Title of article
Production of Nanometer-Sized Metal Oxide Particles by Gas Phase Reaction in a Free Jet. II: Particle Size and Neck Formation--Comparison with theory
Author/Authors
Windeler، نويسنده , , Robert S.; Lehtinen، نويسنده , , Kari E. J.; Friedlander، نويسنده , , Sheldon K، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 1997
Pages
15
From page
191
To page
205
Abstract
Experimental measurements of nanosized primary particle diameters
were compared with calculated values based on a collision--coalescence model. The
method of analysis permits calculation of the primary particle size when growth is
collision limited (individual particles colliding), coalescence limited (primary particles
coalescing in agglomerates), or in a transition regime (particles coalescing
about as fast as they collide). Calculated particle sizes compared well with experimental
measurements. Particle characteristics were studied along the jet axis for the
following conditions: exit velocity = 27.8 mIs, volume loading = 3.2 X 10 -1, Harne
gas How rate = 33 I/min. The growth of niobium oxide particles (largest diffusion
coefficient) was collision limited, yielding particles that are large and nonagglomerated.
The growth of titania particles (mid-range diffusion coefficient) occurred in
the collision limited and coalescence limited regimes to form mid-sized particles in
agglomerates. The growth of alumina particles (lowest diffusion coefficient> was
coalescence limited forming small, oblong particles necked together in large agglomerates.
The extent of necking between particles can be estimated from the
collision and coalescence times along the jet axis. When the coalescence time
rapidly exceeds the collision time, subsequent collisions form agglomerates which
are loosely held together. When the coalescence time slowly becomes longer than
the collision time, strong necks form between the particles
Journal title
Aerosol Science and Technology
Serial Year
1997
Journal title
Aerosol Science and Technology
Record number
430399
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