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8/3/2019 Eugene B. Gordon- Matrix Isolation by Solid Helium
1/1
Matrix Isolation by Solid Helium
Eugene B. Gordon
Russian Academy of Science
Institute of Chemical Physics Problems, Quantum Systems Laboratory
Chernogolovka, 142432 Moscow region, Russia.
Helium is the most inert chemical element and that is the motive to put the spectroscopic objects into low-perturbed
helium matrix. Meanwhile the extreme weakness of interatomic interaction manifesting itself in extraordinary flexibility of
solid and liquid helium causes the noticeable perturbation of the matrix by an embedded impurity itself. Besides its
demonstration in the impurities spectra such an effect should be detectible by changes in the specific for helium quantum
effects such as delocalization and superfluidity.
There are a few of elegant experimental approaches to the impurity introduction into condensed helium. Very popular is
the technique of impurity capture to cold liquid helium droplets [1]; the intriguing results have been obtained by laser
ablation from the target placed inside liquid and, especially, solid helium [2]. Here we will be mainly concentrated on the
method based on condensation of gas helium jet contained the small admixture of particles under study. Its obvious
advantages are the possibilities of large impurity densities achievement and of changing both temperature and pressure; that
allows revealing the effect of impurities affecting the quantum matrix.This approach meets evident difficulty: every hot (300K) helium atom releases under its condensation the energy of
450K whereas every evaporated atom takes away only 7K. It means the helium outflow should be 65 times stronger than the
inflow and thus no flow should exist in one-dimensional case. The solution found in 1974 was to separate the flows in a
space: originated from small orifice the pointed gas He jet carried the impurity to the surface of superfluid helium cooled by
its evaporation, supersonic jet velocity protected gas from cooling and the admixture from coalescence [3]. Recently the
technique has been modified by physical separation the inflow and outflow, the last simply cooled down the experimental
cell by thermoconductivity through its wall [4]. The absence of counterflow resulted in significant enhance of probability for
impurity to be captured inside of liquid He.
Briefly the effect of He surrounding on electronic transitions in atoms can be demonstrated by example of the forbidden2D
4S transition in nitrogen atoms. On one hand, helium practically doesnt quench the excitation (the radiative time is as
long as in a gas, t = 104
s) but, on the other hand, the atomic line transforms to broad, 50 cm-1, band. Moreover ESR study
shown the absence of N atoms mutual recombination in a sediment formed in superfluid helium. That led us to the alluring
idea of Impurity-Helium Solid the metastable substance consisted of frozen together localized helium clusters [5]. However,
in spite of many efforts there have not yet been unambiguous proofs of its real existence.
That challenge, as well as the problems of superfluidity fingerprints in rotation structure of IR spectra for molecules
isolated in liquid4He and of strong difference in magnetic relaxation times for alkali atoms isolated in bcc and hcpphases of
solid He, stimulated us to develop the technique for impurity condensation directly in solid helium. It consists in injecting
high pressure He gas mixed with an impurity on the top surface of liquid-solid interface, with the solid continuously
moving downwards by pumping at the bottom of the cell; the sedimentation occurs through the thin (2 mm) upper layer of
liquid helium. We achieved a guest- particle density of 31019
per cm3
and a doped crystal growth rate of 0.05 mm/s.
The results of CARS study of small deuterium clusters isolated by SHe have shown that the effect of large
predominance of Q1(1) transition over Q2(0) one expressed in CARS even more than in the common Raman scattering. The
significant size effect has been revealed there when the size of cluster became to be close to scattered light wavelength [6].
The preliminary results of IR spectroscopy of simple molecules embedded into SHe will be reported, the special
attention will be paid to temperature and pressure dependences and to their transformation under the doped solid temporarymelting.
1. S.Goyal, D.L.Schutt, G.Scoles, PRL, 69, 933(1992); J.P.Toennies, A.F.Vilesov, Annu. Rev. Phys.
Chem., 49, 1 (1998)
2. S.I. Kanorsky, A. Weis, Adv. Atomic, Molecular & Optical Physics, 38, 87 (1987); K.Ishikawa,
A.Hatakeyama, K.Gosyono-o, et al., Phys.Rev. B56(2),780 (1997)
3. E.B. Gordon, L.P. Mezhov-Deglin, O.F. Pugachev, JETF Lett. 19, 63 (1973)
4. R.E.Boltnev, G.Frossati, E.B.Gordon, et al., JLTP 127(5/6),247 (2002)
5. E.B.Gordon, V.V.Khmelenko, A.A.Pelmenev, et al., CPL 155, 301 (1989)
6. E.B.Gordon, G.Frossati, A.Usenko, et al, Physica B (accepted)