3 MV hypervelocity dust accelerator at the Colorado Center for Lunar Dust and Atmospheric Studies

Shu, Anthony; Collette, A.; Drake, K.; Grün, E.; Horányi, M.; Kempf, S.; Mocker, A.; Munsat, T.; Northway, Paige; Srama, R.; Sternovsky, Z.; Thomas, E.

doi:10.1063/1.4732820

Cited by 75 publications

(54 citation statements)

References 18 publications

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“…The measurements were carried out using the electrostatic dust accelerator at the University of Colorado (Shu et al, 2012). Briefly, an electrostatic field generated by U acc = 2.2 MV potential is used to accelerate micron-and submicron-sized charged dust particles to velocities of 1-100 km/s.…”

Section: Methodsmentioning

confidence: 99%

Magnetic Field Effect on Antenna Signals Induced by Dust Particle Impacts

et al. 2020

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The Radio and Plasma Wave Science instrument on Cassini has observed fewer than expected dust particle impacts during the mission's Grand Finale orbits. The relatively strong magnetic field in the close vicinity of the planet has been suggested to affect the intensity of the dust impact generated signals. A laboratory investigation is performed using dust particles accelerated to ≥20 km/s speed impacting onto a previously developed model of the spacecraft and the Radio and Plasma Wave Science antennas. The external magnetic field is generated by two sets of magnetic coils. The recorded antenna waveforms are decomposed into contributions from the electrons and ions of the dust impact generated plasma cloud. A good qualitative understanding of the waveforms is achieved by dividing the electron and ion population into two portions: one that is escaping from the spacecraft and another that is collected by the spacecraft. The experimental results show that the part of the signal corresponding to escaping electrons is affected by the magnetic field and that dust impact signals can be significantly reduced for spacecraft floating potentials close to zero.

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Section: Methodsmentioning

confidence: 99%

Magnetic Field Effect on Antenna Signals Induced by Dust Particle Impacts

et al. 2020

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“…Figure a shows the experimental arrangement, using the dust accelerator facility at the University of Colorado [ Shu et al , ]. Submicron‐sized iron projectiles are positively charged and ejected from a dust source, located at the high voltage terminal of a Pelletron electrostatic generator [ Herb , ].…”

Section: Methodsmentioning

confidence: 99%

“…Figure shows the speed‐mass distribution for all particles used in the scaling tests. The inverse relation between speed and mass is a characteristic of all electrostatic dust accelerators, related to the charging process [ Shu et al , ].…”

Section: Methodsmentioning

confidence: 99%

Micrometeoroid impact charge yield for common spacecraft materials

et al. 2014

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The impact ionization charge yield is experimentally measured from four common materials used in space and specifically on the two STEREO spacecraft (germanium-coated black Kapton, beryllium copper, multilayer insulation, and solar cells). Cosmic dust particle impacts on spacecraft have been detected by electric field and plasma and radio wave instruments. The accurate interpretation of these signals is complicated by many factors, including the details of the spacecraft antenna system, the local spacecraft plasma environment, and our understanding of the physics of the impact process. The most basic quantity, the amount of charge liberated upon impact, is generally considered poorly constrained and is suspected to depend on the target material. Here we show that for common materials used on spacecraft this variability is small for impacts around 10 km/s, and the impact charge yield can be approximated by 80 fC for a 1 pg projectile. At higher speeds (∼50 km/s), variation of up to a factor of 5 is observed. The measured yields in the 10-50 km/s range are compared to measurements and predictions from the literature and are found to be lower than predicted by at least a factor of 12 at 10 km/s and at least a factor of 1.7 at 50 km/s. Impact charge is also found to depend on angle of incidence; the data suggest a maximum at 45 • .

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“…The flexibility of single particle on-the-fly analysis allows the Aerosol Impact Spectrometer to function with a wide range of nanoparticle masses and charges from a given particle source. Additionally, the variable energy selection of the spectrometer allows a variety of particle sources to be implemented in addition to the demonstrated electrospray ionization, including liquid metal ion sources [54][55][56] and needle-charge dust sources [57,58]. The wide range of final energies achievable with the variable linear accelerator/decelerator will allow for a variety of scattering experiments to be performed to examine both hypo-and hypervelocity impact phenomena Submit your manuscript to a journal and benefi t from:…”

Section: Discussionmentioning

confidence: 99%

The aerosol impact spectrometer: a versatile platform for studying the velocity dependence of nanoparticle-surface impact phenomena

2017

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A new apparatus designed to accelerate/decelerate and study the surface impact phenomena of charged aerosols and nanoparticles over a wide range of mass-tocharge (m/z) ratios and final velocities is described. A nanoparticle ion source coupled with a linear electrostatic trap configured as an image charge detection (ICD) mass spectrometer allows determination of the mass-to-charge ratio and the absolute charge and mass of single nanoparticles. A nine-stage linear accelerator/ decelerator is used to fix the final velocity of the nanoparticles, and in the results reported here the coefficient of restitution for polystyrene latex spheres (PSLs) impacting on silicon is measured using ICD techniques. To enable this apparatus to study a wide range of m/z, the data acquisition system uses a transient digitizer interfaced to a field-programmable gate array module that allows real time calculation of m/z and determination of the pulse sequence for the linear accelerator/decelerator. Electrospray ionization of a colloidal suspension of PSL spheres of 510 and 990 nm has been used to demonstrate acceleration and deceleration of charged nanoparticles and the resolution of the apparatus. Measurements of the coefficient of restitution for PSLs on silicon over the range 10-400 m/s are consistent with previous studies.

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3 MV hypervelocity dust accelerator at the Colorado Center for Lunar Dust and Atmospheric Studies

Cited by 75 publications

References 18 publications

Magnetic Field Effect on Antenna Signals Induced by Dust Particle Impacts

Magnetic Field Effect on Antenna Signals Induced by Dust Particle Impacts

Micrometeoroid impact charge yield for common spacecraft materials

The aerosol impact spectrometer: a versatile platform for studying the velocity dependence of nanoparticle-surface impact phenomena

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