Micro piv measurements for hydrodynamic characterizations of microfluidic flows

Micro-PIV measurements for
hydrodynamic
characterizations of
Microfluidic flows
By
Sadiq Rahim E
S7
DOI,CUSAT

The application presented here is based on a non-invasive
method for velocity measurements in micro channels.
A micro PIV measurement system is used to obtain
velocity profile distributions in primary flow domain and in
vortex zone.
Experimental data is compared to data from numerical
simulations.
If both data are consistent to each other, it gives
information about vortical structures.

Abbreviations
PIV : PARTICLE IMAGE VELOCIMETRY
CCD : CHARGE COUPLED DEVICE
Nd-YAG : NEODYMIUM-doped YITTRIUM
ALUMINIUM GARNET
Re : REYNOLDS NUMBER
LCD : LIQUID CRYSTAL DISPLAY
NA : NUMERICAL APERATURE

INTRODUCTION
Microfluidics is an emerging field with wide range of
applications in tissue engineering, bioassays or
chemical synthesis and single cell analysis drug
Discovery.
used because in all the above applications
characterization of microfluidic flow is important.
Microfluidic devices are used in applications ranging
from biology to nanotechnology and manufacturing.

quantitative method that can be used to characterize
the performance of such microfluidic systems with
spatial resolutions better than one micron.
The resolution of this technique ranges from 10^−4 m
to 10^ −7 m.
Flow-tracing particles, either artificially added or
naturally occurring, are used to make the motion of the
fluid observable.
Two or more images of the moving particles are
captured and analysed using spatial correlation
methods to infer the fluid’s velocity field from the
particle motion.

This measurement technique borrows from the
macroscopic particle image velocimetry (PIV) method.
the hydrodynamics in a micro bifurcation where
vortices are developed is investigated.
Newtonian flows are studied in micro channels with
aspect ratios
AR = h/w=1
where h=viscous stress
w=strain rate
fabricated in cyclofelin copolymer (COC) –
a transparent material

The study emphasizes the evolution of vortexes in the
vicinity of the Y- bifurcation with the increase of flow
rate.
Fig.1.1 Optical microscope image

DESCRIPTION
1. PARTICLE IMAGE VELOCIMETRY
• optical method of flow visualization.
• used to obtain instantaneous velocity
and properties of fluids.

PIV apparatus consists of
• camera (digital camera with CCD chips).
• Strobe or laser (to limit the physical region of
illumination).
• Synchronizer (external trigger for control of camera
and laser).

The particles should be small enough so that response
time of the particles to the motion of the fluid is
reasonably short to accurately follow the flow, yet
large enough to scatter a significant quantity of the
incident laser light.
The particles are typically of a diameter in the order of
10 to 100 micro meters.
In a model where particles are modelled as spherical
(microspheres) at a very low Reynolds number, the
ability of the particles to follow the fluid's flow is
inversely proportional to difference in density between
the particles and the fluid, and also inversely
proportional to the square of their diameter.

The scattered light from the particles is dominated by
Mie scattering and so is also proportional to the
square of the particles diameters.
Thus the particle size needs to be balanced to scatter
enough light to accurately visualize all particles within
the laser sheet plane, but small enough to accurately
follow the flow.

2. MICRO CHANNELS
channels whose dimensions are less than 1 millimetre
and greater than 1 micron.
Fabricated from glass, polymers, silicon, metals using
processes including surface micromachining, bulk
micromachining, moulding, embossing, and
conventional machining with micro cutters.
used to transport biological materials such as proteins,
DNA, cells, and embryos or to transport chemical
samples and analytes.

sample is taken on-board the chip through a port and
moved through the micro channels by pressure to
various sites where it is mixed with analyte and
moved to a different site where the output is read.

3.MICROFLUIDICS
Field intersecting engineering, physics, chemistry,
biochemistry, nanotechnology, and biotechnology,
with practical applications to the design of systems in
which small volumes of fluids will be handled.
Micro means one of the following features:
• small volumes (µL, nL, pL, fL)
• small size
• Low energy consumption.

The behaviour of fluids at the micro scale can
differ from 'microfluidic' behaviour in that factors
such as surface tension, energy dissipation, and
fluidic resistance start to dominate the system.
Microfluidics studies how these behaviours
change, and how they can be worked around, or
exploited for new uses .
At small scales the Reynolds number can become
very low. A key consequence of this is that fluids
do not necessarily mix in the traditional sense, as
flow becomes laminar rather than turbulent
molecular transport between them must often be
through diffusion.

These technologies are based on the manipulation of
continuous liquid flow through micro fabricated
channels.
Continuous-flow microfluidic operation is the
mainstream approach because it is easy to implement
and less sensitive to protein fouling problems.
Closed channel systems are inherently difficult to
integrate and scale because the parameters that govern
flow field vary along the flow path making the fluid flow
at any one location dependent on the properties of the
entire system.

3.REYNOLD’S NUMBER
The Reynolds number (Re) is a dimensionless quantity
that is used to help predict similar flow patterns in
different fluid flow situations.
The Reynolds number is defined as the ratio of inertial
forces to viscous forces and consequently quantifies
the relative importance of these two types of forces
for given flow conditions.

The character of flow in depends on four variables:
• fluid density
• fluid viscosity
• Pipe diameter
• average velocity of flow
Osborne Reynolds was the first to demonstrate that
laminar or turbulent flow can be predicted if the
magnitude of a dimensionless number, now called the
Reynolds number, is known.

The Reynolds number is defined as the ratio of inertial
forces to viscous forces and consequently quantifies
the relative importance of these two types of forces for
given flow conditions.
Where
v - mean velocity of the object relative to the fluid
L - characteristic linear dimension
µ-the kinematic viscosity
ꭍ -is the density of the fluid

4.TYPES OF FLOWS
• Turbulence flow
• Laminar flow
Turbulence flow:
characterized by recirculation, eddies, and apparent
randomness.
Turbulent flows are unsteady by definition. A turbulent
flow can, however, be statistically stationary.
In turbulent flow, unsteady vortices appear on many scales
and interact with each other

Laminar flow
Flow in which turbulence is not exhibited is called
laminar.
occurs when a fluid flows in parallel layers, with no
disruption between the layers.
The fluid tends to flow without lateral mixing, and
adjacent layers slide past one another.

Steady-state flow refers to the condition where the fluid
properties at a point in the system do not change over
time. Otherwise, flow is called unsteady.
5. MICROFLUIDIC DEVICES
Microfluidic devices were composed of silicon or glass and
were fabricated using micromachining techniques
borrowed from the semiconductor industry.
Glass devices are commonly used in microfluidics due to
the straightforward and fabrication techniques, as well as
the beneficial optical properties, surface stability, and
solvent compatibility of glass.

APPLICATIONS
1.TISSUE ENGINEERING

Tissue engineering is the use of a combination of
cells, engineering and materials methods, and
suitable biochemical and physico-chemical factors to
improve or replace biological functions.
tissue engineering is closely associated with
applications that repair or replace portions of or
whole tissues (i.e., bone, cartilage, blood vessels,
bladder, skin, muscle etc.).
Tissue engineering utilizes living cells as engineering
materials. Example is using living fibroblasts in skin
replacement and cartilage repaired with living
chondrocytes.

2.SINGLE CELL ANALYSIS
Single cell analysis helps us to:
Unlock the mystery in gene expression profiles
between individual cells.
Avoid the mistake of taking averages of entire cell
populations.
Discover previously undetected subpopulations and
unveil new regulatory path.

3.DRUG DISCOVERY
Drug discovery is the process by which new candidate
medications are discovered.
Modern drug discovery involves the identification of
screening hits, medicinal chemistry and optimization of
those hits to increase the affinity, selectivity (to reduce
the potential of side effects), potency, metabolic
stability and oral bioavailability. Once a compound that
fulfils all of these requirements has been identified, it
will begin the process of drug development prior to
clinical trials.

4.BIOASSAYS
BIOASSAYS is a type of scientific experiment. A
bioassay involves the use of live animal or plant (in
vivo) or tissue or cell (in vitro) to determine the
biological activity of a substance, such as a hormone
or drug.
conducted to measure the effects of a substance on
a living organism and are essential in the
development of new drugs and in monitoring
environmental pollutants.

Procedure by which the potency or the nature of a
substance is estimated by studying its effects on
living matter.
A bioassay can also be used to determine the
concentration of a particular constitution of a
mixture that may cause harmful effects on
organisms or the environment.
Two types
• qualitative
• Quantitative

Qualitative bioassays are used for assessing the
physical effects of a substance that may not be
quantified, such as seeds fail to germinate or
develop abnormally deformity.
Quantitative bioassays involve estimation of the
concentration or potency of a substance by
measurement of the biological response that it
produces.

5.CHEMICAL SYNTHESIS
Chemical synthesis is a purposeful execution of
chemical reactions to obtain a product, or several
products.
This happens by physical and chemical manipulations
usually involving one or more reactions.
It is the construction of complex chemical compounds
from simpler ones.

A chemical synthesis begins by selection of
compounds that are known as reactants. Various
reaction types can be applied to these to synthesize
the product, or an intermediate product. This requires
mixing the compounds in a reaction vessel such as a
chemical reactor or a simple round bottom flask.
Many reactions require some form of work-up
procedure before the final product is isolated. The
amount of product in a chemical synthesis is the
reaction yield.

Chemists synthesize chemical compounds that occur
in nature in order to gain a better understanding of
their structures.
Synthesis also enables chemists to produce
compounds that do not form naturally for research
purposes.

EXPERIMENTAL METHODOLOGY
The shape and the aspect ratio of the geometry were
chosen to highlight the role on vortex formation and its
manifestation.
We choose the Y-bifurcation with a close branch and
aspect ratio one a flow configuration with potential to
create vortices even at low Re.

Y-bifurcation
A micro-PIV measurement system is used to
obtain velocity profile distributions in the main
flow domains and in the vortex area.

The system can also be used to identify the vortex
centre, stagnation points, and the separation line
between the main flow and the secondary one.
The experimental data is compared with numerical
simulations performed with commercial code
FLUENT in 3D representation of the flow domains.
Quantitative representation of
the flow
field obtained with the
micro-PIV measuring
system.

The experimental methods used are based on
(i) microscopic flow visualization – for a quantitative
representation of the secondary flows
(ii) micro-PIV measurements – for quantitative
measurements of the velocity profiles in a primary
flow domain, and for vortex identification.

Schematic representation of the micro-PIV
measuring system

The important components are
1) INVERTED MICROSCOPE
2) DICHROIC MIRROR
3) CHARGE COUPLED DEVICE (CCD)
4) C-MOUNT
5) Nd: YAG LASER
6) STREAK IMAGING TECHNIQUE
7) EXPERIMENTAL INFERENCE

INVERTED MICROSCOPE
An inverted microscope is a
microscope with its light source
and condenser on the top, above
the stage pointing down, while
the objectives and turret are
below the stage pointing up.

The stage of an inverted microscope is usually
fixed, and focus is adjusted by moving the objective
lens along a vertical axis to bring it closer to or
further from the specimen
The focus mechanism typically has a dual
concentric knob for coarse and fine adjustment.
Depending on the size of the microscope, four to
six objective lenses of different magnifications may
be fitted to a rotating turret known as a nosepiece.
Inverted microscopes are useful for observing
living cells or organisms at the bottom of a large
container.

DICHROIC MIRROR
A dichroic mirror is a
mirror with
significantly different
reflection or
transmission
properties at two
different wavelengths.
Dichroic mirrors are required for separating or
combining laser beams with different wavelengths.

As a dichroic mirror has to be transparent for at least
one wavelength of interest, the quality of the substrate
material and possible reflections from the back side need
to be considered.
An antireflection coating on the backside can help to
reduce such a reflection, and a slight wedge form of the
substrate can often eliminate the effects of residual
reflection.
Dichroic filters are used as beam splitters to direct
illumination of an excitation frequency toward the
sample and then at an analyser to reject that same
excitation frequency but pass a particular emission
frequency.

CHARGE COUPLED DEVICE (CCD)
Charge-coupled device (CCD) is
a device for the movement of
electrical charge, usually from
within the device to an area
where the charge can be
manipulated, for example
conversion into a digital value.
This is achieved by "shifting" the signals between
stages within the device one at a time. CCDs move
charge between capacitive bins in the device, with the
shift allowing for the transfer of charge between bins.

The CCD is a major piece of technology in digital
imaging. In a CCD image sensor, pixels are
represented by p-doped MOS capacitors.
In a CCD for capturing images, there is a
photoactive region (an epitaxial layer of silicon), and a
transmission region made out of a shift register .

C-MOUNT
C-mount is a type of lens
mount commonly found
on 16mm movie cameras,
closed-circuit television
cameras, machine vision
cameras and microscope
phototubes. The vast
majority of C-mount lenses
produce an image circle
too small to effectively
cover the entire (micro-)
four-thirds sensor.

Nd: YAG LASER
Nd: YAG (neodymium-doped yttrium
aluminium garnet; Nd:Y3Al5O12) is a crystal that is
used as a lasing medium for solid-state lasers.
Nd:YAG lasers are optically pumped using a
flashtube or laser diodes. These are one of the
most common types of laser, and are used for
many different applications.

STREAK IMAGING TECHNIQUE
A schematic dig. Of streak imaging technique

The particle images are recorded by CCD cameras with
coplanar continuous and pulsed laser light sheets to
reproduce a single 3D particle streak image instead of
conventional particle point images recorded at two
instants.
This new approach has several advantages:
• Cameras do not require optional double exposure
mode.
• Continuous laser source can be used and focusing of
particle image is not so severely required for
successful velocity recovery.
Moreover, the ghost particles are less generated and if
any, can be filtered out more easily.

EXPERIMENTAL INFERENCE
The quantitative characterization of the flow in the micro
bifurcation area was made using the micro-PIV measuring
system. To assess the velocity and vortex evolution in the
bifurcation area, both experimental and numerical results
were obtained by plotting the velocity vectors and making
qualitative representations of them.
Inertia effect on the streamlines
obtained in a 3D numerical simulation.

At first site, the experimental and the numerical
prediction may suggest a closed recirculation area formed
in the branch. But the self intersected path lines are only
illusive. In fact, the 3D numerical predictions show the
real effect of an open spiral that develops in the closed
branch.

Another effect is regarding the velocity profiles, which
tend to lose the parabolic symmetrical shape, as the
Reynolds number increases. This manifestation appears
due to the inertial effect amplifications caused by a
deviation of 60o of the main flow path before entering in
the bifurcation area.
velocity distribution obtained with the
micro-PIV system, compared with the
numerical prediction

CONCLUSION
In this study the manifestation of primary flows
and the developing of vortical formation were
investigated.
• The micro-PIV technique allowed performing
accurate measurements of velocity profiles in
the main flow as well as in the secondary
one.
• The developing of an asymmetric velocity
profiles in the main flow has been measured,
numerically predicted and physically
explained. .

• The capability of the 3D numerical prediction to
accurately capture both the dynamics and the
kinematics observed experimentally, proves to
have a relative rapid impact when we are
thinking to exploit the geometrical parameters
that are governing the flow in a microfluidic
device.

REFERENCE
• S.T. Wereley and C.D. Meinhart, “Recent
advances in Micro-Particle Image
Velocimetry”.
• S. Dittrich, A. Manz, “Lab-on-a-chip:
microfluidics in drug discovery”
• . Karnik, et al, “Microfluidic platform for
controlled synthesis of polymeric
nanoparticles”

Micro piv measurements for hydrodynamic characterizations of microfluidic flows

More Related Content

What's hot (12)

Similar to Micro piv measurements for hydrodynamic characterizations of microfluidic flows (20)

More from Sadiq Rahim (15)

Recently uploaded (20)

Micro piv measurements for hydrodynamic characterizations of microfluidic flows