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Analysis of Fe nanoparticles using XPS measurements under d.c. or pulsed‐voltage bias
Author(s) -
Suzer Sefik,
Baer Donald R.,
Engelhard Mark H.
Publication year - 2010
Publication title -
surface and interface analysis
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.52
H-Index - 90
eISSN - 1096-9918
pISSN - 0142-2421
DOI - 10.1002/sia.3260
Subject(s) - x ray photoelectron spectroscopy , nanoparticle , biasing , materials science , analytical chemistry (journal) , nanotechnology , voltage , chemistry , nuclear magnetic resonance , physics , electrical engineering , chromatography , engineering
The impact of solution exposure on the charging properties of oxide coatings on Fe metal‐core oxide–shell nanoparticles has been examined by sample biasing during XPS measurements. The Fe nanoparticles were suspended in relatively unreactive acetone and analyzed after particles containing solutions were deposited on SiO 2 /Si or Au substrates. The particle and substrate combinations were subjected to ± 10V d.c. or ± 5V a.c., biasing in the form of square wave (SQW) pulses. The samples experienced variable degrees of charging for which low‐energy electrons at ∼1 eV, 20 µA and low‐energy Ar + ions were used to minimize it. Application of d.c. bias and/or SQW pulses significantly influences the extent of charging, which is utilized to gather additional analytical information about the sample under investigation. This approach allows separation of otherwise overlapping peaks. Accordingly, the O1s peaks of the silicon oxide substrate, the iron oxide nanoparticles, and that of the casting solvent can be separated from each other. Similarly, the C1s peak belonging to the solvent can be separated from that of the adventitious carbon. The charging shifts of the iron nanoparticles are strongly influenced by the solvent to which the particles were exposed. Hence, acetone exhibited the largest shift, water the smallest, and methanol in between. Dynamical measurements performed by application of the voltage stress in the form of SQW pulses provides information about the time constants of the processes involved, which leads us to postulate that these charging properties we probe in these systems stem mainly from ionic movement(s). Copyright © 2010 John Wiley & Sons, Ltd.

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