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Chapter 9: Micro Structure Technology and Micromachined Devices

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Title: Chapter 9: Micro Structure Technology and Micromachined Devices


1
Chapter 9Micro Structure Technology
andMicromachined Devices
  • Picture shows the interior chip assembly of the
    SA30 Crash Sensor, a microsystem from SensoNor,
    Norway

The course material was developed in INSIGTH II,
a project sponsored by the Leonardo da Vinci
program of the European Union
2
Definitions
  • MICRO STRUCTURE TECHNOLOGY can be defined as a
    group of three-dimensional micromachining
    techniques enabling feature dimensions with
    accuracy in the micrometer range.
  • MICROMACHINED DEVICES can be defined as devices
    made by Micro Structure Technology.
  • These micromachining techniques are mainly based
    upon batch organised microelectronic process
    technology, either directly adapted techniques
    like photolithographics, or modified techniques
    such as anisotropic etching techniques.
  • Some micromachining techniques are specially
    developed for this field, e.g., anodic bonding of
    micromachined devices.

3
Example SP80 Pressure Sensor
  • Developed at SINTEF (earlier Center for
    Industrial Research), Norway and manufactured by
    Capto as (earlier SensoNor AS, earlier ame),
    Borre, Norway.
  • This sensor visualises the main features and
    limitations of micromechanical sensors, and
    points out pressure sensing as a main application
    for these kinds of sensors.

4
SP80 Principal Design
  • A piezoresistive integrated pressure sensor with
    the pressure-sensitive diaphragm micromachined in
    a silicon chip by anisotropic etching.
  • Ion implanted piezoresistors in a full Wheatstone
    bridge configuration as the electronic sensing
    element.
  • Temperature measuring resistor and a heating
    resistor are implanted on the same chip, to
    compensate or thermostat the chip to minimise
    thermal drifts.
  • By varying the area and the thickness of the
    diaphragm, pressure ranges from 0.5 Bar full
    scale pressure up to 60 Bar full scale pressure
    can be achieved
  • Packaged in a transistor header
  • Main application areas are within general
    instrumentation, metrology and aerospace
    application.

5
The SP80 Silicon Chip Set - Drawing
  • Consists of diaphragm chip sealed to a support
    chip which is mounted on top of a glass tubing
    acting as a mounting stand as well as a pressure
    port.

6
The SP80 Silicon Chip Set - Picture
  • Consists of diaphragm chip sealed to a support
    chip which is mounted on top of a glass tubing
    acting as a mounting stand as well as a pressure
    port.

7
Dimensions and Processing
  • The size is 44 mm, thickness approximately 0.3
    mm, the diaphragm area is typical 22 mm and the
    diaphragm thickness is typical 30 micrometers.
  • The diaphragm is manufactured by stripping off
    the surface oxide of the silicon wafer by means
    photolithographic technique in the areas we want
    the diaphragm cavity.
  • Then the wafer is etched in an anisotropic
    etching solution with the remaining oxide as
    masking film.
  • This etching solution attacks the single crystal
    silicon with different speed in the different
    crystal directions.
  • The etch is extremely slow in the lt1-1-1gt
    direction The etch is therefore stopped towards
    the (1-1-1) planes.
  • The chip material is (1-0-0) silicon
  • Therefore, the etch cavity is surrounded by four
    (1-1-1) planes which have an angle of inclination
    of 54.7 degrees relative to the (1-0-0) surface
    plane, rendering a cavity with four sloped walls.

8
SP80 Package
  • Cross-sectioned view of the SP80 Pressure Sensor
    packaged in a transistor header.

9
SP80 Package, continued
  • Cross-sectioned view of the SP80 Pressure Sensor
    packaged in a transistor header with a top chip
    containing a vacuum reference chamber.

10
SP80 Schematic
  • The SP80 schematic consists of 4 ion implanted
    piezoresistors in a full Wheatstone bridge
    configuration as the electronic sensing element.
    In addition, a temperature measuring resistor and
    a heating resistor are implanted on the same
    chip, to compensate or thermostat the chip to
    minimise thermal drifts.

11
Picture of SP80 in Transistor Package
  • Comment The Norwegian coin is approximately the
    size of Ø10 mm

12
Main Features of SP80
  • Low non-linearity ( lt - 0.1 )
  • Negligible hysteresis ( lt - 0.005 of full scale
    output )
  • Low long term drift ( typical less than 0.1 per
    year )
  • Active thermal compensation by utilising the
    on-the-chip heating resistor.
  • Small size.

13
Drawbacks of SP80
  • Reference pressure medium must be non-conducting
    and non-corrosive to be compatible with the
    on-chip sensing elements and electronics.
  • Safe overload is limited to 3 times rated
    pressure as no mechanical overload stop is
    implemented.
  • The devices have no normalised output signal.
    Each device has to be individually calibrated
    when system installed.
  • Temperature range is limited (-55 - 125 C) and
    uncompensated thermal sensitivity drift is
    relative high ( -0.2/C).

14
Applications for Micromachined Sensors and
Microsystems
  • The biomedical market
  • Blood pressure sensors
  • The space, defence and avionics markets
  • Accelerometers for rocket navigation
  • Micro gravity sensor
  • Gyroscopes for navigation
  • The agriculture electronics market
  • Automotive sensors used in tractors, harvesters
    etc.
  • The off-shore oil exploitation market
  • High pressure measurement in oil wells
  • Sea wave sensor
  • The automotive market
  • Acceleration microsystems for air bag systems
  • Tire pressure microsystems
  • The data and peripheral market
  • Disk drive write and read heads
  • The consumer market
  • Photo diodes in cameras
  • Level measurement in white goods appliances.

15
Top10 Success Factors
  • 1. Batch organised processing technology
  • 2. Microelectronics manufacturing infrastructure
  • 3. Research results from solid state technology
    and other related fields of microelectronics
  • 4. Micromachining
  • 5. Wafer and chip bonding
  • 6. Mechanical material characteristics
  • 7. Sensor effects
  • 8. Actuator functions
  • 9. Integrated electronics
  • 10. Combination of features

16
Bottom10 Limiting Factors
  • 1. Slow market acceptance
  • 2. Low production volumes
  • 3. Immature industrial infrastructure
  • 4. Poor reliability
  • 5. Complex designs and processes
  • 6. Immature processing technology
  • 7. Immature packaging and interconnection
    technologies
  • 8. Limited research resources
  • 9. Limited human resources
  • 10. High costs

17
Milestones in the Planar Silicon Processing
Technology (and some other related breakthroughs)
  • 1890 Punched cards invented
  • 1939 Vacuum tubes and mechanical computing
  • 1948 The invention of the transistor
  • 1959 The invention of the planar silicon
    processing
  • 1959 The invention of the integrated circuit
  • 1964 Mainframe computing
  • 1971 The invention of the microprocessor
  • 1981 introduction of personal computers
  • 1985 1 Megabit random-access-memory chips
    available
  • 1991 64 Megabit random-access-memory chips
    available
  • 1994 Internet in widespread use
  • 1994 256 Megabit random-access-memory chips
    available
  • 1995 Microprocessors with more than 3 million
    transistors available
  • 2000 Microprocessors with more than 100 million
    transistors available
  • 2005 1 Gigabit random-access-memory chips
    available
  • 2006 Digital consumerisation (Video on mobile
    phones etc)
  • 2007 The Intel Itanium microprocessor with 1.2
    billions transistors.
  • 2008 4 Gigabit random-access-memory chips
    available

18
Manufacturers of Micromechanical Devices
  • The industry structure is highly diversified both
    in size, technological basis and organisation
    type.
  • Traditional sensor manufacturers have seen
    micromechanical sensors as a natural expansion of
    their technological basis, and have taken up
    research and production of these sensors as a
    part of their activity.
  • Semiconductor companies have entered this market
    as an expansion of their integrated circuit
    activity, since they already have most of the
    needed equipment and the appropriate marketing
    channels.
  • System companies or original equipment
    manufacturers which see micromechanical devices
    as a way to boost their systems.
  • "Start ups", companies having micromechanical
    devices as their main business idea.
  • There are of course companies that does not fit
    into any of these types and some are someplace in
    between these types.

19
Manufacturers
  • USA
  • Honeywell, Microswitch, SenSym, IC Sensors,
    Motorola, Delco, Foxboro/ICT, Endevco, Kulite,
    Lucas/NovaSensor, Michigan Microsensors
  • Japan
  • Hitachi, Toshiba, NEC, Yokagawa Hokushin, Toyota
    Motor Company
  • Europe
  • Germany Infineon, Bosch,
  • The Netherlands Philips, Microtel, Xensor
    Integration
  • UK Druck
  • Switzerland Keller, Kistler
  • Finland Vaisala
  • Sweden Radi Medical Systems
  • Norway SensoNor

20
Research Centers
  • USA
  • Stanford University, Case Western Reserve
    University, University of Michigan, University of
    California at Berkeley, University of Wisconsin,
    MIT
  • Japan
  • Tohoku University, Kyoto University, Fudan
    University,
  • Europe
  • The Netherlands Delft University, Twente
    University
  • Belgium IMEC, Catholic Un of Leuven
  • Switzerland University of Neuchâtel, CSEM
  • Germany Fraunhofer Institute, IFT Munich,
    Fraunhofer Institute, IMT Itzehoe, Techn. Un of
    Berlin
  • Denmark Techn. Un of Denmark
  • Finland VTT
  • Sweden Uppsala University, KTH/Acreo
  • Norway SINTEF

21
Batch Processes Adapted from Microelectronics/IC
Technology with no or Minor Modifications  
  • Photolithography
  • Spin coating
  • Etching techniques
  • Diffusion of dopants
  • Implantation
  • Epitaxy
  • Chemical vapour deposition (CVD)
  • Thin film technology
  • Thick film technology

22
Batch Processes Modified from Microelectronics/IC
Technology Processes
  • Double-sided photolithography
  • Wafer fusion bonding
  • LIGA and LIGA-like techniques
  • Laser micromachining  

23
Batch Processes Adapted or Modified from Other
Technologies than Microelectronics/IC Technology
  • Micro stereo lithography
  • Micro electro discharge machining

24
Batch Processes Mainly Developed for
Micromachined Devices
  • Bulk micromachining
  • Surface micromachining
  • Anodic wafer bonding
  • Fusion bonding (Direct bonding)These
    technologies will be commented on the following
    slides

25
Bulk Micromachining in Silicon
  • Bulk Micromachining in Silicon is here defined as
    three-dimensional micromachining in single
    crystal silicon by means of photolithographic
    etching techniques.
  • It is also called Bulk Micromechanics in Silicon
    or Silicon Micromachining
  • To understand this technology, some basic insight
    in single crystal silicon is needed

26
Crystal Structure of Single Crystal Silicon
  • It is a face-centered cubic structure (diamond
    structure) with two atoms associated with each
    lattice point of the unit cube. One atom is
    located in position with xyz coordinates (0, 0,
    0), the other in position (a/4, a/4, a/4), a
    being the basic unit cell length.

27
Miller Indices for a Plane in a Crystal
  • The orientation of of different crystal planes in
    the basic unit cell can be described by the
    Miller indices (hkl) between parentheses with
    each plane defined by a vector description (hx
    ky lz) of the direction perpendicular to that
    plane. This is related to a coordinate system
    oriented in parallel with the side edges of the
    basic cell, with the Miller indices reduced to
    the smallest possible integers with the same
    ratio.

28
Important Crystal Planes in the Silicon Crystal
  • (100), (110) and (111) are the three most
    important crystal planes of the silicon crystal
    structure.

29
Silicon as a Mechanical Material
30
Silicon as an Electronic Material
31
Principles of Micromachining in Silicon
  • Micromechanics in silicon is here defined as
    three-dimensional micromachining in single
    crystal silicon by means of photolithographic
    etching techniques.
  • This definition covers most techniques used to
    make micromechanical sensors, although in some
    cases additive structures such as polysilicon and
    silicon dioxide also have been micromachined by
    selective etching techniques, and in some cases
    mechanical drilling or other machining methods
    are used.

32
Wet Chemical Etching of Silicon using Alkaline
Etchants
  • The fundamental reactions are electrochemical in
    nature.
  • Holes are injected from the etching solution into
    the silicon and Si-atoms are ionized to Si.
  • Hydroxyl (OH-) from the etching solution reacts
    with Si to hydrated silicon.
  • Hydrated silicon reacts with a complexing agent
    in the etching solution to form a soluble
    reaction product.
  • The soluble reaction product is dissolved into
    the etching solution and carried away from the
    etching site on the silicon surface into the
    solution.
  • All in all, silicon is etched and the reactant
    products are diluted into the etching solution.

33
Isotropic Etching of Silicon
  • Typical wet isotropic silicon etches are either
    organic or inorganic acids such as acetic acid
    (CH3COOH) or hydrogenfluorid (HF) or mixtures
    together with water. Often a complexing agent is
    needed transforming the oxidized product into
    soluble species.
  • By using selective etching techniques in
    combination with etching time some sort of
    dimensional control of the etched structure can
    be obtained. By using spray etching, agitation or
    light enhanced etching preferred etching
    directions can be obtained.
  •  Generally, dimensional accuracy below
    approximately 30 µmeters are very hard to
    achieve, making wet isotropic etching a less
    favourable and less used method for
    micromechanics in silicon compared to anisotropic
    etching.

34
Isotropic Etching of Silicon
  • This table shows some popular isotropic etches

35
A Typical Isotropic Etch Cavity
  • Isotropic etch cavity in a silicon chip with a
    square masking film opening. The result is an
    underetched etch pit with rounded structures.

36
Anisotropic Etching of Silicon
  • An anisotropic etching solution or orientation
    -dependent etching solution will attack the
    various crystal directions in single crystal
    silicon with different speed. Orientation effects
    during this type of preferential etch have been
    attributed to crystallographic properties. One
    explanation is that the atomic bonds in some
    planes are more exposed than in some others. A
    suitable designed etching agent will thus attack
    and strip away certain plane orientations more
    quickly than others.
  • Typical wet anisotropic silicon etches are
    organic or inorganic alkaline solutions used at
    elevated temperatures, such as a mixture of
    ethylene diamine, pyrocatechol and water
    (EDP-etch) or potassium hydroxide and water
    (KOH-etch), or tetra-methyl-ammonium-hydroxide
    (TMAH).. Hydrazine-water mixture are also popular
    anisotropic silicon etchants. In the following
    table some examples of anisotropic etchants are
    given, including appropriate masking films.
  • These typical anisotropic etching solutions are
    all characterized by an extremely slow etching
    speed in the lt111gt directions of single crystal
    silicon, as shown in the example given in the
    following figure.

37
Anisotropic Etching of Silicon
38
Anisotropic Lateral Etch Rate
  • Lateral etch rate as a function of crystal
    direction on (110) silicon wafers for an
    EDP-etch.
  • The composition of the etchant was 1l
    ethylene-diamine, 133 ml water, 160 gram
    pyrocatechol and 6 gram pyrazine.
  • The dashed (111) directions are all equivalent
    with the (111) direction in single crystal
    silicon.

80 micrometer/hour is around 1.3 micrometer/min
39
Anisotropic Etch Cavity in (100) Silicon
  • Anisotropic etch cavity in (100) silicon with a
    square masking film opening oriented in parallel
    with the lt110gt direction. Due to the four-fold
    symmetry of the slow-etching (111) planes,
    sideways etching is stopped giving a cavity with
    four sloped sidewalls. The photography shows such
    an etched cavity.

40
Understanding Anisotropic Underetching
  • Anisotropic underetching of mask openings
    nonparallel with lt110gt direction, and anisotropic
    underetching of convex corners.
  • (a) is a typical pyramidal pit, bounded by the
    (111) planes, etched into silicon with an
    anisotropic etch through a square hole in an
    oxide mask.
  • (b) is a type of pit which is expected from
    anisotropic etch with a slow convex undercut
    rate.
  • (c) is the same mask pattern resulting in an
    substantial degree of undercutting using an
    etchant with a fast undercut rate such as EDP.
  • In (d), further etching of (c) produces a
    cantilever beam suspended over the pit.
  • (e) is an illustration of the general rule for
    anisotropic etch undercutting assuming a
    "sufficiently long" etching time. The reader who
    understands (e) has understood the main
    principles.

41
Selective Etching of Silicon
  • There are four different techniques in use
  • Calculate the needed etching time on the basis of
    the etching speed of the used etch. This is an
    easy, but inaccurate method, as etching speed
    varies with the chemical condition of the etch
    and upon geometrical factors limiting the
    agitation of the etch. Typical accuracy 20
    micrometer.
  • Inspect etch cavity depth in appropriate time
    intervals until needed depth is reached. More
    time consuming than the above method, but
    improved accuracy. Uneven etching depth from
    cavity to cavity due to chemical and geometrical
    factor is still a problem limiting accuracy,
    which is typical 10 micrometer.
  • Chemical selective techniques stopping the etch
    when an impurity doped chemical resistive layer
    is reached. Accuracy is typical 3 micrometer.
  • Electrochemical selective techniques stopping the
    etch towards a biased p-n junction. This enhances
    passivation very effectively, giving a typical
    accuracy of 1 micrometer.

42
Chemical Selective Etching of Silicon
  • Chemical selective etching with EPD-etch as a
    function of boron doping concentration. The boron
    stop layer can be made by diffusion deposition or
    implantation on the opposite side of the wafer
    compared to the etch cavity, which are both well
    known processing techniques.

43
Epitaxial Layer Atop Boron Doped Stop Layer
n-type epitaxial layer
p type boron stop layer
n-type substrate
  • The shortcoming of not being able to integrate
    electronics in the boron stop layer can be
    avoided by depositing an epitaxial layer atop the
    stop layer, with doping appropriate as substrate
    material for integrated devices.

44
A Typical Etching Dewar for Wet Chemical Etching
of Silicon
45
Electrochemical Selective Etching of Silicon
  • Low-doped material can be passivated, both p-type
    and n-type. This gives more processing
    flexibility, and low-doped silicon can be used as
    substrate material for integrated components such
    as piezoresistors.
  • High accuracy of thickness of unetched layer can
    be achieved, typical 1micrometer, by using
    well-controlled implantation and diffusion
    techniques for making the p-n- junction.
  • This method makes KOH a useful selective etch,
    avoiding the health dangers of EDP-etch.

46
Surface Micromachining
  • Surface micromachining can be defined as a set of
    methods to make three-dimensional surface
    structures, with deposition of thin films as
    additive technique and selective etching of the
    deposited thin films as subtractive techniques.
  • In practice, single crystal silicon wafer is the
    dominant substrate material, and chemical vapor
    deposited (CVD) polysilicon is mostly used as the
    material making up the three-dimensional surface
    structures.

47
Surface Micromachining, continued
  • A main advantage, compared to bulk
    micromachining, is that it does not need double
    sided processing (back side processing) of the
    wafers.
  • The main additive deposition techniques are
    evaporation, sputtering, chemical vapor
    deposition (CVD), and variants of these.
  • The main subtractive methods are selective wet
    etching and dry plasma etching.
  • Photolitography is used for pattern definition.
  • The use of sacrificial layers is important. With
    this method, etching of the sacrificial layers
    underneath non-etched thin film structures can be
    done. In this way several three-dimensional
    surface structures can be made, such as cavities,
    supported microbeams, microstrings, diaphragms,
    lateral mobile microelements etc.

48
Micrograph of a Surface Micromachined Structure
  • Lateral mobile polysilicon microwheels on a
    silicon substrate fabricated by surface
    micromachining. Each wheels is free to rotate
    around its axis at the center of the stud
    element, which is fixed against the substrate and
    thus keeps the wheel in place. The wheels have
    gear teeth to show a possible gear function. 

49
Process Sequence
  • The process sequence for fabricating laterally
    mobile elements, such as the microwheel shown in
    Photo XIII.2, is schematically depicted in Figure
    XIII.12.
  • First (a), an oxide film is grown on the silicon
    wafer.
  • Then (b), a polycrystalline film is deposited by
    chemical vapor deposition (CVD), and openings are
    defined and etched out using standard
    photolithography (c).
  • A second oxide layer is deposited by CVD (d), an
    opening in the oxide is etched using a second
    lithographic mask, and a second polysilicon film
    is deposited and patterned with a third mask (e).
  • Finally (f), the sacrificial oxide layers are
    removed by selective etching in hydrofluoric acid
    (HF), leaving the first polysilicon film free to
    move laterally, and the second polysilicon film
    as a supporting element fixed to the substrate. 

50
Process Sequence Diagram
  • Figure XIII.12 Process sequence for the
    fabrication of laterally mobile structures using
    surface micromachining and sacrificial layer
    technique.

51
Examples of Sensor Elements Using Surface
Micromachining
  • Sensor elements can be made by surface
    micromachining by either using thin films with
    sensing effects, such zinc oxide ZnO with
    piezoelectric field, or using mechanical sensing
    properties such as variable air gap elements
    and/or vibrating structures.
  • An example of such a sensor, the Berkeley
    Polysilicon Microbridge Integrated Vapor Sensor.
    This sensor has a surface micromachined
    polysilicon microbridge. This sensor uses the
    vibrating structure sensing principle, with
    vibration activation and vibrating sensing by
    means of the capacitance between the bridge and
    the substrate. (Coulomb force activation and
    capacitance change sensing)

52
Anodic Wafer Bonding
  • Can be defined as a method of electrostatically
    bonding two dissimilar materials together to form
    a strong, hermetic seal that involves little
    alteration in the shape, size, and dimensions of
    the members making up the joint.
  • It is a high yield wafer-to-wafer sealing method
    that makes it possible to obtain hermetic seals.
    The technique was first developed for
    silicon-to-glass anodic wafer bonding, and has
    later been further developed to
    silicon-to-silicon anodic wafer bonding and
    silicon-to-thin film anodic wafer bonding.

53
Anodic Wafer Bonding Schematic View
  • Schematic view of silicon-to-silicon anodic
    bonding and silicon-to-glass anodic bonding.

54
Example Digital Micromirror Device (DMD) from
Texas Instruments
  • The device is using very advanced surface
    micromachining of thin Al alloys on Si substrates
    containing CMOS drive electronics

55
Picture of the packaged DMDs
  • The DMDs are pixel devices
  • Here are the VGA (640x480), the SVGA (800x600)
    and the XGA (1024x768) devices shown

56
Principle of Operation for the DMD
  • The hinge system of each pixel structure enables
    electronic control mirror position.

57
Picture of Digital Micromirror Device
  • The device is packaged in an elastomer connect
    package with a glass window. Here shown mounted
    on a PCB with back end drive electronics

58
The Davis DPX 16 Projector using the TI Digital
Micromirror Device
  • XGA resolution (1024 x 768 pixels)
  • 2.3 kg weight
  • 1000 Lumens brightness

59
The Zeiss Optical Engine for the DP X16 Projector
  • Advanced optics
  • Small size and low weight

60
The Zeiss Optical Engine for the DP X16
Projector Modelling
  • Mechanical modelling using ProEngineer Design
    Tools

61
Example The SA30 Crash Sensor from SensoNor
  • This is a good example of the features of
    microsystems please refer to the separate slide
    presentation
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