Open AccessHelium ion beam induced growth of hammerhead AFM probes
Author(s) -
Gaurav Nanda,
Emile van Veldhoven,
Diederik Maas,
Hamed Sadeghian,
Paul F. A. Alkemade
Publication year - 2015
Publication title -
journal of vacuum science and technology b nanotechnology and microelectronics materials processing measurement and phenomena
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.429
H-Index - 119
eISSN - 2166-2754
pISSN - 2166-2746
DOI - 10.1116/1.4936068
Subject(s) - nanoneedle , materials science , ion beam , nanolithography , beam (structure) , atomic force microscopy , focused ion beam , nanotechnology , optoelectronics , silicon , fabrication , optics , ion , nanostructure , chemistry , medicine , physics , alternative medicine , organic chemistry , pathology
The authors report the direct-write growth of hammerhead atomic force microscope(AFM) probes by He+beam induced deposition of platinum-carbon. In order to grow a thin nanoneedle on top of a conventional AFM probe, the authors move a focused He+beam during exposure to a PtC precursor gas. In the final growth stage, a perpendicular movement of the beam results in the required three-dimensional (hammerhead) shape. The diameter of the needle depends on the ion beam dose, beam dwell time, and speed of the beam movement. A nanoneedle radius below 10?nm and a hammerhead smaller than 35?nm have been achieved. This fabrication process is robust and enables precise control over the three-dimensions of the hammerhead AFM probe. Finally, the authors test the capabilities of the fabricated AFM probes for two-dimensional metrology of sidewall angles and line-edge roughness of trenches and shark-fins in silicon.QN/Quantum NanoscienceApplied Science
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