We aim to apply atom optical techniques to iron to produce periodic magnetic nanostructures. Laser cooling has been observed experimentally, and calculations predict that a bright beam can be obtained with 200 µrad divergence. We expect to be able to laser focus this beam to feature sizes around 10 nm by the use of nanoscale mechanical beam masking and velocity selection via a supersonic source. In separate calculations, we have modelled surface diffusion of the atoms during deposition using a kinetic Monte Carlo approach taking into account the Ehrlich–Schwoebel barrier. These calculations successfully explain anomalous broadening of structures observed in similar experiments on chromium [Anderson et al., Phys. Rev. A 59 (1999) 2476]
editorial reviewedWe report on the first laser cooling of Iron atoms. Our laser cooling setup makes ...
Abstract We present a new method for nanoscale atom lithography. We propose the use of a supersonic ...
By using laser manipulation techniques, we have produced a cesium beam with sub-thermal velocity; at...
We aim to apply atom optical techniques to iron to produce periodic magnetic nanostructures. Laser c...
Atom lithography is a technique in which a light field is used to pattern an atomic beam. This patte...
Atom lithography is a technique to structure layers of atoms during deposition, using interactions o...
Lithography based on laser focusing of a beam of neutral iron atoms shows great promise for creating...
Direct-write atom lithography is a technique in which highly periodic nanostructures are directly de...
Direct write atom lithography is a technique in which nearly resonant light is used to pattern an at...
Laser focusing of Fe atoms offers the possibility of creating separate magnetic structures on a scal...
We study the role of surface diffusion in the fabrication of nanostructures by laser-focused (“cold”...
Contains fulltext : 57617.pdf (publisher's version ) (Open Access)We fabricate iro...
Contains fulltext : 18994_lasemaofa.pdf (publisher's version ) (Open Access)Fundam...
We report on the first laser cooling of Iron atoms. Our laser cooling setup makes use of 2 UV laser ...
Iron structures with dimensions comparable to the minimum domain size of 5nm may provide us with a n...
editorial reviewedWe report on the first laser cooling of Iron atoms. Our laser cooling setup makes ...
Abstract We present a new method for nanoscale atom lithography. We propose the use of a supersonic ...
By using laser manipulation techniques, we have produced a cesium beam with sub-thermal velocity; at...
We aim to apply atom optical techniques to iron to produce periodic magnetic nanostructures. Laser c...
Atom lithography is a technique in which a light field is used to pattern an atomic beam. This patte...
Atom lithography is a technique to structure layers of atoms during deposition, using interactions o...
Lithography based on laser focusing of a beam of neutral iron atoms shows great promise for creating...
Direct-write atom lithography is a technique in which highly periodic nanostructures are directly de...
Direct write atom lithography is a technique in which nearly resonant light is used to pattern an at...
Laser focusing of Fe atoms offers the possibility of creating separate magnetic structures on a scal...
We study the role of surface diffusion in the fabrication of nanostructures by laser-focused (“cold”...
Contains fulltext : 57617.pdf (publisher's version ) (Open Access)We fabricate iro...
Contains fulltext : 18994_lasemaofa.pdf (publisher's version ) (Open Access)Fundam...
We report on the first laser cooling of Iron atoms. Our laser cooling setup makes use of 2 UV laser ...
Iron structures with dimensions comparable to the minimum domain size of 5nm may provide us with a n...
editorial reviewedWe report on the first laser cooling of Iron atoms. Our laser cooling setup makes ...
Abstract We present a new method for nanoscale atom lithography. We propose the use of a supersonic ...
By using laser manipulation techniques, we have produced a cesium beam with sub-thermal velocity; at...