Ch4

Question 1

What is microfluidics

Answer 1

the science and technology of systems that deals with the behaviour, precise control and manipulation of microliter and nanoliter volumes of fluids using channels with dimension of tens to hundreds of micrometers

Question 2

Advantages of microfluidics?

Answer 2

SINF
1. sample savings - nL instead of mL
2. Integration - combine lots of steps into a single device
3. faster analysis - shorter reaction time in small volumes
4. novel physics - diffusion, surface tension and surface effects dominate, leading to faster reactions

Question 3

Why miniaturization?

Answer 3

1. Small components: reduced weight and size, reduced energy consumption
2. Small sample amts: reduction consumption of material, reduced waste production, accurate dosing
3. Batch fabrication: reduced price (disposable)
4. Potential for higher yield and fewer defects: integration of sensors, parallel process
5. Device performance: scaling law for new effects, increased heat exchange, fast mass transport

Question 4

Bio-MEMS

Answer 4

Biomedical Micro Electro Mechanical Systems

Micro: small size, microfabricated structures
Electro: electrical signal/control
Mechanical: mechanical functionality
Systems: Structures, Devices, Systems, Control

Question 5

What is a lab-on-a-chip/lab-on-a-disc?

Answer 5

Miniaturized device that integrates into a single chip one or several analyses, which are usually done in a laboratory;

analyses such as:
DNA sequence
Biochemical detection.

relies on microfluidics and molecular biology

Question 6

What do we learn from scaling theory?

Answer 6

• length decreases by X, surface by X^2 and volume by X^3.
• the behaviour of fluids at the microscale is different from macroscale in factors such as surface tension
  surface tension force decreases
  capillary effect is caused by surface tension.

look at equations in slide 11

Question 7

What is scaling theory?

Answer 7

a valuable guide to what may work and what will not work. by understanding how phenomena behave and change as their scale size changes, we can gain some insight and better understand the profitable approaches

Question 8

What are scaling laws?

Answer 8

• relates to geometry and its implications on physical forces
• applies to phenomenological behaviour
• mathematically speaking phenomena that have large power dependencies on length will have a reduced effect at smaller length scales
• phenomena with lower power dependencies play an important role in the design of micro/nano systems

Question 9

what is reynolds number

Answer 9

a dimensionless number that is the ratio of inertial forces to viscous forces and consequently it quantifies the relative importance of these two types of forces for given flow conditions.

re = puL/v
p = density, u = viscosity, v = velocity, L = characteristic length

Question 10

What reynolds number with give what flow regimes?

Answer 10

Re > 2,300 is turbulent (inertial forces dominate)
Re < 2,000 is laminar (viscous forces dominate)
3,000 > Re > 2,000 is transitional

Question 11

what is hydraulic diameter?

Answer 11

Dhydro = 4A/P, where A is the cross sectional area of the channel and P is the wetted perimeter

it is used instead of characteristic length, so:
Re = puD/v

Question 12

Expression for diffusion

Answer 12

tao = L^2/aD proportional to l^2

• mixing occurs through diffusion at the microscale
• chemical reactions happen faster at the microscale

Question 13

What is poiseuille flow

Answer 13

pressure driven flow in which a pressure difference exists between the ends of a microchannel

Question 14

FLuidic resistance

Answer 14

• ratio of applied pressure (for driving the flow) and the volume flow rate (in analogy with electrical resistance: R = V/I)
• for a microchannel segment of length L: R = deltaP/Q

check slide 27 for actual formulas for resistance depending on cross section shape

Question 15

Hydraulic resistance (hagen=poiseuille law)

Answer 15

R hydr = driving force/ flow rate = delta P / Q

Q = h^3w delta P/12uL so R hyd = 12uL/h^3w in the case of flow in a section of an infinite parallel plate system

this will also change depending on cross section

Question 16

CAD and simulation of microfluidics

Answer 16

computer aided design (CAD) softwares are employed to create the microfluidic configuration, including channels and chambers etc

computational fluid dynamics (CFD) software can solve complex transport phenomena equations to test, iterate, validate and optimate the designs

Question 17

difference between flow in macrochannels vs microchannels

Answer 17

look at slide 36 - 38

Question 18

what happens at small scales?

Answer 18

• at small scales (10-1000mm) some interesting and unintuitive properties appear
• inertia means nothing
• viscosity is important
• flow is laminar
• surface is important
• fluidic resistance dominates

Question 19

What are some unique characteristics of microfluidics?

Answer 19

• DEterministic feature due to laminar flows at microscale:
  —> flow patterns and concentrations are mathematically predictable –> experimental and theoretical results agree well
• micrometer size of channels: fits well with biological cell size –> suitable for probing cell behaviour, handling single cells, imitating physiological parameters
• easy integration for automatic fluid control (quake valve) –> avoid human errors and operator costs
• low cost: batch fabrication, high density integration, high throughput, multiplexed assays
• low consumption of reagents, smaller footprint –> potentially portable

Question 20

What are the two types of synthesis/fabrication methods

Answer 20

• bottom-up fabrication methods (wet-chemistry, physical/chemical deposition, electrodeposition)
• top down (lithography)

Question 21

top-down lithography?

Answer 21

• materials (glass, fused silica, silicon)
• resist (e-beam, photo)
• lithography (e-beam/photo)
• etch (wet/dry)

Question 22

what is needed for photolithography?

Answer 22

• a photomask for selective exposure of resist
• a photoresist that is an optically sensitive polymer

–>with a positive PR, light will remove the exposed areas
–> with a negative PR, light will do the opposite

Question 23

What is the difference between wet and dry etching?

Answer 23

wet:
- isotropic
3 spatial directions
- spherical cavities
- HF for glass and fused silica
- large depth

dry:
- anisotropic
- depends on crystallographic orientation
- flat surfaces, such as wells or channels
- reactive ion etching, CHF3 for silica
- small depth

Question 24

What are the properties of fused silica?

Answer 24

thermal: diffusion bonding at temp over 1000C is possible
chemical resistance to acids (not HF0 and solvents
optical: high optical clarity which makes it suitable for single molecule resolution microscopy

Question 25

how does electron beam lithography work?

Answer 25

A focused beam of electrons is scanned across a substrate covered by an electron-sensitive material (resist) and changes it solubility properties

a positive resist of PPMA is used
important parameters: resolution

EBL system consists of a chamber, an electron gun, a column containing all the electron optics needed to focus and scan the electron beam

dispersion of e-beam resist –> e beam lithography –> development –> dry etch –> SEM