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Practical Training Report at IIT Mumbai
PRACTICAL TRAINING
AT
IIT - BOMBAY
POWAI - MUMBAI
Indian Instituite Of TechnologyBombay
IIT Bombay, set up by an Act of Parliament, was established in 1958, at Powai, a northern
suburb of Mumbai. Today the Institute is recognised as one of the centres of academic
excellence in the country. Over the years, there has been dynamic progress at IIT Bombay in
all academic and research activities, and a parallel improvement in facilities and
infrastructure, to keep it on par with the best institutions in the world. Institutes in positions
of excellence grow with time. The ideas and ideals on which such institutes are built evolve
and change with national aspirations, national perspectives, and trends world - wide. IIT
Bombay, too, is one such institution.
Department Of Electrical Engineering
The EE department at IIT Bombay has been active in teaching and research since itsinception in 1957. Currently, about 45 faculty members are engaged in research in the areas
of Communication and Signal Processing, Control and Computing, Power Electronics and
Power Systems, Microelectronics and VLSI design, and Electronic Systems.
The department has academic programmes with about 320 undergraduate and 200
postgraduate students. The department is equipped with the latest experimental and
computational facilities for taking up R & D and consultancy activities in various fields.
CTARA
Since its inception in 1985, Center for Technology Alternatives for Rural Areas (CTARA) atIIT-Bombay is involved in design and development of technologies relevant to rural areas.
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The current working areas of CTARA include farm machinery, food processing, low cost
housing, renewable energy, water management, rural industry etc. The CTARA carries out its
programmes through full time research assistants, visiting experts and associated faculty
members from different disciplines at IIT. Presently the undergraduate and graduate students
from other engineering or applied science disciplines participate in CTARA activities as a
part of thesis or project requirement.
CONTENTS
1. Introduction
2. Cooling Using Microchannels
3. Two Phase Flow in Microchannels
4. Annular Flow Model
5. Fabrication of Silicon Chip
6.
Lithography7. Photolithography
8. Lithography Module
9. Etching
10.Conclusion
11.Scope for Future work
12.References
1. INTRODUCTION
Power densities encountered in microelectronic equipment have increased tremendously due
to progress in semiconductor technology. Integrated circuits in the near future are expected to
have such large power densities, that traditional air cooling will no longer be sufficient to
cool them. The thermal design goal is to limit the magnitude of chip temperature rise above
ambient temperature in order to ensure satisfactory electrical circuit operation and reliability.
For optimal performance and lifetime of these devices, more efficient cooling techniques will
be required.
Microprocessors, in the near future, are expected to have a requirement for removing
a very large amount of heat from a small area. Conventional air cooled heat sinks will no
longer be sufficient to cater to this requirement. Heat transfer to fluids flowing through
microchannels is being looked upon as a promising solution to this problem. Hence, a
thorough understanding of heat transfer in microchannels has become a necessity.
Our knowledge of macro-scale heat transfer cannot in general be directly applied to heattransfer in microchannels. Experimentation and modeling studies are being carried out by
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various researchers around the world to obtain a better understand of micro-scale heat
transfer. There is a need for the development of better models and correlations to explain
experimental observations related to microflows. Annular flow is a flow pattern observed by
several researchers in microchannels. Annular flow model has been studied, modified and
extended for obtaining the pressure distribution and for handling non-uniform heating along
the microchannel.
2. COOLING USING MICROCHANNELSA very promising solution for cooling microchips is by heat transfer to single phase and
boiling fluids flowing through microchannels. To cool a small device having a large power
density, we require a very large heat transfer coefficient between the device and the cooling
fluid. From our experience with macro-scale flows, we know that in a fully developed
laminar flow of a liquid through a tube with uniform surface heat flux, the Nusselt number isa constant. This implies that, the heat transfer coefficient is inversely proportional to the
hydraulic diameter. Thus, the heat transfer coefficient is expected to have a very large value
when the hydraulic diameter of the channel is in the range of micrometers. However, such an
increase will come at the cost of a significant increase in pressure drop across the channel.
3. TWO PHASE FLOW IN MICROCHANNELSIt has been claimed by Goodson et al. [3] that boiling heat transfer in microchannels requires
less pumping power than single-phase liquid convection to achieve a given heat sink thermal
resistance. Also, using a two phase flow helps to eliminate large temperature variations
within the device. Unless a very large flow rate is used, this is difficult to achieve using a
single phase flow. A large flow rate will invariably lead to a large pressure drop which
requires more pumping power, may generate more noise and requires bulkier packaging.
4. ANNULAR FLOW MODELAnnular flow is a regime that has been observed by many researchers in microchannels. Qu
and Mudawar [8] have attempted a model of annular flow that is described in brief below.
In an annular flow, the vapor phase flows along the center of the channel and is
surrounded by a thin film of liquid along the channel walls. The vapor phase, thus, forms a
continuous vapor core in the center of the channel. Liquid droplets are entrained in the vapor
core. Mass is continuously exchanged between the liquid film and vapor core in the direction
of the fluid flow.
Figure 3.1 is a representation of the annular flow in a microchannel.
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Figure Error! No text of specified style in document.. 1 (a) Schematic of annular flow pattern
in a microchannel heat sink [8]
(b) Idealized annular flow region [8]
The model has been constructed by means of equations for mass conservation and
momentum conservation in the liquid film and the vapor core. These mass and momentum
conservation equations have been solved numerically and the predictions have been
compared with experimental data. Good agreement has been claimed between experimental
data and model predictions.
Dryout
When there is a very high heat input into the channel, the fluid film may completely
evaporate. This condition is known as dryout. The annular flow equations are no longer valid
beyond this point. Hence, appropriate changes must be incorporated in the program to
identify this scenario.
5. FABRICATION OF SILICON CHIP
Channels are made with glass and
silicon using microfabrication
techniques. Channel masks are printed
in positive with a high-resolution
printer on transparent paper for
lithography. Photoresist is spin coatedon a silicon wafer. The wafer is then Two-phase flow microchannel module
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exposed to UV light through the
mask. Channels are etched at different
depths using Deep Reactive Ion
Etching (DRIE). The sealing is made
with Pyrex glass using anodic
bonding, providing optical access forflow analysis.
Properly introducing gas bubbles is an
important step in producing a two-phase
flow pattern. We micromachined an
effective small mixing section on-chip.
Well-defined bubbles in a wide range of
sizes can be produced as a function of
liquid and gas flow rates. Because of thesquare channel symmetries, bubbles flow
naturally in the center of the channel.
The cross-shaped was chosen to produce
a steady uniform flow. The minimal size
of bubbles is about the size of the
channel. In these experiments, this
mixing system is used as an effective
way to produce two-phase flows in
microdevices.
6. LITHOGRAPHY
Lithography is typically the transfer of a pattern to photosensitive material by selective
exposure to a radiation source such as light. A photosensitive material is a material that
experiences in its physical properties when exposed to a radiation source. If we selectively
expose a photosensitive material to radiation (e.g. by masking some of the radiation) the
pattern of the radiation on the material is transferred to the material exposed, as the properties
of the exposed and unexposed regions differ (as shown in fig 1).
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Figure 1:Transfer of pattern to a photosensitive material
This discussion will focus on optical lithography, which is simply lithography using a
radiation source with wavelength(s) in the visible spectrum.
In lithography for micromachining, the photosensitive material used is typically a photoresist
(also called resist, other photosensitive polymers are also used). When resist is exposed to a
radiation source of a specific a wavelength, the chemical resistance of the resist to developer
solution changes. If the resist is placed in a developer solution after selective exposure to a
light source, it will etch away one of the two regions (exposed or unexposed). If the exposed
material is etched away by the developer and the unexposed region is resilient, the material is
considered to be a positive resist (shown in figure 2a). If the exposed material is resilient to
the developer and the unexposed region is etched away, it is considered to be a negative resist
(shown in figure 2b).
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Figure 2:a)Pattern definition in positive resist, b)Pattern definition in negative resist.
Lithography is the principal mechanism for pattern definition in micromachining.
Photosensitive compounds are primarily organic, and do not encompass the spectrum of
materials properties of interest to micro-machinists. However, as the technique is capable of
producing fine features in an economic fashion, a photosensitive layer is often used as a
temporary mask when etching an underlying layer, so that the pattern may be transferred to
the underlying layer (shown in figure 3a). Photoresist may also be used as a template for
patterning material deposited after lithography (shown in figure 3b). The resist is
subsequently etched away, and the material deposited on the resist is "lifted off".
The deposition template (lift-off) approach for transferring a pattern from resist to another
layer is less common than using the resist pattern as an etch mask. The reason for this is that
resist is incompatible with most MEMS deposition processes, usually because it cannot
withstand high temperatures and may act as a source of contamination
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Figure 3:a)Pattern transfer from patterned photoresist to underlying layer by etching, b)
Pattern transfer from patterned photoresist to overlying layer by lift-off.
Once the pattern has been transferred to another layer, the resist is usually stripped. This is
often necessary as the resist may be incompatible with further micromachining steps. It also
makes the topography more dramatic, which may hamper further lithography steps.
Alignment
In order to make useful devices the patterns for different lithography steps that belong to a
single structure must be aligned to one another. The first pattern transferred to a wafer usually
includes a set of alignment marks, which are high precision features that are used as the
reference when positioning subsequent patterns, to the first pattern (as shown in figure 4).
Often alignment marks are included in other patterns, as the original alignment marks may be
obliterated as processing progresses. It is important for each alignment mark on the wafer to
be labeled so it may be identified, and for each pattern to specify the alignment mark (and the
location thereof) to which it should be aligned. By providing the location of the alignment
mark it is easy for the operator to locate the correct feature in a short time. Each pattern layer
should have an alignment feature so that it may be registered to the rest of the layers.
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Figure 4:Use of alignment marks to register subsequent layers
Depending on the lithography equipment used, the feature on the mask used for registration
of the mask may be transferred to the wafer (as shown in figure 5). In this case, it may beimportant to locate the alignment marks such that they don't effect subsequent wafer
processing or device performance. For example, the alignment mark shown in figure 6 will
cease to exist after a through the wafer DRIE etch. Pattern transfer of the mask alignment
features to the wafer may obliterate the alignment features on the wafer. In this case the
alignment marks should be designed to minimize this effect, or alternately there should be
multiple copies of the alignment marks on the wafer, so there will be alignment marks
remaining for other masks to be registered to.
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Figure 5:Transfer of mask registration feature to substrate during lithography (contact
aligner)
Figure 6:Poor alignment mark design for a DRIE through the wafer etch (cross hair is
released and lost).
Alignment marks may not necessarily be arbitrarily located on the wafer, as the equipment
used to perform alignment may have limited travel and therefore only be able to align to
features located within a certain region on the wafer (as shown in figure 7). The regionlocation geometry and size may also vary with the type of alignment, so the lithographic
equipment and type of alignment to be used should be considered before locating alignment
marks. Typically two alignment marks are used to align the mask and wafer, one alignment
mark is sufficient to align the mask and wafer in x and y, but it requires two marks
(preferably spaced far apart) to correct for fine offset in rotation.
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Figure 7:Restriction of location of alignment marks based on equipment used.
As there is no pattern on the wafer for the first pattern to align to, the first pattern is typically
aligned to the primary wafer flat (as shown in figure 8). Depending on the lithography
equipment used, this may be done automatically, or by manual alignment to an explicit wafer
registration feature on the mask.
Figure 8:Mask alignment to the wafer flat.
7. PHOTOLITHOGRAPHY
Photolithographyor optical lithographyis a process used in semiconductor device
fabrication to transfer a pattern from a photomask (also called reticle) to the surface of a
substrate. Often crystalline silicon in the form of a wafer is used as a choice of substrate,
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although there are several other options including, but not limited to, glass, sapphire, and
metal. Photolithography (also referred to as "microlithography" or "nanolithography") bears a
similarity to the conventional lithography used in printing and shares some of the
fundamental principles of photographic processes.
Photolithography involves a combination of:
substrate preparation photoresist application soft-baking exposure developing hard-baking etching
and various other chemical treatments (thinning agents, edge-bead removal etc.) in repeated
steps on an initially flat substrate.
A part of a typical silicon lithography procedure would begin by depositing a layer of
conductive metal several nanometers thick on the substrate. A layer of photoresist -- a
chemical that hardens when exposed to light (often ultraviolet) -- is applied on top of the
metal layer. The photoresist is selectively "hardened" by illuminating it in specific places. For
this purpose a transparent plate with patterns printed on it, called a photomask or
shadowmask, is used together with an illumination source to shine light on specific parts of
the photoresist. Some photoresists work well under broadband ultraviolet light, whereas
others are designed to be sensitive at specific frequencies to ultraviolet light. It is also
possible to use other types of resist that are sensitive to X-Rays and others that are sensitive
to electron-beam exposure.
A spinner used to apply photoresist to the surface of a silicon wafer.
Generally most types of photoresist will be available as either "positive" or "negative". With
positive resists the area that you can see (masked) on the photomask is the area that you will
see upon developing of the photoresist. With negative resists it is the inverse, so any area that
is exposed will remain, whilst any areas that are not exposed will be developed. After
developing, the resist is usually hard-baked before subjecting to a chemical etching stagewhich will remove the metal underneath.
Finally, the hardened photoresist is etched using a different chemical treatment, and all that
remains is a layer of metal in the same shape as the mask (or the inverse if negative resist has
been used).
Lithography is used because it affords exact control over the shape and size of the objects it
creates, and because it can create patterns over an entire surface simultaneously. Its main
disadvantages are that it requires a substrate to start with, it is not very effective at creating
shapes that are not flat, and it can require extremely clean operating condition.
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8. The LITHOGRAPHY MODULE
Typically lithography is performed as part of a well-characterized module, which includes thewafer surface preparation, photoresist deposition, alignment of the mask and wafer, exposure,
develop and appropriate resist conditioning. The lithography process steps need to be
characterized as a sequence in order to ensure that the remaining resist at the end of the
modules is an optimal image of the mask, and has the desired sidewall profile.
The standard steps found in a lithography module are (in sequence): dehydration bake,
HMDS prime, resist spin/spray, soft bake, alignment, exposure, post exposure bake, develop
hard bake and descum. Not all lithography modules will contain all the process steps. A brief
explanation of the process steps is included for completeness.
Dehydration bake - dehydrate the wafer to aid resist adhesion.
HMDS prime - coating of wafer surface with adhesion promoter. Not necessary forall surfaces.
Resist spin/spray - coating of the wafer with resist either by spinning or spraying.
Typically desire a uniform coat.
Soft bake - drive off some of the solvent in the resist, may result in a significant loss
of mass of resist (and thickness). Makes resist more viscous.
Alignment - align pattern on mask to features on wafers.
Exposure - projection of mask image on resist to cause selective chemical property
change.
Post exposure bake - baking of resist to drive off further solvent content. Makes resist
more resistant to etchants (other than developer).
Develop - selective removal of resist after exposure (exposed resist if resist is
positive, unexposed resist if resist is positive). Usually a wet process (although dry
processes exist).
Hard bake - drive off most of the remaining solvent from the resist.
Descum - removal of thin layer of resist scum that may occlude open regions in
pattern, helps to open up corners
9. ETCHING
Etchingis a method of printmaking in which the image is incised into the surface of a
metal plate using an acid.
Wet etchingis the removal of material by immersing the wafer in a liquid bathof
chemical etchant. There are two kinds of wet etching etchants, isotropic etchants and
anisotropic etchants:
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Isotropic etchants attack the material being etched at the same rate in all directions. Anisotropic etchants attack the silicon wafer at different rates in different directions.
On wafers the most used etchant is KOH.
Anisotropic etching does not cause undercutting, and is preferred in applications
where straight side walls are essential.
Anisotropic etching requires a substrate with a well defined crystalline structure such
as silicon. The etch is directional and proceeds along the exposed plane in the crystal
lattice. As atoms are removed from the crystal lattice, different planes are exposed to
the etchant. Since the density of atoms on the planes varies, the etch rate varies
significantly.
Figure 1:Difference between anisotropic and isotropic wet etching.
In silicon, a popular anisotropic wet etch substrate, the initial (0 degree) surface is called 100
and etches a hundred times faster than the 110 (45 degree) and 111 (54 degree) surfaces. Thisresults in a consistent wedge shaped etch pattern.
Wet etching is also used for the characterization of the quality of a wafer. The etch pit density
is a measure for the number of dislocations per area.
10. CONCLUSIONS
Two phase heat transfer to fluids flowing through microchannels is a promising solution to
the problem of cooling integrated circuits with very high power densities. Macro-scale results
cannot be directly applied to microchannels. Onset of annular flow and dryout may besignificantly affected by the location of a hotspot along the microchannel. In a practical
cooling device having a set of parallel microchannels with common inlet and exit manifolds,
the flow will distribute itself between the channels depending on the heat input to each of the
channels. In certain cases, it is not possible to have equal pressures across two channels
without encountering dryout in one of them.
Parametric studies may help an engineer to choose suitable operating conditions for
microchannel heat sink. These studies are also helpful in understanding the physics involved
in two phase flows. Hydraulic diameter of the microchannel, mass flow rate,
Heat input and subcooling at the inlet are some of the parameters that can affect the pressuredrop across the microchannels and two phase heat transfer coefficient.
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11. SCOPE FOR FUTURE WORKThere is a great scope for doing experimental work to verify the predictions of
these modeling studies. The results presented in the chapter on parametric studies may prove
to be especially suitable for experimental verification. There is scope for including more
features in the annular flow model, like a temperature dependent viscosity, to possibly obtain
a better match with experimental observations. Based on the modeling and experimental
results, some standards could be developed for the design of microchannel heat sinks to be
used for cooling microprocessors
12. REFERENCES
[1] G. Hetsroni, Z. Mosyak, G. Ziskind, A uniform temperature heat sink for cooling of
electronic devices, Int. J. Heat Mass Transfer 45 (2002) 3275-3286.
[2] L. Zhang, J. Koo, L.Jiang, M. Ashegi, K. Goodson, J. Santiago, T. Kenny, Measurement
and modeling of two-phase flow in microchannels with nearly constant heat flux boundary
condition, J. Microelectromech. Syst. 11 (2002) 12-19.
[3] W. Qu, I. Mudawar, Flow boiling heat transfer in two-phase microchannel heat sinksI.
Experimental investigation and assessment of correlation methods, Int. J. Heat Mass Transfer
46 (2003) 2755-2771.
[4] P. Lee, H. Li, F. Tseng, C. Pan, Nucleate boiling Heat transfer in Silicon-based
microchannels, Proceedings of ASME summer heat transfer conference, 2003, pp.1-4.
[5] W. Qu, I. Mudawar, Flow boiling heat transfer in two-phase microchannel heat sinks
II. Annular two-phase flow model, Int. J. Heat Mass Transfer 46 (2003) 2773-2784.
[6] S. Kandalikar, Microchannels and Minichannels - History, terminology, classification
and current research needs, Proceedings of First International Conference on Microchannels
and Minichannels, 2003, pp. 1-6.