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Compound refractive lens

From Wikipedia, the free encyclopedia

A compound refractive lens (CRL) is a series of individual lenses arranged in a linear array in order to achieve focusing of X-rays in the energy range of 5–40 keV.[1][2][3][4][5] They are an alternative to the KB mirror.

For all materials the real part of the refractive index for X-rays is close to 1, hence a single conventional lens for X-rays has an extremely long focal length (for practical lens sizes). In addition, X-rays attenuate as they pass through a material so that conventional lenses for X-rays have long been considered impractical. The CRL gets its reasonably short focal length, on the order of meters, by using many lenses in series, hence reducing the curvatures of each lens to practical levels. Absorption in the lens is still a challenge, however, and lenses are usually made from low-atomic-number materials such as aluminium, beryllium, or lithium.

CRLs were first demonstrated in the mid-1990s by a group of scientists at the ESRF. They drilled holes in an aluminium block, and achieved focusing in two dimensions. For X-rays a concave lens focuses the X-rays because the index of refraction is slightly below unity. In a CRL of this type the walls between the cylindrical holes act as concave lenses for X-rays traveling perpendicular to the axis of the drilled cylinders. In contrast, for visible light the index of refraction is larger than unity and focusing is done with a convex lens.

Scientists associated with the ESRF synchrotron have done much of the CRL's subsequent development, notably the parabolic CRLs pioneered by the Aachen group under Lengeler. Their signature material is beryllium: a group at the Advanced Photon Source demonstrated the same lenses in lithium. These lenses have a direct counterpart in visible light.

The saw-tooth lens is a unique optical scheme suggested and demonstrated by Cederstrom.[6] It approximates a parabolic lens much as a numerical computation on a grid approximates a smooth line, with a series of prisms that each deflect the X-rays over a minute angle. Lenses of this type have been made from silicon, plastic, and lithium. To address the challenge with absorption in the lens, each prism in the saw-tooth lens can be exchanged for a column of smaller prisms, hence removing phase shifts of 2π that do not contribute to refraction but add absorption.[7] This scheme is similar to the approximation of a conventional parabolic lens by a zone plate. The relatively simple manufacturing of the saw-tooth refractive lens and the prism-array lens make them usable also outside of research and both have been suggested for applications in medical x-ray imaging.[8][9]

References

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  1. ^ Snigirev, A; Kohn, V; Snigireva, I; Souvorov, A; Lengeler, B (1998). "Focusing High-Energy X Rays by Compound Refractive Lenses". Applied Optics. 37 (4): 653–662. Bibcode:1998ApOpt..37..653S. doi:10.1364/AO.37.000653. PMID 18268637.
  2. ^ Snigirev, A; Filseth, B; Elleaume, P; Klocke, Th; Kohn, V; Lengeler, B; Snigireva, I; Souvorov, A; Tuemmler, J (1997). "Refractive lenses for high-energy x-ray focusing". Proc. SPIE. 3151: 164–170. Bibcode:1997SPIE.3151..164S. doi:10.1117/12.294496.
  3. ^ Smither, R. K.; Khounsary, A. M.; Xu, S. (1997). "Potential of a beryllium x-ray lens". Proc. SPIE. 3151: 150–163. Bibcode:1997SPIE.3151..150S. doi:10.1117/12.294474.
  4. ^ Young, K.; Khounsary, A.; Jansen, A.; Dufresne, E.; Nash, P. (2007). "Fabrication and Performance of a Lithium X-Ray Lens". AIP Conference Proceedings. 879: 989–993. Bibcode:2007AIPC..879..989Y. doi:10.1063/1.2436228.
  5. ^ Arndt Last. "Compound refractive X-ray optics". Retrieved 12 June 2018.
  6. ^ Cederström, Björn; Cahn, Robert; Danielsson, Mats; Lundqvist, Mats; Nygren, David (2000). "Focusing hard X-rays with old LP's". Nature. 404 (6781): 951. Bibcode:2000Natur.404..951C. doi:10.1038/35010190. PMID 10801113.
  7. ^ Cederström, Björn; Ribbing, Carolina; Lundqvist, Mats (2005). "Generalized prism-array lenses for hard x-rays". Journal of Synchrotron Radiation. 12 (Pt 3): 340–344. doi:10.1107/S0909049504034181. PMID 15840919.
  8. ^ Fredenberg, Erik; Cederström, Björn; Åslund, Magnus; Nillius, Peter; Danielsson, Mats (27 January 2009). "An efficient pre-object collimator based on an x-ray lens". Medical Physics. 36 (2): 626–633. arXiv:2101.07788. Bibcode:2009MedPh..36..626F. doi:10.1118/1.3062926. PMID 19292003.
  9. ^ Fredenberg, Erik; Cederström, Björn; Nillius, Peter; Ribbing, Carolina; Karlsson, Staffan; Danielsson, Mats (2009). "A low-absorption x-ray energy filter for small-scale applications". Optics Express. 17 (14): 11388–11398. Bibcode:2009OExpr..1711388F. doi:10.1364/OE.17.011388. PMID 19582053.
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