nanoparticle characterization introduction: dls
TRANSCRIPT
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© 2021 HORIBA, Ltd. All rights reserved.
Jeffrey Bodycomb, Ph.D.
Nanoparticle Characterization Introduction:
DLS, Diffraction, and NTA
Feb. 17, 2021
HORIBA Scientific
Particle Characterization
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Outline
Overview of Techniques
• Laser Diffraction
• Dynamic Light Scattering
• Nanoparticle Tracking Analysis and Multiple Lasers
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Laser Diffraction
• Converts scattered light
to particle size distribution
• Quick, repeatable
• Powders, suspensions
• Most common technique
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Diffraction effects arise due
to scattering from various
points in the particle (and,
in the large particle limit
only the edges)
Incoming light
Path Length Difference
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Interpreting Scattering Data
• Scattering data typically cannot
be inverted to find particle shape.
• We use optical models to
interpret data and understand our
experiments.
• Modern systems use particle
refractive index in a 3-D
calculation (Mie Theory) that
includes behavior of light inside of
particles.
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Fine particles: silica and latex
30 nm silica 40 nm latex
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Finding large particle impurities
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Instrument to instrument variation
4 instruments
(real sample)
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Particles
Backscatter (173°)
(High conc.)
90° for size and MW, A2
Laser PD
For T%532nm, 10mWAttenuator
Particles moving due to
Brownian motion
DLS (Dynamic Light Scattering)
Use scattering as a function of
time to determine size and size
distribution
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Particles in suspension undergo
Brownian motion (random thermal motion).
Brownian Motion
Random
Related to Size
Related to viscosity
Related to temperature
Brownian Motion
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Hydrodynamic Diameter
m
Bh
DT
TkD
)(3
Dm diffusion coefficient
Dh hydrodynamic diameter
viscosity
kB Boltzman’s constant
Then a miracle occurs …
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What is Hydrodynamic Size?
DLS gives the diameter of a sphere that moves (diffuses)
the same way as your sample.
Dh Dh
Dh
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Lab to Lab comparison
Colloidal Silica
Mean determined
Z-average size
(nm)
COV
(%)
Dynamic Light
Scattering with SZ-100,
laboratory 134.4 0.7
Dynamic Light
Scattering with SZ-100,
laboratory 234.6 0.3
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Effect of salt on measured size of silica
• Note that when we
suppress effect of
charges by adding
salt, the effect of
concentration is
suppressed.
• Concentration
effects are due to
changes in particle
motion, not just
multiple scattering.
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Nanoparticle Tracking (NTA)
microscope
+ camera
light sheet
scattered light
light sheet thickness
investigated volumeParticle by particle gives you:
• Detailed Distribution
• Particle Concentration light source
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100M X
Scattered
Light
Intensity
450 nm laser on polystyrene beads
Diameter [nm]
Angula
r scatt
ering c
oeffic
ient [1
/m]
10 1000100
1E-13
1E-23
Problem: Intensity vs size
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100M X
Scattered
Light
Intensity
450 nm laser on polystyrene beads
Diameter [nm]
Angula
r scatt
ering c
oeffic
ient [1
/m]
10 1000100
1E-13
1E-23
Solution: Intensity vs size
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Why three colors?
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Silica Particles by NTA
Number, not
volume based
distribution.
Particle
concentration!
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Key benefits of ViewSizer
• Individual particle method, not ensemble
average
• Accurate PSD for polydisperse samples
• Concentration measured, not estimated
• Absolute method (no calibration needed)
• Particle visualization
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Closing Comparison
Issue Laser
Diffraction
DLS Multi-laser
nanoparticle
tracking
Large (>1 micron) particles in sample
that need to be analyzed++ -- -
Small quantity of sample - + +
Smallest particles (<10~50 nm) - ++ -
Speed ++ + -
Nanoparticle Distribution - - +
Analyze only tagged particles -- -- +
Nanoparticle Concentration -- -- +
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