Sung Ho Kim, Oun-Ho Park, et al.
Small
The tremendous variety of nanotechnology experiments and tools to fabricate and characterize ever-smaller structures down to molecular or even atomic scales leads to stringent demands for appropriate, so-called "silent", premises that allow such susceptible experiments to be conducted. Reducing dimensions means smaller absolute optical and electrical signal levels, and consequently reduced signal-to-noise ratios. Hence, in addition to short-range disturbances inside the laboratory, remote long-range noise sources have to be considered for next-generation laboratories that aim at screening the disturbances and keeping the remaining values at utmost constancy. We present a novel laboratory concept that addresses simultaneously all the disturbances relevant for nanotechnology, namely, vibrations, electro-magnetic fields, temperature, humidity, and sound. Particular attention was paid to tackling the mutual derogation of the various measures to enable unprecedented performance of the novel research platform. © 2013 The Royal Society of Chemistry.
Sung Ho Kim, Oun-Ho Park, et al.
Small
Biancun Xie, Madhavan Swaminathan, et al.
EMC 2011
J.A. Barker, D. Henderson, et al.
Molecular Physics
A. Gupta, R. Gross, et al.
SPIE Advances in Semiconductors and Superconductors 1990