Abstract

Nanoscale focused ion beams (FIBs) represent one of the most useful tools in nanotechnology, enabling nanofabrication via milling and gas-assisted deposition, microscopy and microanalysis, and selective, spatially resolved doping of materials. Recently, a new type of FIB source has emerged, which uses ionization of laser cooled neutral atoms to produce the ion beam. The extremely cold temperatures attainable with laser cooling (in the range of 100 μK or below) result in a beam of ions with a very small transverse velocity distribution. This corresponds to a source with extremely high brightness that rivals or may even exceed the brightness of the industry standard Ga+ liquid metal ion source. In this review we discuss the context of ion beam technology in which these new ion sources can play a role, their principles of operation, and some examples of recent demonstrations. The field is relatively new, so only a few applications have been demonstrated, most notably low energy ion microscopy with Li ions. Nevertheless, a number of promising new approaches have been proposed and/or demonstrated, suggesting that a rapid evolution of this type of source is likely in the near future.

Highlights

  • Nanoscale focused ion beams (FIBs) represent one of the most useful tools in nanotechnology, enabling nanofabrication via milling and gas-assisted deposition, microscopy and microanalysis, and selective, spatially resolved doping of materials

  • Driven by the needs of nanotechnology, all of these sources have advanced to a stage of commercialization and are currently available in focused ion beam systems provided by a number of vendors

  • With Eqs. (11) and (15), knowledge of the emittance, normalized brightness, and/or total current of the source, and estimations of the aberrations expected in the ion optics to be used, it is possible to estimate the spot size and current that could potentially be obtained in a focused ion beam system

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Summary

APPLICATIONS OF FOCUSED ION BEAMS

The application of FIBs in nanotechnology has evolved into an extraordinarily broad and diverse discipline, and has been covered by a large number of reviews16–25 and books.26–30 For the purpose of the current review, we touch on a few of the more prominent applications in order to set the stage for ways in which the new sources discussed here can complement existing sources and provide enhanced performance in a number of instances.

Nanofabrication
Ion microscopy
Microanalysis
FOCUSED ION BEAM SOURCE PRINCIPLES
Emittance
Contributions to spot size
Brightness
CONVENTIONAL FIB SOURCES
Liquid metal ion source
Gas field ionization source
Inductively coupled plasma source
COLD-ATOM-BASED SOURCES
LASER COOLING AND TRAPPING
Laser cooling
Cold atom traps
Estimates of MOTIS performance
Pulsed operation
Continuous operation
VIII. MOTIS REALIZATIONS
Rubidium
Chromium
Lithium
Lithium ion microscopy
COLD ATOMIC BEAM SOURCES
Findings
SUMMARY AND OUTLOOK

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