Martin Sigrist scite author profile

The Plasma and Suprathermal Ion Composition (PLASTIC) investigation provides the in situ solar wind and low energy heliospheric ion measurements for the NASA Solar Terrestrial Relations Observatory Mission, which consists of two spacecraft (STEREO-A, STEREO-B). PLASTIC-A and PLASTIC-B are identical. Each PLASTIC is a timeof-flight/energy mass spectrometer designed to determine the elemental composition, ionic charge states, and bulk flow parameters of major solar wind ions in the mass range from hydrogen to iron. PLASTIC has nearly complete angular coverage in the ecliptic plane and an energy range from ∼0.3 to 80 keV/e, from which the distribution functions of suprathermal ions, including those ions created in pick-up and local shock acceleration processes, are also provided.

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Spatially Resolved Manipulation of Single Electrons in Quantum Dots Using a Scanned Probe

Pioda

et al. 2004

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The scanning metallic tip of a scanning force microscope was coupled capacitively to electrons confined in a lithographically defined gate-tunable quantum dot at a temperature of 300 mK. Single electrons were made to hop on or off the dot by moving the tip or by changing the tip bias voltage owing to the Coulomb-blockade effect. Spatial images of conductance resonances map the interaction potential between the tip and individual electronic quantum dot states. Under certain conditions this interaction is found to contain a tip-voltage induced and a tip-voltage-independent contribution.

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The Plasma and Suprathermal Ion Composition (PLASTIC) Investigation on the STEREO Observatories

Galvin

Kistler

Popecki

et al.

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Interference in a quantum dot molecule embedded in a ring interferometer

et al. 2007

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Measurement of the tip-induced potential in scanning gate experiments

et al. 2007

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We present a detailed experimental study on the electrostatic interaction between a quantum dot and the metallic tip of a scanning force microscope. Our method allowed us to quantitatively map the tip-induced potential and to determine the spatial dependence of the tip's lever arm with high resolution. We find that two parts of the tip-induced potential can be distinguished, one that depends on the voltage applied to the tip and one that is independent of this voltage. The first part is due to the metallic tip while we interpret the second part as the effect of a charged dielectric particle on the tip. In the measurements of the lever arm we find fine structure that depends on which quantum state we study. The results are discussed in view of scanning gate experiments where the tip is used as a movable gate to study nanostructures.

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Martin Sigrist

The Plasma and Suprathermal Ion Composition (PLASTIC) Investigation on the STEREO Observatories

Spatially Resolved Manipulation of Single Electrons in Quantum Dots Using a Scanned Probe

The Plasma and Suprathermal Ion Composition (PLASTIC) Investigation on the STEREO Observatories

Interference in a quantum dot molecule embedded in a ring interferometer

Measurement of the tip-induced potential in scanning gate experiments

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