Kenneth Middleton scite author profile

Laser-assisted chemical vapor deposition (LCVD) was utilized to produce SnO 2 films from SnBr 4 plus air, O 2 or N 2 O. SnO 2 films were successfully generated using either 222 or 308 nm laser pulses but there was evidence for film contamination when using less than 60 mJ/ pulse laser energies at 222 nm. Films were characterized using ultraviolet absorption spectroscopy; the spectra of films with impurities resembled the spectrum of SnBr 4 . AFM images were obtained which indicated that this LCVD route produced small and fairly uniform SnO 2 grains which were 50-100 nm in size. Multiphoton ionization spectroscopy was used to verify that the dissociation of a film dopant precursor, copper(II) acetate, produced gasphase copper atoms under conditions similar to those used in film deposition experiments. The deposition of SnO 2 from SnBr 4 plus an oxidant was found to be more efficient than from di-nbutyl tin diacetate but films produced via this new LCVD route, including those doped with copper, were found to be much less sensitive in preliminary gas-sensing screening.

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Comparison of SnBr4 and di-n-butyl tin diacetate as laser-assisted chemical vapor deposition precursors for SnO2-based gas sensors

Hossenlopp

Lamelas

Middleton

et al. 1998

Appl. Organometal. Chem.

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Laser‐assisted chemical vapor deposition (LCVD) was utilized to produce SnO2 films from SnBr4 plus air, O2 or N2O. SnO2 films were successfully generated using either 222 or 308 nm laser pulses but there was evidence for film contamination when using less than 60 mJ/pulse laser energies at 222 nm. Films were characterized using ultraviolet absorption spectroscopy; the spectra of films with impurities resembled the spectrum of SnBr4. AFM images were obtained which indicated that this LCVD route produced small and fairly uniform SnO2 grains which were 50–100 nm in size. Multiphoton ionization spectroscopy was used to verify that the dissociation of a film dopant precursor, copper(II) acetate, produced gas‐phase copper atoms under conditions similar to those used in film deposition experiments. The deposition of SnO2 from SnBr4 plus an oxidant was found to be more efficient than from di‐n‐butyl tin diacetate but films produced via this new LCVD route, including those doped with copper, were found to be much less sensitive in preliminary gas‐sensing screening. © 1998 John Wiley & Sons, Ltd.

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Kenneth Middleton

Adolescent functioning as a consequence of recent parental divorce and the parent-adolescent relationship

Comparison of SnBr4 and di‐n‐butyl tin diacetate as laser‐assisted chemical vapor deposition precursors for SnO2‐based gas sensors

Comparison of SnBr4 and di-n-butyl tin diacetate as laser-assisted chemical vapor deposition precursors for SnO2-based gas sensors

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