6 mPa.s) is equal to the dynamic viscosity of octadecene at 303 K. The PL peak position of Si NPs is equal to 1.702 eV in octadecene at 303 K and is equal to 1.68 eV in squalane at 368 K. Therefore, there is a difference of 22 meV between the two PL peak positions which is very close to the shift given by the Varshni expression
on bulk Si (17.5 meV) in the same temperature range (from 303 down to 368 K). Hence, when corrected from the viscosity effect, the red shift that we observed (around −0.3 meV/K) with temperature is close to the one reported by different groups. Conclusion Si NPs Proteases inhibitor prepared by electrochemical etching of bulk Si have been functionalized with alkyl chains (octadecene) for dispersion in NPLs like lubricants for mechanical bearings. Their potential application as fluorescent nanosensors for temperature measurement in lubricated contact with EPZ015938 clinical trial optical access has been evaluated. The important variation of the fluorescence emission energy with temperature (−0.9 meV/K) allows simple temperature measurement in squalane. Nevertheless, we have shown that this variation is mainly due to energy
exchange between Si NPs promoted by viscosity reduction when the temperature is increased. For static condition in the fluid, this indirect temperature sensing via viscosity change is convenient, but in dynamic conditions of buy CBL0137 the mechanical contact, a more intrinsic measurement like PL lifetime [21] is needed. Authors’ information HH has obtained his Master’s degree in Physics and Materials in June 2011 at University of Poitiers (France).
Immune system In October 2011, he started his current Ph.D. project at Lyon Institute of Nanotechnologies. His main scientific interest focuses on synthesis, chemical functionalization, and optical characterization of silicon-based semiconductor nanostructures. SAA received his Master’s degree in Chemistry from Kiev National Taras Shevchenko University in 1998 and then his Ph.D. degree in Chemistry at the same university in 2003 for his work on the ‘Immobilization of organic acids on silica gel surface, thermochemical and catalytic properties of materials obtained’. Currently, SAA is working as an associate professor in the Chemistry Faculty of the same university. Since 2004, SAA has close scientific collaboration with INSA Lyon (France); he participated in European projects such as INTAS, IRSES, and LST. Fields of his research interests are as follows: surface chemistry of nanostructured materials (semiconductors, inorganic oxides), surface functionalization and characterization, and application of nanostructures in LDI mass spectrometry, sensors, and catalysis. GG received his Master’s degree in Solid State Physics from Claude Bernard University in Lyon (France) in 1970 and then his Ph.D.