysts)
The critical point for para-H is Tc = 33 K and Pc= 1.3 MPa
Properties of the extended system (contd.) The triple point where hydrogen
begins to solidify under saturated vapor pressure is TTP = 13.8 K at PTP=0.72 MPa
At T=0 it is an hcp solid density = 0.026 molecules per Å3 Energy per particle 93.5 K M.J.Norman, R.O.Watts and U. Buck, J. Chem. Phys. 81, 3500 (1984).
Small para-Hydrogen clusters:dimer A. Watanabe and H.L. Welsh
Phys.Rev.Lett. 13, 810 (1964) A.R.W. McKellar
J.Chem.Phys. 92, 3261 (1990) A.R.W. McKellar
J. Chem. Phys. 95, 3081 (1991) Technique: Infrared Absorption by
gas at 20 K
Small para-Hydrogen clusters:dimer Pure
rotational absorption splitting of Dn=0 DJ=2 line S0(0)
Small para-Hydrogen clusters:dimer
Rovibrational absorption Splitting of Dn=1 DJ=2 line S1(0)
Small para-Hydrogen clusters:Conclusions on dimer
Proof of the existence of bound state
Determination of excitation spectrum, both bound and resonant levels
Para-Hydrogen clusters: Motivation
They have been detected We have some expertise in dealing
with clusters Interesting questions raised: are quantal or classical? Some clusters are magical Solid-like or liquid-like?
Raman shifts and identification of small clusters G. Tejeda, J.M. Fernández, S.Montero, D. Blume
and J. P. Toennies Phys. Rev. Lett. 92, 223401 (2004)
Measurement of Q1(0) Raman shift of para-Hydrogen molecules in small clusters
Alternative method to mass diffraction Intermolecular effects on intramolecular
interaction J. van Kranendonk and G. Karl
Rev.Mod.Phys. 40, 531 (1968) studies the effect in hcp solid.
Pictures of the experimental set
Experimental results
N Dn cm-1
2 -0.400
3 -0.822
4 -1.521
5 -1.594
6 -1.904
7 -2.316
8 -2.350
Ortho-Hydrogen impurities
Mag
ical
clu
sters
The two-body problem and H2-H2 interacion
U. Buck, F. Huisken, A. Kohlhase, D. Otten, and J. Schaeffer J. Chem. Phys. 78, 4439 (1983) I.F. Silvera, V.V. Goldman, J. Chem. Phys. 69, 4209 (1978)
M(H2) ≈ M(He)/2, but Vmin(H2) ≈ 4 Vmin(He): Larger zero-point energy but more attraction
B=4.311 K
<r>=5.13 Å
B=0.0018 K
<r>=57.33 Å
Theoretical analysis: previous work P. Sindzingre, D.M.Ceperley and M.L.Klein,
Phys.Rev.Lett. 67, 14 (1992) (13, 18 and 33) Daphna Scharf, Michael L. Klein and Glenn J.
Martyna, J. Chem.Phys. 97, 3590 (1992) (13, 19, 33, and 34)
Michele A. McMahon, Robert N. Barnett, and K. Birgitta Whaley, J. Chem.Phys. 99, 8816 (1993) (N=7)
Michele A. McMahon, K. Birgitta Whaley, Chem. Phys. 182, 119 (1994) (6, 7, 13, 33)
E. Cheng, Michele A. McMahon, and K. Birgitta Whaley, J. Chem. Phys. 104, 2669 (1996) (N=7)
Theoretical analysis: recent work Rafael Guardiola and Jesús Navarro
Phys. Rev. A 74, 025201 (2006) DMC - BUCK Javier Eduardo Cuervo and Pierre-Nicholas Roy
J.Chem.Phys. 125, 124314 (2006) PIGS – BUCK & SILVERA
Fabio Mezzacapo and Massimo Boninsegni Phys.Rev.Lett. 97, 045301 (2006) PIMC - SILVERA
Fabio Mezzacapo and Massimo Boninsegni Phys.Rev. A 75, 033201 (2007) PIMC - SILVERA
S. A. Khairallah, M. B. Sevryuk, D.M.Ceperley and J. P. Toennies Phys.Rev.Lett. 98, 183401 (2007) PIMC - SILVERA
Present situation
DMC and PIMC in agreement for N<25
but large discrepancies for N between 30 and 40
Our action: revise DMC
Importance sampling trial function for DMC
Two- and three-body Jastrow correlationsK.E.Schmidt, M.A.Lee and m.H.Kalos, Phys.Rev.Lett. 47, 807(1981)
p5, sT and wT are fairly independent of cluster size
DMC: characteristics
t (K-
1)N=10 N=20 N=30
0.001 183.47 0.05 559.28 0.17 1006.4 0.3
0.0005 185.91 0.06 566.56 0.17 1020.0 0.4
Extrap t =0
186.72 0.09 568.99 0.28 1024.5 0.5
0.0001 186.93 0.06 569.16 0.12 1025.2 0.2
0.00002
186.72 0.03 569.48 0.07 1024.8 0.1Richardson extrapolation assumes a correction O(t2)
Acceptable value for t=0.0001, without bias. Sampling up to T=10 K-1
Calculations: N-walkers=1000, Nsteps=105
Error control: Statistical analysis of 10 independent runs to avoid statistical correlations
VMC versus DMC
Three-body correlations provide more than 50% of the missing variational energy
Dissociation energy and magical clusters: DMC
Magical N=13 observed
Magical? N=36 for BUCK potential
Silvera: less statistics, results scattered
BUCK and SILVERA qualitatively similar
Comparison DMC-PIMC
Clear disagreement between DMC and PIMC calculations
The origin of the disagreement
Is DMC too strongly constrained by the importance sampling wave function?
Have PIMC calculations too optimistic error estimates?
NOT: different potentials NOT: poor DMC statistics
One-body distributionsDMC and VMC(Jastrow-2)
Conclusion: well defined geometrical shells, even in VMC.
Trial function is liquid-like but reveals signs of shells
Shells actually constructed by DMC algorithm
Comparison with He clusters
Para-Hydrogen Helium
Shell occupancy
Centroids : c
Widths : s
About the structure of shells Radii of shells grow slowly but
steadily:Elastic shells
Widths of gaussians (error bars) fairly constant
After N=50 the particle at the center dissapears, and reappears near N=70
Inner shells with non constant number of particles
Pair distribution functionsparahydrogen helium
Parahydrogen has a crystal-like structure, absent in Helium
N=2 N=30
A long way to a classical system
Definite analysis of clusters would require …
To find a very good variational wave function
Variations on the variational wave function: shells
A model with shells: add one-body terms
Or with a quenching parameter
Variations on the variational wave function: solid-like
Nosanov-like wave function
Both approaches give rise to a minimal gain in energy.
Open question! Lack of imagination?
FINAL COMMENTS Hydrogen clusters are fascinating, with
a richness of properties not found in the more familiar 4He clusters.
Open problems: >PIMC calculations should be revisited >Other variational forms for DMC
should be experimented. >One should fill the gap between T=0
and non null temperatures by studying the excitation spectrum of clusters.
Excitation spectrum: preliminary
Levels for L=2 to 6 MagicClusters?
Thanks for your patience
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