AMN- 606 MEMS/NEMS Technology and Devices
Lecture 3-4: Micro-machining
Dr. Hassan Mostafa
Cairo University
Fall 2018
Basic Processing Tools
Physical Vapor Deposition
(PVD)
includes Sputtering and
Evaporization
Sputtering deposition
In sputter deposition, a target made of a material to be deposited is physically bombarded by a flux of inert-gas ions (usually Argon due to its heavy atoms) in a vacuum chamber
Atoms or molecules from the target are ejected and deposited onto the wafer
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Basic Processing Tools
Sputtering deposition types
Direct-current (dc) glow discharge (dc plasma)
suitable only for electrically conducting materials (WHY?)
Deposition of an insulator results in accumulating the positive Ar ions on the target and stops the electrons flow
Voltage of 1012 V is needed
the inert-gas ions are accelerated in a dc electric field between the target and the wafer
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Basic Processing Tools
Sputtering deposition types
Planar RF Sputtering
the target and the wafer form two parallel plates with RF excitation
the positive Ar ions will accumulate when the target is negative
when the target is positive (short time), the electrons from the plasma will be attracted to it and neutralize the Ar ions.
The Ar ions will not hit the wafer but the electrons will hit the target because the Ar ions are much heavier than electrons
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Basic Processing Tools
Sputtering deposition types.
Ion-beam deposition
ions are generated in a remote plasma, then accelerated at the target
RF planar sputtering and ion-beam methods work for the deposition of both conducting and insulating materials, such as silicon dioxide
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Basic Processing Tools
Sputtering deposition Typical deposition rates are 0.1–0.3 μm/min, and can be as high as 1
μm/min for aluminum in certain sputtering tools
In reactive sputtering, a reactive gas such as nitrogen or oxygen is added during the sputtering of a metal to form compounds such as titanium nitride or titanium dioxide
The directional randomness of the sputtering process, provided that the target size is larger than the wafer, results in good step coverage
Step coverage is the uniformity of the thin film over a geometrical step though some thinning occurs near corners
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Basic Processing Tools
Evaporization
Evaporation involves the heating of a source material to a high temperature, generating a vapor that condenses on a substrate to form a film
Evaporation is performed in a high vacuum chamber
Target heating can be done
resistively by passing an electrical current through a tungsten filament, strip, or boat holding the desired material
high voltage (i.e., 10-kV) electron beam (e-beam) over the source material
E-beam provides better-quality films and slightly higher deposition rates (5–100 nm/min), but the deposition system is more complex than the resistive heating
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Basic Processing Tools
Evaporization
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Basic Processing Tools
Chemical Vapor Deposition (CVD)
initiating a surface chemical reaction in a controlled atmosphere, resulting in the deposition of a reacted species on a heated substrate
In contrast to sputtering, CVD is a high temperature process, usually performed above 300ºC
CVD processes are categorized as
APCVD (Atmospheric-Pressure CVD)
LPCVD (Low-Pressure CVD)
PECVD (Plasma-Enhanced CVD)
HDP-CVD (High-Density Plasma CVD)
APCVD and LPCVD methods operate at rather elevated temperatures (400º–800ºC).
In PECVD and HDP-CVD, the substrate temperature is typically near 300ºC
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Basic Processing Tools
Deposition of Polysilicon
Chemical-vapor deposition processes allow the deposition of polysilicon as a thin film on a silicon substrate
Polysilicon is deposited by the pyrolysis of Silane (SiH4) to silicon and hydrogen in a LPCVD reactor
Deposition from Silane in a low-temperature PECVD reactor is also possible but results in amorphous silicon (non-crystalline form of silicon)
What is the difference between Single crystalline, Poly crystalline, and Amorphous Silicon??
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Basic Processing Tools
Deposition of Silicon Dioxide
Silicon dioxide is deposited below 500ºC by reacting Silane and oxygen in an APCVD, LPCVD, or PECVD reactor
Due to the low temperature compared to thermally grown oxide, this is known as low-temperature oxide (LTO)
Deposition of Silicon Nitride
Silicon nitride is common in the semiconductor industry for the passivation of electronic devices because it forms an excellent protective barrier against the diffusion of ions
In micromachining, LPCVD silicon nitride films are effective as masks for the selective etching of silicon
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Basic Processing Tools
Spin-On Methods
Spin-on is a process to put down layers of dielectric insulators and organic materials
Unlike the methods described earlier, the equipment is simple, requiring a variable-speed spinning table with appropriate safety screens
A nozzle dispenses the material as a liquid solution in the center of the wafer. Spinning the substrate at speeds of 500 to 5,000 rpm for 30 to 60 seconds spreads the material to a uniform thickness
Photoresists are common organic materials that can be spun on a wafer with thicknesses between 0.5 and 20 μm
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Basic Processing Tools
Spin-On Methods
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Basic Processing Tools
Etching
the objective is to selectively remove material using imaged photoresist as a masking template. The pattern can be etched directly into the silicon substrate or into a thin film
Bulk micromachining defines structures by selectively etching inside a substrate
Surface micromachiningcreates structures on top of a substrate
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Basic Processing Tools
Etching
DRIE (Deep Reactive Ion Etching)
highly anisotropic etching process
DRIE evolved from the need within the micromachining community for an etch process capable of vertically etching high-aspect-ratio trenches at rates larger than the 0.5 μm/min <typical of plasma etchers>
It was developed for MEMS, which require these features
Recently for creating Through Silicon Via (TSV) in advanced 3D wafer level packaging technology
In Bosch process, the following two modes are repeated
A standard, nearly isotropic plasma etching is adopted which uses ions that attack the wafer
Deposition of a chemically passivation layer
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Basic Processing Tools
Etching
DRIE (Deep Reactive Ion Etching)
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Advanced Process Tools
Anodic Bonding (field-assisted bonding)
A simple process to join together a silicon wafer and a sodium-containing glass substrate (i.e., pyrex)
used in the manufacturing of a variety of sensors, including pressure sensors
provides a rigid support to the silicon that mechanically isolates it from packaging stress
The bonding is performed at a temperature between 200°and 500°C in vacuum, air, or in an inert gas environment
The application of 500 to 1,500V across the two substrates, with the glass held at the negative potential, causes mobile positive ions (Na+) in the glass to migrate away from the silicon-glass interface toward the cathode, leaving behind fixed negative charges in the glass
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Advanced Process Tools
Anodic Bonding
The bonding is complete when the ion current (measured externally as an electron current) vanishes, indicating that all mobile ions have reached the cathode
The built-in large electric field at the silicon-glass interface is the reason for holding the glass substrate to the silicon wafer
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Advanced Process Tools
Chemical Mechanical Polishing/Planarization (CMP)
The resulting surface roughness is removed in the subsequent polishing step in which wafers are mounted inside precise templates on a rotating table
A wheel with a felt-like texture polishes the wafer surface using a slurry containing fine silica in a very dilute alkaline solution
The final surface is smooth, with a thickness control as good as ±0.5 μm
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CMP
Advanced Process Tools
LIGA
German abbreviation and stands for Lithographie, Galvanoformung and Abformung (lithography, electrodeposition and molding)
The LIGA Fabrication process provides the possibility to produce micromechanical structures with very high aspect ratios compared to other microelectromechanical technologies (up to 300:1)
The height of the manufactured pieces can be 100 microns to a couple of millimeters
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Advanced Process Tools
LIGA
The principle of the LIGA process consists of depositing a relatively thick layer of a polymer sensitive to X-rays on top of a conductive substrate or one covered with a conductive seed layer
multiple coats of photoresist during spinning the substrate wafer for thicknesses of up to a few hundred microns
plates of PMMA (poly-methyl-meth-acrylate), a thicker polymer layers (millimeters) used as a photoresist
After exposure through an appropriate X-ray-mask, a developer removes either the exposed (positive photoresist) or the unexposed (negative) areas of polymer
Metal layers are grown by electroplating in the spaces now free from cover
Having removed the unwanted areas of the polymer, the resulting metallic structure can be used
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Advanced Process Tools
LIGA
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Advanced Process Tools
LIGA
The process may be stopped at this point with a metal microstructure suitable for some purposes such as gears
Alternatively, the metal can be used as a mold for plastic parts (the “A” in LIGA)
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Advanced Process Tools
LIGA
Advantages:
high aspect ratios
very sharp vertical sidewalls as well as the possibility to produce three-dimensional structures
Disadvantages:
the need of high-energy X-rays
the expensive X-ray masks needed for exposure make the cost for the process high
Mold formation using optical lithography is often called “poor man’s LIGA” due to the small aspect ratios
Companies providing the necessary tools for LIGA to multiple users can reduce the production cost
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Advanced Process Tools
LIGA examples (Metals)
Microfluidic device
Micromechanical actuator (capacitive comb drive)
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Advanced Process Tools
LIGA examples (Plastic)
World’s smallest helicopter is contructed from parts made using LIGA process
The world's tiniest helicopter has a length of 24 millimeters and a weight of 0.4 grams and takes off at 40,000 rpm
With a diameter of only 1.9 millimeters the electromagnetic motors can reach an incredible revolution speed of nearly half a million rpm on the one hand
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SU-8 Photosensitive Epoxy (poor man’s LIGA)
New negative photosensitive epoxy resist, SU-8, developed by IBM is capable of yielding high aspect ratio structures
Processing uses standard lithography equipment: UV light source and standard masks
Structures up to several millimeters thick have been demonstrated with aspect ratios of ~15:1
Advanced Process Tools
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SU-8 Photosensitive Epoxy (poor man’s LIGA)
Advantages:
High aspect ratio micro-structures can be built cheaply
Uses standard lithography equipment in standard cleanrooms
Disadvantages:
Resist is very difficult to be removed (stripped)
Good for small parts, but most useful devices require assembly
SU-8 is used to form microfluidic channels and optical waveguides
Advanced Process Tools
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Laser Machining Focused high power laser pulses can
ablate material (explosively remove it as fine particles and vapor) from a substrate
Incorporating such a laser in a computer-numerical-controlled (CNC) system enables precision laser machining
Metals, ceramics, silicon, and plastics can be laser machined
Holes as small as tens of microns in diameter, with aspect ratios greater than 10:1, can be produced
Laser machining is most often a serial process, but with mask-projection techniques, it becomes a parallel process
Nonlithographic Microfabrication
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Micro-contact Printing/Soft Lithography
Production of the original, hard, 3D master pattern
A mold of an elastomer, usually poly-di-methyl-siloxane (PDMS), is made against the master, then peeled off to create a stamp
An “ink,” is poured onto the PDMS stamp and dried
Nonlithographic Microfabrication
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The metal can then be used as an etch mask for the underlying substrate, such as silicon
Alternatively, selective plating of the metal can be carried out
Micro-contact Printing/Soft Lithography
The inked stamp is then held against a substrate coated with gold, silver, or copper, then removed
The coating is used as an etch mask for the metal
Nonlithographic Microfabrication
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Nano-imprint Lithography
Starts with a mold of etched silicon, silicon dioxide, or other hard material created using optical or electron-beam lithography
The substrate is coated with a 50nm to 250nm resist layer, which does not need to be photosensitive
The resist is heated so that it flows easily under pressure
Nonlithographic Microfabrication
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Nano-imprint Lithography
The mold is then pressed into the resist
The mold is removed, leaving an unintentional residue of resist
This residue is stripped using vertical etching
Features 25nm wide with smooth sidewalls have been demonstrated
Nonlithographic Microfabrication
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Micro device is not useful until it is placed in a “package” that allows it to interface with the real world
MEMS packaging is extremely difficult and expensive. 80% of cost of MEMS is in package.
MEMS Packaging
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CMOS packaging includes:
Silicon wafer with dies
Wafer level probe test
Dicing
Die attach to lead frame
Wire bonding
Final packaged chip
MEMS Packaging
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Problems:
MEMS device cannot be tested at the wafer level. It must be released in order to test!
MEMS part cannot be “pick and placed” by automated machinery and Must be treated carefully
MEMS part must be handled in clean room environment
MEMS part typically tested after dicing, cleaning, release, and packaging—after much cost has already been incurred
MEMS part often requires vacuum sealing
MEMS Packaging
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Solutions:
Build package over MEMS part during clean room fabrication
Treat similarly as semiconductor device.
Apply temporary package array to wafer prior to testing.
Perform wafer-level release.
Perform testing, dicing, etc.
MEMS Packaging
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New paradigm for MEMS/NEMS FAB
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Nano Investigating Tools
Optical microscopes are limited to 200nm due to light diffraction and resolution limits
New Nano investigation tools are utilized such as:
SEM
TEM
AEM
SPM
STM
AFM
Nano-Lithography
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Scanning Electron Microscope (SEM)
SEM uses a focused beam of electrons to scan the surface of the sample in Vacuum environment inside the SEM
SEM samples must conduct electricity
a beam of electrons of high energy down through a series of magnetic lenses, which focus the beam to a very fine point
A set of scanning coils move the focused beam back and forth across the specimen row by row
As the electron beam hits each spot on the sample, electrons are reflected to a detector that counts these electrons and sends the signals to an amplifier
The final image is collected from the number of electrons emitted from each sample spot and shown on a computer screen
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Scanning Electron Microscope (SEM)
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Transmission Electron Microscope (TEM)
SEM can only scan the surface of the sample, whereas, TEM can see all the way through a sample
A wide beam of electrons passes through a thinly sliced sample to form an image
The electrons that a TEM uses to project images are focused by magnets similar to the glass lens bends light in a regular optical microscope
Electrons can be focused until a clear picture appears on the monitor
TEM is similar to a regular optical microscope in that thicker or denser areas of a sample absorb or scatter the beam causing dark areas, while less dense areas look bright
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Transmission Electron Microscope (TEM)
At the bottom of the microscope the unscattered/unabsorbed electrons hit a fluorescent screen, which gives rise to a "shadow image" of the specimen with its different parts displayed in varied darkness according to their density
The image can be photographed with a camera
Resolution of a TEM is about 0.1nm to 0.2nm
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Analytical Electron Microscope (AEM)
TEMs are used to look inside materials at high magnification
To expand the role of TEM, We need to develop the ability to measure material structure and chemical characteristics atom by atom
For this purpose, a TEM is equipped with analytical instruments, such as X rays and electron spectrometers, which makes TEM an analytical electron microscope (AEM)
These machines measure and form images from X rays created by atoms
Such measurements can distinguish, for example, between carbon atoms from nitrogen atoms, allowing scientists to map out the compositions of materials
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Scanning Probe Microscope (SPM)
It is used to study the surface characteristics of material at the atomic scale
It has a probe tip that tracks and records sample surface changes as the surface of the sample is moved
The tip records the height, electrical or other changes on the surface
SPM methods are used to form and investigate tiny circuit elements and custom made molecules
Two types:
Scanning tunneling microscope (STM)
Atomic force microscope (AFM)
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Scanning Probe Microscope (SPM)
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Scanning Tunneling Microscope (STM)
This microscope uses a fixed probe tip to measure material's surface electrical characteristics
Various kinds of images can be seen depending on the type of STM probe tip used
The simplest method is to scan the structure of a surface keeping the tip a constant distance away such as 0.2 nm, and the tip is raised or lowered to keep the current flowing at a constant value, which means the distance is maintained
a voltage is created between the probe tip and the conductive sample's surface to cause a flow of electrons across the gap
When the tip moves up or down relative to the surface to keep the tunneling current constant, it then tracks and records the sample's topography
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Scanning Tunneling Microscope (STM)
For current to be maintained the sample must be conductive (i.e., Insulating sample must be coated first by a conductive coating)
STM can also cause chemical reactions and create ions by pulling off individual electrons from atoms or adding these electrons
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Scanning Tunneling Microscope (STM)
The up and down motions of the tip are controlled by piezoelectric elements and recorded by a computer
Piezoelectricity is the ability of some crystals to create mechanical stress, or motion in response to applying voltage
the piezoelectric crystal expands or contracts to keep the distance between the tip and sample surface constant depending on the voltage applied to it
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Scanning Tunneling Microscope (STM)
Atomic Force Microscope (AFM)
An important limitation of STM is that is can be used only with specimens that conduct electric current
Atomic force microscopes (AFMs) can be used to study conducting and insulating materials
AFM is based on scanning a flexible force sensing cantilever across a specimen
Attractive and repulsive forces acting on the cantilever cause deflections that can be measured with laser methods, in which a laser beam reflects off the back side of the probe tip to find the position of the probe tip
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Atomic Force Microscope (AFM)
Atomic Force Microscope (AFM)
The AFM can operate in several modes, such as:
Contact mode
the tip touches the specimen surface and senses inter-nuclear repulsive forces between the nuclei in the tip and nuclei in the sample
Noncontact mode
the probe is held just above the surface and the small electrostatic van der Waals attractive forces between atoms not in contact are measured
As with STM, a feedback circuit can be used to adjust the tip to maintain a constant force
The tip motions can be recorded and converted into relief maps
AFM produces 3D images, while optical and electron microscopes (SEM, TEM, AEM) produce only 2D images
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Nano-Lithography (Bottom-Up)
These new investigation tools have the ability to – not just characterize– but actually move individual atoms and molecules
A probe tip was used to deliver carbon monoxide molecules one at a time to an iron atom
An interesting research is concerned with using an AFM tip to convey molecular ink to a substrate, enabling it to draw patterns with nanometric dimensions
A key shortcoming of scanning probe procedure is the slow serial methods by which they operate, which limits their use mainly to laboratory applications
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