Sami Franssila's 3D Laser Microfabrication: Principles and Applications PDF
By Sami Franssila
A radical advent to 3D laser microfabrication know-how, best readers from the basics and idea to its quite a few powerful purposes, comparable to the new release of tiny gadgets or third-dimensional constructions in the bulk of obvious materials.The ebook additionally provides new theoretical fabric on dielectric breakdown, permitting a greater knowing of the variations among optical harm on surfaces and contained in the bulk, in addition to a glance into the future.Chemists, physicists, fabrics scientists and engineers will locate this a invaluable resource of interdisciplinary wisdom within the box of laser optics and nanotechnology.
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Additional resources for 3D Laser Microfabrication: Principles and Applications
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This includes the relation between an axially-symmetric focused beam and the real 3D distribution of the absorbed energy density, electron density, temperature, and pressure, etc. Furthermore, we do not know how the transition to spherical symmetry at high intensity occurs. We do not know the real shape of the cavity, the exact phase state and the distribution in space of the laser-modified material, which will be important for the formation of a 3D photonic crystal (iii) On the basis of knowledge gained from existing experimental and theoretical studies we can predict semi-quantitatively (with an accuracy in the range 40–50%) the result of the laser–matter interaction at high intensity (~ 1014 W cm–2); the size of the cavity (not its shape); and the possible material changes (very approximate range for density and refraction index changes).
3D Laser Microfabrication: Principles and Applications by Sami Franssila