11,028 research outputs found
Process for purification of silicon
The purification of metallurgically pure silicon having a silicon content of more than 95% by weight is accomplished by leaching with an acidic solution which substantially does not attack silicon. A mechanical treatment leading to continuous particle size reduction of the granulated silicon to be purified is combined with the chemical purification step
Probing the Melting of a Two-dimensional Quantum Wigner Crystal via its Screening Efficiency
One of the most fundamental and yet elusive collective phases of an
interacting electron system is the quantum Wigner crystal (WC), an ordered
array of electrons expected to form when the electrons' Coulomb repulsion
energy eclipses their kinetic (Fermi) energy. In low-disorder, two-dimensional
(2D) electron systems, the quantum WC is known to be favored at very low
temperatures () and small Landau level filling factors (), near the
termination of the fractional quantum Hall states. This WC phase exhibits an
insulating behavior, reflecting its pinning by the small but finite disorder
potential. An experimental determination of a vs phase diagram for
the melting of the WC, however, has proved to be challenging. Here we use
capacitance measurements to probe the 2D WC through its effective screening as
a function of and . We find that, as expected, the screening
efficiency of the pinned WC is very poor at very low and improves at higher
once the WC melts. Surprisingly, however, rather than monotonically
changing with increasing , the screening efficiency shows a well-defined
maximum at a which is close to the previously-reported melting temperature
of the WC. Our experimental results suggest a new method to map out a vs
phase diagram of the magnetic-field-induced WC precisely.Comment: The formal version is published on Phys. Rev. Lett. 122, 116601
(2019
Interaction-induced Interlayer Charge Transfer in the Extreme Quantum Limit
An interacting bilayer electron system provides an extended platform to study
electron-electron interaction beyond single layers. We report here experiments
demonstrating that the layer densities of an asymmetric bilayer electron system
oscillate as a function of perpendicular magnetic field that quantizes the
energy levels. At intermediate fields, this interlayer charge transfer can be
well explained by the alignment of the Landau levels in the two layers. At the
highest fields where both layers reach the extreme quantum limit, however,
there is an anomalous, enhanced charge transfer to the majority layer.
Surprisingly, when the minority layer becomes extremely dilute, this charge
transfer slows down as the electrons in the minority layer condense into a
Wigner crystal. Furthermore, by examining the quantum capacitance of the dilute
layer at high fields, the screening induced by the composite fermions in an
adjacent layer is unveiled. The results highlight the influence of strong
interaction in interlayer charge transfer in the regime of very high fields and
low Landau level filling factors.Comment: Please see the formal version on PR
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