CHAPTER 13 Fabrication of Microelectronic and Micromechanical Devices
Pentium Processor FIGURE 13.1 (a) A completed eight-inch wafer with completed dice. (b) A single chip in a dual in-line package (DIP) with cover removed. (c) A printed circuit board. Source: Courtesy Intel Corporation.
Fabrication of Semiconductor FIGURE 13.2 Cross-sectional views of the fabrication of a metal oxide semiconductor. Source: R. C. Jaeger.
Fabrication Sequence for Integrated Circuits FIGURE 13.3 General fabrication sequence for integrated circuits.
Crystallographic Structure of Silicon FIGURE 13.4 Crystallographic structure and Miller indices for silicon. (a) Construction of a diamond-type lattice from interpenetrating face-centered cubic cells (one of eight penetrating cells shown). (b) The diamond-type lattice of silicon. The interior atoms have been shaded darker than the surface atoms. (c) The Miller indices for a cubic lattice.
Single-Crystal Wafers of Silicon FIGURE 13.5 Identification of single-crystal wafers of silicon.
CVD Reactors FIGURE 13.6 Schematic diagrams of (a) a continuous, atmospheric-pressure CVD reactor and (b) a low-pressure CVD reactor. Source: S.M. Sze. (c) Apparatus for ion implantation. Source: J.A. Schey.
Growth of Silicon Dioxide FIGURE 13.7 Growth of silicon dioxide, showing consumption of silicon. Source: S.M. Sze.
Lithography Techniques TABLE 13.1 General characteristics of lithography techniques.
Pattern Transfer by Lithography FIGURE 13.8 Pattern transfer by lithography. Note that the mask in Step 3 can be either a positive or a negative image of the pattern. Source: After W. C. Till and J. T. Luxon.
Etching Directionality FIGURE 13.10 Etching directionality. (a) Isotropic etching: Etch proceeds vertically and horizontally at approximately the same rate, with significant mask undercut. (b) Orientation-dependant etching (ODE): Etch proceeds vertically, terminating on {111} crystal planes with little mask undercut. (c) Vertical etching: etch proceeds vertically with little mask undercut. Source: Courtesy of K. R. Williams, Agilent Laboratories.
Etch Rates of Silicon FIGURE 13.11 Etch rates of silicon in different crystallographic orientations, using ethylene-diamine/pyrocatechol-in-water as the solution. Source: After H. Seidel et al., J. Electrochemical Society, 1990, pp. 3612-3626.
Membrane and Orifice Formation FIGURE 13.12 Application of a boron etch stop and back etching to form a membrane and orifice. Source: After Il Brodie and J. J. Murray, The Physics of Microfabrication, Plenum Press, 1982.
Machining Profiles FIGURE 13.14 Machining profiles associated with different dry-etching techniques: (a) sputtering; (b) chemical; (c) ion-enhanced energetic; (d) ion-enhanced inhibitor. Source: After M. Madou.
Reactive Plasma Etching FIGURE 13.15 (a) Schematic illustration of reactive plasma etching. (b) Example of deep reactive ion etched trench. Note the periodic undercuts, or scalloping. (c) Near vertical sidewalls produced through DRIE with an anisotropic etching process. (d) An example of cryogenic dry etching, showing a145µm deep structure etched into Si using a 2.0µm thick oxide masking layer. The substrated temperature was -140˚C during etching. Source: (a) AfterM. Madou. (b)-(d) R. Kassing and I. W. Rangelow, University of Kassel.
Holes Generated From a Square Mask FIGURE 13.16 Different holes generated from a square mask in (a) isotropic (wet) etching; (b) ODE with a larger hole; (d) ODE of a rectangular hole; (e) deep reactive ion etching; (f) vertical etching. Source: After M. Madou.
Two-Level Metal Interconnect FIGURE 13.17 (a) Scanning electron microscope photograph of a two-level metal interconnect. Note the varying surface topography. (b) Schematic drawing of a two-level metal interconnect structure. Source: R.C. Jaeger.
Defect Probe FIGURE 13.18 A probe checks for defects, and an ink mark is placed on defective dice. Source: Intel Corp.
Wire Bonds Connecting Package Leads FIGURE 13.19 (a) SEM photograph of wire bonds connecting package leads (left-hand side) to die bonding pads. (b) and (c) Detailed views of (a). Source: Courtesy of Micron Technology, Inc.
IC Packages FIGURE 13.21 Schematic illustration of different IC Packages: (a) dual in-line (DIP); (b) ceramic flat pack; (c) common surface-mount configurations; (d) ball-grid array (BGA). Source: After R.C. Jaeger, A.B. Glaser, and G. E. Subak-Sharpe.
Flip-Chip Technology FIGURE 13.22 Illustration of flip-chip technology. (a) Flip-chip package with solder plated metal balls and pads on the printed circuit board; (b) flux application and placement; (c) reflow soldering; (d) encapsulation. Source: Paul Wright, 21st Century Manufacturing, Upper Saddle River, NJ: Prentice Hall, 2001.
Circuit Board Structures FIGURE 13.23 Types of circuit board structures: (a) single sided; (b) double sided; (c) multilayer, showing vias and pathways between layers. Source: M. Groover, Fundamentals of Modern Manufacturing. Upper Saddle River, NJ: Prentice Hall, 1996.
Design Features of Circuit Boards FIGURE 13.24 Design features in printed circuit boards. Source: M. Groover, Fundamentals of Modern Manufacturing, Upper Saddle River, NJ: Prentice Hall, 1996.
Layout of IC Packages on Circuit Boards FIGURE 13.25 Layout of IC packages and other components on circuit boards to facilitate wave soldering. Source: After G, Boothroyd, P. Dewhurst, and W. Knight, Product Design for Manufacture and Assembly, Marcel-Dekker, 1994.
Bulk Micromachining FIGURE 13.27 Schematic illustration of bulk micromachining. (a) Diffuse dopant in desired pattern . (b) Deposit and pattern masking film. (c) Orientation-dependent etch, leaving behind a freestanding structure. Source: K.R. Williams, Agilent Laboratories.
Steps in Surface Microma-chining FIGURE 13.28 Schematic illustration of the steps in surface micromachining: (a) deposition of a phosphosilicate glass (PSG) spacer later; (b) etching of the spacer layer; (C) deposition of polysilicon; (d) etching of polysilicon; (e) selective wet etching of PSG, leaving the silicon substrate and deposited polysilicon unaffected.
Microlamp FIGURE 13.29 A microclamp produced form a combination of bulk and surface micromachining. Source: K.R. Williams, Agilent Technologies.
Deployed Micromirror FIGURE 13.31 (a) SEM image of deployed micromirror. (b) Detail of the micromirror hinge. Source: Sandia National Laboratories.
Hinge Manufacture FIGURE 13.32 Schematic illustration of the steps required to manufacture a hinge. (a) Deposition of a phosphosilicate glass (PSG) spacer later and polysilicon layer. (See Fig. 13.28.) (b) Deposition of a second spacer layer. (c) Selective etching of the PSG. (d) Depostion of polysilicon to form a staple for the hinge. (e) After selective wet etching of the PSG, the hinge can rotate.
Thermal Ink-Jet Printer Operation Sequence FIGURE 13.36 Sequence of operation of a thermal ink-jet printer. (a) Resistive heating element is turned on , rapidly vaporizing ink and forming a bubble. (b) Within five microseconds, the bubble has expanded and displaced liquid ink from the nozzle. (c) Surface tension breaks the ink stream in to a bubble, which is discharged at high velocity. The heating element is turned off at this time, so that the bubble collapses as heat is transferred to the surrounding ink. (d) within 24 microseconds, and ink droplet (and undesirable satellite droplets) are ejected, and surface tension of the ink draws more liquid form the reservoir. Source: From F. G. Tseng, “Microdroplet Generators,” in M. Gad-el-hak (ed.), The MEMS Handbook, CRC Press, 2002.
Sequence for Producing Thermal Ink-Jet Printer Heads FIGURE 13.37 The manufacturing sequence for producing thermal ink-jet printer heads. Source: From F. G. Tseng, “Microdroplet Generators,” in M. Gad-el-hak (ed.), The MEMS Handbook, CRC Press, 2002.
Electroformed Nickel Structures FIGURE 13.39 (a) Electroformed 200-µm-tall nickel structures. (b) Detail of 5-µm-wide nickel lines and spaces. Source: After Todd Christenson, The MEMS Handbook, CRC Press, 2002.
Multilevel Fabrication Through Diffusion Bonding FIGURE 13.42 (a) Multilevel MEMS fabrication through wafer-scale diffusion bonding. (b) A suspended ring structure for measurement of tensile strain, formed by two-layer wafer-scale diffusion bonding. Source: After T. Christenson, Sandia National Laboratories.
Micro-Acceleration Sensor FIGURE 13.44 Schematic illustration of a micro-acceleration sensor. Source: After N. Maluf.