Browsing by Author "Kamada, M."

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  • Quantum degeneracy in mesoscopic matter : Casimir effect and Bose-Einstein condensation
    (2024-06-01) Todoshchenko, I.; Kamada, M.; Kaikkonen, J. P.; Liao, Y.; Savin, A.; Kauppinen, E.; Sergeicheva, E.; Hakonen, P. J.
     A1 Alkuperäisartikkeli tieteellisessä aikakauslehdessä
    The ground-state phonon pressure is an analog to the famous Casimir pressure of vacuum produced by zero-point photons. The acoustic Casimir forces are, however, many orders of magnitude weaker than the electromagnetic Casimir forces, as the typical speed of sound is 100 000 times smaller than the speed of light. Because of its weakness, zero-point acoustic Casimir pressure was never observed, although the pressure of artificially introduced sound noise on a narrow aperture has been reported. However, the magnitude of Casimir pressure increases as 1/L3 with the decrease of the sample size L, and reaches piconewtons in the submicron scales. We demonstrate and measure the acoustic Casimir pressure induced by zero-point phonons in solid helium adsorbed on a carbon nanotube. We have also observed Casimir-like "pushing out"thermal phonons with the decreasing temperature or the length. We also show that all thermodynamic quantities are size dependent, and therefore in the mesoscopic range L≲h c/(kBT) quadruple points are possible on the phase diagram where four different phases coexist. Due to the smallness of solid helium sample, temperature of Bose-Einstein condensation (BEC) of vacancies is relatively high, 10-100mK. This allowed us to experimentally discover the BEC in a system of zero-point vacancies, predicted more than 50 years ago.
  • Topologically-imposed vacancies and mobile solid 3He on carbon nanotube
    (2022-10-05) Todoshchenko, I.; Kamada, M.; Kaikkonen, J. P.; Liao, Y.; Savin, A.; Will, M.; Sergeicheva, E.; Abhilash, T. S.; Kauppinen, E.; Hakonen, P. J.
     A1 Alkuperäisartikkeli tieteellisessä aikakauslehdessä
    Low dimensional fermionic quantum systems are exceptionally interesting because they reveal distinctive physical phenomena, including among others, topologically protected excitations, edge states, frustration, and fractionalization. Our aim was to confine 3He on a suspended carbon nanotube to form 2-dimensional Fermi-system. Here we report our measurements of the mechanical resonance of the nanotube with adsorbed sub-monolayer down to 10 mK. At intermediate coverages we have observed the famous 1/3 commensurate solid. However, at larger monolayer densities we have observed a quantum phase transition from 1/3 solid to an unknown, soft, and mobile solid phase. We interpret this mobile solid phase as a bosonic commensurate crystal consisting of helium dimers with topologically-induced zero-point vacancies which are delocalized at low temperatures. We thus demonstrate that 3He on a nanotube merges both fermionic and bosonic phenomena, with a quantum phase transition between fermionic solid 1/3 phase and the observed bosonic dimer solid.