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Lecture 19 mems metrology

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Metrology is the science of measurement and its application. It is essential for characterizing microsystems and structures below what can be perceived with the naked eye. Key metrology tools for microscale include optical microscopy, scanning electron microscopy, atomic force microscopy, interferometry, and ellipsometry. These tools allow measuring parameters like length, thickness, roughness, composition, and defects at micro- and nanoscales. Statistical analysis is also important in metrology for understanding measurement uncertainties and variations.

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MEMS Metrology Dr. Bruce K. Gale Fundamentals of Micromachining Metrology What is metrology? It is the science of weights and measures Refers primarily to the measurements of length, wetight, time, etc. Mensuration- A branch of applied geometry It measure the area and volume of solids from lengths and angles It also includes other engineering measurements for the establishment of a flat, plane reference surface What is a Measurement A measurement is an act of assigning a specific value to a physical variable The physical variable becomes the measured variable Measurements provide a basis for judgements about Process information Quality assurance Process control Measurable Parameters What do we want to measure? Length or distance Mass Temperature Elemental composition Viscosity Diplacements or distortions Time Pressure Forces Stress Strain Friction Resistance Roughness Depth Intensity etc.
Measurement Systems and Tools Measurement systems are important tools for the quantification of the physical variable Measurement systems extend the abilities of the human senses, while they can detect and recognize different degrees of physical variables For scientific and engineering measurement, the selection of equipment, techniques and interpretation of the measured data are important Components of a Measuring System Importance of Metrology In human relationships, things must be counted and measured Metrology is an absolute necessity for human development This necessity increased greatly with the advent of the industrial age As society develops further, metrology must also be refined further How Important are Measurements? Measurement is the language of science It helps us communicate about size, quantity, position, condition, time, etc. Simple measurement errors can cost a company a contract, work, jobs, and lots of money Three areas to which the basic principles of measurement can be applied Communication of the measurement Act and application of the measurement Codification of the measurement
Human Interaction in Measurements Almost always require the use of vision Other senses not always good at measurement Measurements usually require tools They rely on the visual process What happens if object is too small to perceive? At what size do things become to small to measure? Handling and/or perception problems Limits of vision/ perception without aid or assistance What is Microsystem Metrology Measurement of physical dimensions of microsystems or structures that are at the dimension scale below our ability to perceive without the help of measurements systems or instruments Microsystems: IC, MEMS Microstructures: Line widths, film thickness, surface struture and roughness, step heights, particle size, atomic composition, defect inspections, etc Nanosystem metrology is emerging now! Where Metrology at the Micro Level is Used Precision engineering and measurements Micron and nano manufacturing Research and development Calibration of instruments and standards MEMS Measurement Statistics and probability Statistical process control Optical microscopy Scanning electron microscopy (SEM) Atomic force microscopy (AFM) Scanning tunneling microscopy (STM) Near- field microscopy Laser/ White light interferometry Video Microscopy Surface Profiler Roughness Tester Ellipsometry
Statistics and Probability Statistical terms and definitions Infinite statistics Finite statistics Standard deviations Probability density functions Confidence intervals Uncertainty analysis Error sources Bias and precision errors Error propagation Regression analysis Least squares methods Linear polynomials Students t-Test Single and multiple measurement errors Zero and higher order uncertainties Correlation coefficient Statistical Process Control Concept of variation Importance of SPC in production processes Controlled and uncontrolled variation Common and special causes Control charts Statistical inference Running records Population parameters Control limits Subgroup average and range Three sigma limits Six now! Optical Microscopy Light propagation and Snells law Mirrors, prisms, lenses and beam splitters Image formation, interference and diffraction Simple and compound microscopes Mirror and thin lens equations Resolving power and resolution Aberrations and corrections Depth of field and focus Measurement on the optical microscopic scale Numerical Aperture
MEMS Optical Microscopy Problems Scanning Electron Microscopy Used for observation, analysis, and measurement Can produce images over a wide range of magnifications High magnification and great depth of field High resolution (down to 2.5 nm) Can provide morphological, compositional, and physical information 3D appearance of image Greater degree of freedom Near Field Scanning Optical Microscopy Used to get below the limits of far-field diffraction High resolution down to 50 nm NSOM Tip Images using NSOM
SEM Components Electron gun assembly Stable source of primary electrons Electromagnetic lenses and apertures Focus electron beam Vacuum system Allows passage of electrons without interference Electron collector, display, and recorder Specimen stage Goniometer stage SEM Operation Small area irradiated by electrons E-beam can be static or swept Secondary and backscattered electrons detected SEM Operation Current in the focused e-beam determines magnitude of emitted signals Size of focused beam determines the resolution Optical SEM Comparisonof Systems
Transmission Electron Microscopy (TEM) Only for thin materials Usually used to study crystals Gives good information on nanometer structure Atomic Force Microscopy Atomically sharp tip Measures minute atomic forces that cause repulsion Can measure individual atoms AFM Image of Silicon Silicon (111) plane- ridges 0.38 nm high Scanning Tunneling Microscopy
Scanning Tunneling Microscopy Sharp tip Tunneling current or voltage measured Current increases rapidly on approach to surface Atomic resolution Roughness Step Tester (RST) Surface characterization Interference microscope Optical measurement of surface Surface Texture Definition Repetitive or random deviation from nominal surface that forms the 3-D topography of the surface Roughness Closely spaced irregularities Waviness Wider spaced irregularities (tool marks) Form Does not contribute to surface texture Surface Profiler Large tip scans across surface Excellent for measuring height of objects Sidewalls are not accurate Variation dependent on tip diameter Vertical accuracy in angstroms
Ellipsometry Light is rotated as it passes through medium If dielectric constant is known, can be used to measure film thickness Interferometry Reflected light waves interfere with each other Used to measure thickness of thin films or deflections Interference occurs at different locations based on wavelength Thin Films Change Colors CCD Cameras (Video Imaging) Charge Coupled Devices (CCD) Metal - insulator - semiconductor devices (MIS) Incident light generates charge on gate Induced voltage causes charge separation CCD cameras are arrays of MIS devices Can be 10 microns square Charge collected and moved sequentially to edge of device Dyes can be applied to transistor to detect colors

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Lecture 19 mems metrology

  • 1. MEMS Metrology Dr. Bruce K. Gale Fundamentals of Micromachining Metrology What is metrology? It is the science of weights and measures Refers primarily to the measurements of length, wetight, time, etc. Mensuration- A branch of applied geometry It measure the area and volume of solids from lengths and angles It also includes other engineering measurements for the establishment of a flat, plane reference surface What is a Measurement A measurement is an act of assigning a specific value to a physical variable The physical variable becomes the measured variable Measurements provide a basis for judgements about Process information Quality assurance Process control Measurable Parameters What do we want to measure? Length or distance Mass Temperature Elemental composition Viscosity Diplacements or distortions Time Pressure Forces Stress Strain Friction Resistance Roughness Depth Intensity etc.
  • 2. Measurement Systems and Tools Measurement systems are important tools for the quantification of the physical variable Measurement systems extend the abilities of the human senses, while they can detect and recognize different degrees of physical variables For scientific and engineering measurement, the selection of equipment, techniques and interpretation of the measured data are important Components of a Measuring System Importance of Metrology In human relationships, things must be counted and measured Metrology is an absolute necessity for human development This necessity increased greatly with the advent of the industrial age As society develops further, metrology must also be refined further How Important are Measurements? Measurement is the language of science It helps us communicate about size, quantity, position, condition, time, etc. Simple measurement errors can cost a company a contract, work, jobs, and lots of money Three areas to which the basic principles of measurement can be applied Communication of the measurement Act and application of the measurement Codification of the measurement
  • 3. Human Interaction in Measurements Almost always require the use of vision Other senses not always good at measurement Measurements usually require tools They rely on the visual process What happens if object is too small to perceive? At what size do things become to small to measure? Handling and/or perception problems Limits of vision/ perception without aid or assistance What is Microsystem Metrology Measurement of physical dimensions of microsystems or structures that are at the dimension scale below our ability to perceive without the help of measurements systems or instruments Microsystems: IC, MEMS Microstructures: Line widths, film thickness, surface struture and roughness, step heights, particle size, atomic composition, defect inspections, etc Nanosystem metrology is emerging now! Where Metrology at the Micro Level is Used Precision engineering and measurements Micron and nano manufacturing Research and development Calibration of instruments and standards MEMS Measurement Statistics and probability Statistical process control Optical microscopy Scanning electron microscopy (SEM) Atomic force microscopy (AFM) Scanning tunneling microscopy (STM) Near- field microscopy Laser/ White light interferometry Video Microscopy Surface Profiler Roughness Tester Ellipsometry
  • 4. Statistics and Probability Statistical terms and definitions Infinite statistics Finite statistics Standard deviations Probability density functions Confidence intervals Uncertainty analysis Error sources Bias and precision errors Error propagation Regression analysis Least squares methods Linear polynomials Students t-Test Single and multiple measurement errors Zero and higher order uncertainties Correlation coefficient Statistical Process Control Concept of variation Importance of SPC in production processes Controlled and uncontrolled variation Common and special causes Control charts Statistical inference Running records Population parameters Control limits Subgroup average and range Three sigma limits Six now! Optical Microscopy Light propagation and Snells law Mirrors, prisms, lenses and beam splitters Image formation, interference and diffraction Simple and compound microscopes Mirror and thin lens equations Resolving power and resolution Aberrations and corrections Depth of field and focus Measurement on the optical microscopic scale Numerical Aperture
  • 5. MEMS Optical Microscopy Problems Scanning Electron Microscopy Used for observation, analysis, and measurement Can produce images over a wide range of magnifications High magnification and great depth of field High resolution (down to 2.5 nm) Can provide morphological, compositional, and physical information 3D appearance of image Greater degree of freedom Near Field Scanning Optical Microscopy Used to get below the limits of far-field diffraction High resolution down to 50 nm NSOM Tip Images using NSOM
  • 6. SEM Components Electron gun assembly Stable source of primary electrons Electromagnetic lenses and apertures Focus electron beam Vacuum system Allows passage of electrons without interference Electron collector, display, and recorder Specimen stage Goniometer stage SEM Operation Small area irradiated by electrons E-beam can be static or swept Secondary and backscattered electrons detected SEM Operation Current in the focused e-beam determines magnitude of emitted signals Size of focused beam determines the resolution Optical SEM Comparisonof Systems
  • 7. Transmission Electron Microscopy (TEM) Only for thin materials Usually used to study crystals Gives good information on nanometer structure Atomic Force Microscopy Atomically sharp tip Measures minute atomic forces that cause repulsion Can measure individual atoms AFM Image of Silicon Silicon (111) plane- ridges 0.38 nm high Scanning Tunneling Microscopy
  • 8. Scanning Tunneling Microscopy Sharp tip Tunneling current or voltage measured Current increases rapidly on approach to surface Atomic resolution Roughness Step Tester (RST) Surface characterization Interference microscope Optical measurement of surface Surface Texture Definition Repetitive or random deviation from nominal surface that forms the 3-D topography of the surface Roughness Closely spaced irregularities Waviness Wider spaced irregularities (tool marks) Form Does not contribute to surface texture Surface Profiler Large tip scans across surface Excellent for measuring height of objects Sidewalls are not accurate Variation dependent on tip diameter Vertical accuracy in angstroms
  • 9. Ellipsometry Light is rotated as it passes through medium If dielectric constant is known, can be used to measure film thickness Interferometry Reflected light waves interfere with each other Used to measure thickness of thin films or deflections Interference occurs at different locations based on wavelength Thin Films Change Colors CCD Cameras (Video Imaging) Charge Coupled Devices (CCD) Metal - insulator - semiconductor devices (MIS) Incident light generates charge on gate Induced voltage causes charge separation CCD cameras are arrays of MIS devices Can be 10 microns square Charge collected and moved sequentially to edge of device Dyes can be applied to transistor to detect colors