Hesselink's research encompasses nano-photonics, ultra high density optical data storage, nonlinear optics, optical super-resolution, materials science, three-dimensional image processing and graphics, and Internet technologies.
With advantages of small size, cheapness, flexible shape, and some others [3], random lasers can be widely used in temperature sensing [4], document encoding, material marking, high-density optical data storage [5], tumor diagnosis [6, 7], liquid crystal display [8], integrated optics [3], liquid flow monitoring, and other areas [9].
Gu, M., Zhang, Q. & Lamon, S. Nanomaterials for optical data storage.
We hence applied Carbow to optical data storage and identification on microbeads.
Rakuljic, G. A., Leyva, V. & Yariv, A. Optical data storage by using orthogonal wavelength-multiplexed volume holograms.
Cumpston, B. H. et al. Two-photon polymerization initiators for three-dimensional optical data storage and microfabrication.
Chen, M., Rubin, K. A. & Barton, R. W. Compound materials for reversible, phase-change optical data storage.
Lohse, B. et al. Acridizinium-Substituted Dendrimers As a New Potential Rewritable Optical Data Storage Material for Blu-ray.
The G.E. team plans to present its research data and lab results at an optical data storage conference in Orlando next month.
Thusfar, the applications suggested for these fascinating phenomena have primarily involved some type of rotating disk based optical data storage.
Kalb, J., Spaepen, F. & Wuttig, M. Calorimetric measurements of phase transformations in thin films of amorphous Te alloys used for optical data storage.
