Electrostatic analyzer

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An electrostatic analyzer or ESA is an instrument used in ion optics that employs an electric field to allow the passage of only those ions or electrons that have a given specific energy. It usually also focuses these particles (concentrates them) into a smaller area. ESAs are typically used as components of space instrumentation, to limit the scanning (sensing) energy range and, thereby also, the range of particles targeted for detection and scientific measurement. The closest analogue in photon optics is a filter.

Radial cylindrical analyzer

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Electrostatic analyzers are designed in different configurations. A simple version is a radial cylindrical analyzer, which consists of two curved parallel plates at different potentials. Ions or electrons enter the analyzer at one end and either pass through the other end or collide with the walls of the analyzer, depending on their initial energy. In these types of analyzers, only the radial component of the velocity of a charged particle is changed by an ESA since the potential on the plates only varies in the radial direction if one considers the geometry in cylindrical coordinates. Poisson's Equation can be then used to calculate the magnitude of the electric field pointing radially inwards. The resultant inward-pointing force generated by this electric field will cause the particles' trajectories to curve in a uniform circular motion. Depending on initial energy (velocity), only certain particles will therefore have the "correct" motion to exit the analyzer by tracing its physical structure, while others will collide into the walls of the instrument. In addition to the energy, the angle of entry will also affect the particles' time-of-flight through the analyzer as well as exit angle. In practice, the plates are usually oppositely charged and at very high potentials. Also, the inner surface of the analyzer, usually made of aluminum for space missions, is sometimes plated with black chrome or even Ebonol C to absorb stray light, instead of allowing it to bounce its way through.

Face-field cylindrical and conical electrostatic energy analyzers

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The well-known class of cylindrical face-field energy analyzers and a more recently developed type of face-field conical electrostatic energy analyzers are very useful instruments with very wide area of applications. These instruments can achieve very high energy resolution combined with large acceptance aperture, what is very important for measurements of in-space plasma flows.[1][2] This new class of analyzers can be used in a variety of applications for studying objects with different forms and sizes,[3] and for analysis of remote objects in the exploration of nanomaterials within a set of different methods.[4][5]

ESAs are usually designed and analyzed using an off-the-shelf ion-optics simulation-software package which includes the capability of performing Monte Carlo simulations on known test particles, thus providing the designer a better understanding of the response characteristics of the analyzer itself.

Use in space instrumentation

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Examples of space instruments or missions using Electrostatic Analyzers:

See also

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References

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  1. ^ Ilyin, A. M. (2003). "New class of electrostatic energy analyzers with a cylindrical face-field". Nuclear Instruments and Methods in Physics Research Section A. 500 (1–3): 62–67. Bibcode:2003NIMPA.500...62I. doi:10.1016/S0168-9002(03)00334-6.
  2. ^ Ilyin, A. M.; Ilyina, I. A. (2005). "New electrostatic energy analysers with a bounded cylindrical field". Measurement Science and Technology. 16 (9): 1798–1801. Bibcode:2005MeScT..16.1798I. doi:10.1088/0957-0233/16/9/012. ISSN 0957-0233. S2CID 121955696.
  3. ^ Ilyin, A. M. and I. A. Ilyina (2007). "An electrostatic face-field energy analyzer for space and plasma measurements". Measurement Science and Technology. 18 (3): 724–726. Bibcode:2007MeScT..18..724I. doi:10.1088/0957-0233/18/3/023. S2CID 121520374.
  4. ^ Ilyin, A. M.; N. R. Guseinov; M. A. Tulegenova (2022). "Conical Face-Field electrostatic energy analyzers for investigating nanomaterials". J. Electr. Spectr. Relat. Phenom. 257.
  5. ^ Ilyin, A. M.; "Computer Simulation of radiation defects in graphene and relative structures".In: "Graphene Simulation" Ed. J.R.Gong, "InTech"(2011) 39
  6. ^ Barabash, S.; Lundin, R.; Andersson, H.; Brinkfeldt, K.; Grigoriev, A.; Gunell, H.; Holmström, M.; Yamauchi, M.; Asamura, K.; Bochsler, P.; Wurz, P.; Cerulli-Irelli, R.; Mura, A.; Milillo, A.; Maggi, M.; Orsini, S.; Coates, A. J.; Linder, D. R.; Kataria, D. O.; Curtis, C. C.; Hsieh, K. C.; Sandel, B. R.; Frahm, R. A.; Sharber, J. R.; Winningham, J. D.; Grande, M.; Kallio, E.; Koskinen, H.; Riihelä, P.; et al. (2007). "The Analyzer of Space Plasmas and Energetic Atoms (ASPERA-3) for the Mars Express Mission". Space Science Reviews. 126 (1–4): 113–164. doi:10.1007/s11214-006-9124-8. S2CID 189767397.
  7. ^ "Orbiter Instruments". sci.esa.int. Retrieved 2019-06-26.