` #:1111
`
`
`
`
`
`
`
`
`EXHIBIT B
`
`
`
`
`
`
`
`
`Case 2:17-cv-04273-JVS-JEM Document 79-2 Filed 06/22/18 Page 2 of 36 Page ID
` #:1112
`
`THIRD
`
`EDITION
`
`Circuit Design, Layout, and Simulation
`
`R. JACOB BAKER
`
`IEEE Series on Microelectronic Systems
`
`@WILEY
`
`+IEEE
`
`IEEE PRESS
`
`
`
`Case 2:17-cv-04273-JVS-JEM Document 79-2 Filed 06/22/18 Page 3 of 36 Page ID
` #:1113
`
`This page intentionally left blank
`
`
`
`Case 2:17-cv-04273-JVS-JEM Document 79-2 Filed 06/22/18 Page 4 of 36 Page ID
` #:1114
`
`Multipliers
`
`Symbol
`T
`
`G
`
`M (MEG in SPICE)
`
`k
`
`m
`
`µ (oru)
`
`11
`
`p
`
`f
`
`a (not used in SPICE)
`
`Value
`1012
`
`109
`106
`101
`10-]
`
`10-6
`
`10 9
`10-12
`
`10-15
`
`10·18
`
`Name
`terra
`
`giga
`
`mega
`
`kilo
`
`milli
`
`micro
`
`nano
`
`pico
`
`femto
`
`atto
`
`Physical Constants
`
`Name
`Vacuum dielectric
`constant
`
`Silicon dielectric
`constant
`Si0 2 dielectric
`constant
`SiN 1 dielectric
`constant
`
`Boltzmann's constant
`
`Electronic charge
`
`Temperature
`
`Thermal voltage
`
`Symbol
`
`i\,
`
`£Si
`
`EOX
`
`£'Ji
`
`k
`q
`
`T
`VT
`
`Value/Units
`8.85 aF/µm
`
`11. 7£0
`
`3.97£0
`
`16£0
`
`1.38 X 10·23 J/K
`I.6 X 10·19 C
`Kelvin
`kT!q = 26 mV @300K
`
`
`
`Case 2:17-cv-04273-JVS-JEM Document 79-2 Filed 06/22/18 Page 5 of 36 Page ID
` #:1115
`
`CMOS
`
`
`
`Case 2:17-cv-04273-JVS-JEM Document 79-2 Filed 06/22/18 Page 6 of 36 Page ID
` #:1116
`
`IEEE Press
`445 Hoes Lane
`Piscataway, NJ 08854
`
`IEEE Press Editorial Board
`Lajos Hanzo, Editor in Chief
`
`R. Abari
`J. Anderson
`F. Canavero
`T. G. Croda
`
`M. EI-Hawary
`B. M. Hammerli
`M. Lanzerotti
`0. Malik
`
`S. Nahavandi
`W. Reeve
`T. Samad
`G. Zobrist
`
`Kenneth Moore, Director of IEEE Book and Information Services (BIS)
`
`IEEE Solid-State Circuits Society, Sponsor
`
`
`
`Case 2:17-cv-04273-JVS-JEM Document 79-2 Filed 06/22/18 Page 7 of 36 Page ID
` #:1117
`
`CMOS
`Circuit Design, Layout, and Simulation
`
`Third Edition
`
`R. Jacob Baker
`
`IEEE Press Series on Microelectronic Systems
`
`Stuart K. Tewksbury and Joe E. Brewer, Series Editors
`
`+IEEE
`
`IEEE PRESS
`
`~WILEY
`
`A JOHN WILEY & SONS, INC., PUBLICATION
`
`
`
`Case 2:17-cv-04273-JVS-JEM Document 79-2 Filed 06/22/18 Page 8 of 36 Page ID
` #:1118
`
`Copyright © 2010 by the Institute of Electrical and Electronics Engineers, Inc. All rights reserved.
`
`Published by John Wiley & Sons, Inc., Hoboken, New Jersey.
`Published simultaneously in Canada.
`
`No part of this publication may be reproduced, stored in a retrieval system, or transmitted in any form or
`by any means, electronic, mechanical, photocopying, recording, scanning, or otherwise, except as
`permitted under Section 107 or 108 of the 1976 United States Copyright Act, without either the prior
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`the Copyright Clearance Center, Inc., 222 Rosewood Drive, Danvers, MA 01923, (978) 750-8400, fax
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`be addressed to the Permissions Department, John Wiley & Sons, Inc., 111 River Street, Hoboken, NJ
`07030, (201) 748-6011, fax (201) 748-6008, or online at http://www.wiley.com/go/permission.
`
`Limit of Liability/Disclaimer of Warranty: While the publisher and author have used their best efforts in
`preparing this book, they make no representations or warranties with respect to the accuracy or
`completeness of the contents of this book and specifically disclaim any implied warranties of
`merchantability or fitness for a particular purpose. No warranty may be created or extended by sales
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`
`Library of Congress Cataloging-in-Publication Data:
`
`3rd ed.
`
`Baker, R. Jacob, 1964-
`CMOS : circuit design, layout, and simulation I Jake Baker. -
`p. cm.
`Summary: "The third edition of CMOS: Circuit Design, Layout, and Simulation continues to cover the
`practical design of both analog and digital integrated circuits, offering a vital, contemporary view of a
`wide range of analog/digital circuit blocks, the BSIM model, data converter architectures, and much
`more. The 3rd edition completes the revised 2nd edition by adding one more chapter (chapter 30) at the
`end, which describes on implementing the data converter topologies discussed in Chapter 29. This addi(cid:173)
`tional, practical information should make the book even more useful as an academic text and companion
`for the working design engineer.
`Images, data presented throughout the book were updated, and more
`practical examples, problems are presented in this new edition to enhance the practicality of the book"(cid:173)
`Provided by publisher.
`Summary: "The third edition of CMOS: Circuit Design, Layout, and Simulation continues to cover the
`practical design of both analog and digital integrated circuits, offering a vital, contemporary view of a
`wide range of analog/digital circuit blocks, the BSIM
`model, data converter architectures, and much more"-
`ISBN 978-0-470-88132-3 (hardback)
`and construction. 2. Integrated circuits(cid:173)
`I. Metal oxide semiconductors, Complementary-Design
`Design and construction. 3. Metal oxide semiconductor field-effect transistors. I. Title.
`TK7871.99.M44B35 2010
`62 l .39'732---dc22
`
`Provided by publisher.
`
`2010016630
`
`Printed in the United States of America.
`
`10 9 8 7 6 5 4 3 2 1
`
`
`
`Case 2:17-cv-04273-JVS-JEM Document 79-2 Filed 06/22/18 Page 9 of 36 Page ID
` #:1119
`
`Chapter
`
`2
`
`The Well
`
`To develop a fundamental understanding of CMOS integrated circuit layout and design,
`we begin with a study of the well. The well is the first layer fabricated when making a
`CMOS IC. The approach of studying the details of each fabrication (layout) layer will
`build a solid foundation for understanding the performance limitations and parasitics (the
`pn junctions, capacitances, and resistances inherent in a CMOS circuit) of the CMOS
`process.
`
`The Substrate (The Unprocessed Wafer)
`
`CMOS circuits are fabricated on and in a silicon wafer, as discussed in Ch. 1. This wafer
`is doped with donor atoms, such as phosphorus for an n-type wafer, or acceptor atoms,
`such as boron for a p-type wafer. Our discussion centers around a p-type wafer (the most
`common substrate used in CMOS IC processing). When designing CMOS integrated
`circuits with a p-type wafer, n-channel MOSFETs (NMOS for short) are fabricated
`directly in the p-type wafer, while p-channel transistors, PMOS, are fabricated in an
`"n-well." The substrate or well are sometimes referred to as the bulk or body of a
`MOSFET. CMOS processes that fabricate MOSFETs in the bulk are known as "bulk
`CMOS processes." The well and the substrate are illustrated in Fig. 2.1, though not to
`scale.
`
`Often an epitaxial layer is grown on the wafer. In this book we will not make a
`distinction between this layer and the substrate. Some processes use a p-well or both n(cid:173)
`and p-wells (sometimes called twin tub processes). A process that uses a p-type (n-type)
`substrate with an n-well (p-well) is called an "n-well process" ("p-well process"). We will
`assume, throughout this book, that an n-well process is used for the layout and design
`discussions.
`
`A Parasitic Diode
`
`Notice, in Fig. 2.1, that then-well and the p-substrate form a diode. In CMOS circuits, the
`substrate is usually tied to the lowest voltage in the circuit (generally, the substrate is
`grounded) to keep this diode from forward biasing. Ideally, zero current flows in the
`substrate. We won't concern ourselves with how the substrate is connected to ground at
`this point (see Ch. 4).
`
`
`
`Case 2:17-cv-04273-JVS-JEM Document 79-2 Filed 06/22/18 Page 10 of 36 Page ID
` #:1120
`32
`CMOS Circuit Design, Layout, and Simulation
`
`n-well
`I
`
`Flip chip
`
`I Chip I
`
`on its side
`and enlarge
`
`p-type epi layer (p-)
`
`p-type substrate (p+)
`
`MOSFETs are not shown.
`
`n-well
`
`p-substrate
`
`Usually, we
`will not show
`the epitaxial
`layer. Many
`processes don't use
`the epi layer.
`
`Figure 2.1 The top (layout) and side ( cross-sectional) view of a die.
`
`Using the N-well as a Resistor
`
`In addition to being used as the body for p-channel transistors, the n-well can be used as a
`resistor, Fig. 2.2. The voltage on either side of the resistor must be large enough to keep
`the substrate/well diode from forward biasing.
`
`Resistor leads
`
`p-substrate
`
`n-well
`
`Shows parasitiV
`diode
`
`Figure 2.2 The n-well can be used as a resistor.
`
`2.1 Patterning
`CMOS integrated circuits are formed by patterning different layers on and in the silicon
`wafer. Consider the following sequence of events that apply, in a fundamental way, to any
`layer that we need to pattern. We start out with a clean, bare wafer, as shown in Fig. 2.3a.
`The distance given by the line A to B will be used as a reference in Figs. 2.3b-j. Figures
`2.3b-j are cross-sectional views of the dashed line shown in (a). The small box in Fig.
`2.3a is drawn with a layout program (and used for mask generation) to indicate where to
`put the patterned layer.
`
`
`
`Case 2:17-cv-04273-JVS-JEM Document 79-2 Filed 06/22/18 Page 11 of 36 Page ID
` #:1121
`Chapter 2 The Well
`33
`
`A
`
`B
`
`sc,t;,a , 1
`
`-'"-'"'"
`cut along dotted
`line
`
`(a) Unprocessed wafer
`
`(b) Cross-sectional view of (a)
`A ______
`B
`
`A ------
`
`B
`
`_!
`
`__
`
`_I __
`
`
`
`(c) Grow oxide (glass or Si0 2) on wafer.
`
`A
`
`B
`
`(d) Deposit photoresist
`A
`
`Side view
`~
`
`p-type l
`P-IY~P' l 3~i~~
`resist rd,
`
`Photo-
`
`B
`
`Mask
`Photo-
`
`p-type
`
`(e) Mask made resulting from layout.
`
`(f) Placement of the mask over the wafer.
`
`lll
`
`p-t~- rx;~
`D
`Top view I
`lll Mask (reticle)
`r~de
`resist I
`r;,,
`resist l \
`
`I
`I \
`
`(g) Exposing photoresist.
`
`p-type
`
`)
`
`p-type
`
`(i) Etchi ng oxide to expose wafer.
`
`Photo-
`
`Photo-
`
`Photo-
`resist
`
`p-type
`
`r~,,
`L r;d,
`
`(h) Developing exposed photores ist.
`
`p-type
`
`(j) Removal ofphotoresist.
`
`Figure 2.3 Generic sequence of events used in photo patterning.
`
`
`
`Case 2:17-cv-04273-JVS-JEM Document 79-2 Filed 06/22/18 Page 12 of 36 Page ID
` #:1122
`34
`CMOS Circuit Design, Layout, and Simulation
`
`The first step in our generic patterning discussion is to grow an oxide, Si0 2 or
`glass, a very good insulator, on the wafer. Simply exposing the wafer to air yields the
`reaction Si + 0 2 ~ Si0 2• However, semiconductor processes must have tightly controlled
`conditions to precisely set the thickness and purity of the oxide. We can grow the oxide
`using a reaction with steam, H20, or with 0 2 alone. The oxide resulting from the reaction
`with steam is called a wet oxide, while the reaction with 0 2 is a dry oxide. Both oxides
`are called thermal oxides due to the increased temperature used during oxide growth. The
`growth rate increases with temperature. The main benefit of the wet oxide is fast growing
`time. The main drawback of the wet oxide is the hydrogen byproduct. In general terms,
`the oxide grown using the wet techniques is not as pure as the dry oxide. The dry oxide
`generally takes a considerably longer time to grow. Both methods of growing oxide are
`found in CMOS processes. An important observation we should make when looking at
`Fig. 2.3c is that the oxide growth actually consumes silicon. This is illustrated in Fig. 2.4.
`The overall thickness of the oxide is related to thickness of the consumed silicon by
`Xs; = 0.45 · Xox
`
`(2.1)
`
`Figure 2.4 How growing oxide consumes silicon.
`
`p-substrate
`
`is to deposit a
`The next step of the generic CMOS patterning process
`photosensitive
`resist layer across the wafer (see Fig. 2.3d). Keep in mind that the
`dimensions of the layers, that is, oxide, resist, and the wafer, are not drawn to scale. The
`thickness of a wafer is typically 500 µm, while the thickness of a grown oxide or a
`deposited resist may be only a µm (1 o-6 m) or even less. After the resist is baked, the
`mask derived from the layout program, Figs. 2.3e and f, is used to selectively illuminate
`areas of the wafer, Fig. 2.3g. In practice, a single mask called a reticle, with openings
`several times larger than the final illuminated area on the wafer, is used to project the
`pattern and is stepped across the wafer with a machine called a stepper to generate the
`patterns needed to create multiple copies of a single chip. The light passing through the
`opening in the reticle is photographically reduced to illuminate the correct size area on the
`wafer.
`
`that were
`the areas
`removing
`(Fig. 2.3h),
`is developed
`The photoresist
`illuminated. This process is called a positive resist process because the area that was
`illuminated was removed. A negative resist process removes the areas of resist that were
`not exposed to the light. Using both types of resist allows the process designer to cut
`down on the number of masks needed to define a CMOS process. Because creating the
`masks is expensive, lowering the number of masks is equated with lowering the cost of a
`process. This is also important in large manufacturing plants where fewer steps equal
`lower cost.
`
`
`
`Case 2:17-cv-04273-JVS-JEM Document 79-2 Filed 06/22/18 Page 13 of 36 Page ID
` #:1123
`Chapter 2 The Well
`35
`
`The next step in the patterning process is to remove the exposed oxide areas (Fig.
`2.3i). Notice that the etchant etches under the resist, causing the opening in the oxide to
`be larger than what was specified by the mask. Some manufacturers intentionally bloat
`(make larger) or shrink (make smaller) the masks as specified by the layout program.
`Figure 2.3j shows the cross-sectional view of the opening after the resist has been
`removed.
`
`2.1.1 Patterning the N-well
`
`At this point we can make an n-well by diffusing donor atoms, those with five valence
`electrons, as compared to the 4 four found in silicon, into the wafer. Referring to our
`generic patterning discussion given in Fig. 2.3, we begin by depositing a layer of resist
`directly on the wafer, Fig. 2.3d (without oxide). This is followed by exposing the resist to
`light through a mask (Figs. 2.3f and g) and developing or removing the resist (Fig. 2.3h).
`The mask used is generated with a layout program. The next step in fabricating the n-well
`is to expose the wafer to donor atoms. The resist blocks the diffusion of the atoms, while
`the openings allow the donor atoms to penetrate into the wafer. This is shown in Fig.
`2.5a. After a certain amount of time, depending on the depth of the n-well desired, the
`diffusion source is removed (Fig. 2.5b). Notice that the n-well "outdiffuses" under the
`resist; that is, the final n-well size is not the same as the mask size. Again, the foundry
`where the chips are fabricated may bloat or shrink the mask to compensate for this lateral
`diffusion. The final step in making then-well is the removal of the resist (Fig. 2.5c).
`
`p-type
`
`(a) Diffusion of donor atoms
`
`.._ __________
`
`
`
`P_-typ ......... e_l
`
`(b) After diffusion
`
`LL LL L l l L l l L l l l Diffusion of donor atoms
`l
`~R~ist ~ Start of diffusion into th, w,f.,
`l ~ t~ist
`l
`
`( d) Angled view of n-well
`
`( c) After resist removal
`
`Figure 2.5 Formation of then-well.
`
`
`
`Case 2:17-cv-04273-JVS-JEM Document 79-2 Filed 06/22/18 Page 14 of 36 Page ID
` #:1124
`36
`CMOS Circuit Design, Layout, and Simulation
`
`2.2 Laying Out the N-well
`
`When we lay out the n-well, we are viewing the chip from the top. One of the key points
`in this discussion, as well as the discussions to follow, is that we do layout to a generic
`scale factor. If, for example, the minimum device dimensions are 50 nm(= 0.05 µm =
`50 x 10-9 m), then an n-well box drawn 10 by 10, see Fig. 2.6, has an actual size after it
`is fabricated of 10 · 50 nm or half a micron (0.5 µm = 500 nm), neglecting lateral
`diffusion or other process imperfections. We scale the layout when we generate the GDS
`(calma stream format) or CIF (Caltech-intermediate-format)
`file from a layout program.
`(A GDS or CIF file is what the mask maker uses to make reticles.) Using integers to do
`layout simplifies things. We'll see in a moment that many electrical parameters are ratios
`(such as resistance) and so the scale factor cancels out of the ratio.
`
`Cross section
`
`shown below
`
`--------------------1
`
`:
`
`I
`I
`I
`
`:-------------------
`
`10
`
`10
`
`I
`
`I
`
`~---n-_we_n
`
`__
`
`)
`
`p-substrate
`
`Figure 2.6 Layout and cross-sectional view of a 10 by 10 ( drawn) n-well.
`
`2.2.1 Design Rules for the N-well
`
`Now that we've laid out then-well (drawn a box in a layout program), we might ask the
`question, "Are there any limitations or constraints on the size and spacing of the
`n-wells?" That is to say, "Can we make the n-well 2 by 2?" Can we make the distance
`between the n-wells
`l? As we might expect, there are minimum spacing and size
`requirements for all layers in a CMOS process. Process engineers, who design the
`integrated circuit process, specify the design rules. The design rules vary from one
`process technology (say a process with a scale factor of l µm) to another (say a process
`with a scale factor of 50 nm).
`
`Figure 2.7 shows sample design rules for then-well. The minimum size (width or
`length) of any n-well is 6, while the minimum spacing between different n-wells is 9. As
`the layout becomes complicated, the need for a program that ensures that the design rules
`are not violated is needed. This program is called a design rule checker program (DRC
`program). Note that the minimum size may be set by the quality of patterning the resist
`(as seen in Fig. 2.5), while the spacing is set by the parasitic npn transistor seen in Fig.
`2.7. (We don't want then-wells interacting to prevent the parasitic npn from turning on.)
`
`
`
`Case 2:17-cv-04273-JVS-JEM Document 79-2 Filed 06/22/18 Page 15 of 36 Page ID
` #:1125
`Chapter 2 The Well
`37
`
`Cross section
`
`shown below r
`
`Width
`Width
`~ ____ ~ Spacing~- __ -~
`:
`:< >:
`
`I
`
`:
`
`I
`
`I --------
`
`T Design rules: width of
`{,
`the n-well must be at
`least 6 while spacing
`should be at least 9.
`
`~-..._
`
`......... ~._ n-well
`
`?
`
`7
`Parasitic npn bipolar transistor
`
`p-substrate
`
`Figure 2.7 Sample design rules for then-well.
`
`2.3 Resistance Calculation
`
`In addition to serving as a region in which to build PMOS transistors ( called the body or
`bulk of the PMOS devices), n-wells are often used to create resistors. The resistance of a
`material is a function of the material's resistivity, p, and the material's dimensions. For
`example, the slab of material in Fig. 2.8 between the two leads has a resistance given by
`R = £ . L · scale = £ . 1=._
`t W· scale
`t W
`
`(2_2)
`
`In semiconductor processing, all of the fabricated thicknesses, t , seen in a cross(cid:173)
`sectional view, such as the n-well's, are fixed in depth (this is important). When doing
`layout, we only have control over W (width) and L (length) of the material. The Wand L
`are what we see from the top view, that is, the layout view. We can rewrite Eq. (2.2) as
`p
`t
`Rsquare is the sheet resistance of the material in Q/square (noting that when L = W the
`layout is square and R = Rsqua,.).
`
`(2.3)
`
`R = Rsquare
`
`L
`· W ~ Rsquare
`
`w
`
`B
`
`A
`
`A
`
`IE L
`
`Layout view
`
`!w )I B
`
`Figure 2.8 Calculation of the resistance of a rectangular block of material.
`
`
`
`Case 2:17-cv-04273-JVS-JEM Document 79-2 Filed 06/22/18 Page 16 of 36 Page ID
` #:1126
`CMOS Circuit Design, Layout, and Simulation
`38
`
`Example 2.1
`Calculate the resistance ofan n-well that is 10 wide and 100 long. Assume that the
`n-well's sheet resistance is typically 2 kn/square; however, it can vary with
`process shifts from 1.6 to 2.4 kn/square.
`
`The typical resistance, using Eq. (2.3), between the ends of then-well is
`
`R = 2 000 · l OO = 20 kn
`'
`10
`
`The maximum value of the resistor is 24k, while the minimum value is 16k. •
`
`Layout of Corners
`
`Often, to minimize space, resistors are laid out in a serpentine pattern. The comers, that
`is, where the layer bends, are not rectangular. This is shown in Fig. 2.9a. All sections in
`Fig 2.9a are square, so the resistance of sections 1 and 3 is Rsquare· The equivalent
`resistance of section 2 between the adjacent sides, however, is approximately 0.6 Rsquare·
`The overall resistance between points A and B is therefore 2.6 ·Rsquare· As seen in Ex. 2.1
`the actual resistance value varies with process shifts. The layout shown in Fig. 2.9b uses
`wires to connect separate sections of unit resistors to avoid comers. A voiding comers in a
`resistor is the (generally) preferred method of layout in analog circuit design where the
`ratio of two resistors is important. For example, the gain of an op-amp circuit may be
`R/R 1 •
`
`Layout (top view)
`
`_ --~ ----_i B
`l~-=~_J
`: __ r __ ,
`
`I
`
`: 1
`
`:
`
`:
`
`(a)
`
`A
`
`_ _[ _ -
`
`I
`I
`
`__ I_ __
`
`__ ~I __ -_ -B
`
`I
`
`I
`
`(b)
`
`' I
`
`I -r-' I -r-'
`I -r-'
`
`I
`
`I
`
`Figure 2.9 (a) Calculating the resistance of a comer section and (b) layout to avoid comers.
`
`A
`
`2.3.1 The N-well Resistor
`
`At this point, it is appropriate to show the actual cross-sectional view of the n-well after
`all processing steps are completed (Fig. 2.10). The n+ and p+ implants are used to
`increase the threshold voltage of the field devices; more will be said on this in Ch. 7. In
`all practical situations, the sheet resistance of the n-well is measured with the field
`implant in place, that is, with the n+ implant between the two metal connections in Fig.
`2.10. Not shown in Fig. 2.10 is the connection to substrate. The field oxide (FOX; also
`known as ROX or recessed oxide) are discussed in Chs. 4 and 7 when we discuss the
`active and poly layers. The reader shouldn't, at this point, feel they should understand any
`of the cross-sectional layers in Fig. 2.10 except the n-well. Note that the field implants
`aren 't drawn in the layout and so their existence is transparent to the designer.
`
`
`
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`Chapter 2 The Well
`39
`
`Metal
`
`Metal
`
`FOX
`
`_)
`
`p+ field 11nplant
`n+ field implant
`
`n+ active implant
`
`p-substrate
`
`Figure 2.10 Cross-sectional view ofn-well showing field implant. The field
`implantation is sometimes called the "channel stop implant."
`
`2.4 The N-well/Substrate Diode
`As seen in Fig. 2.1, placing an n-well in the p-substrate forms a diode. It is important to
`understand how to model a diode for hand calculations and in SPICE simulations. In
`particular,
`let's discuss general diodes using the n-well/substrate pn junction as an
`example. The DC characteristics of the diode are given by the Shockley diode equation,
`or
`
`Io = Is(e::r - 1)
`
`(2.4)
`
`The current ID is the diode current; ls is the scale (saturation) current; Vd is the voltage
`across the diode where the anode, A, (p-type material) is assumed positive with respect to
`the cathode, K, (n-type); and Vr is the thermal voltage, which is given by !f where k =
`Boltzmann's constant (1.3806 x 10-23 Joules per degree Kelvin), T is temperature
`in
`Kelvin, n is the emission coefficient (a term that is related to the doping profile and
`affects both the exponential behavior of the diode and the diode's turn-on voltage), and q
`is the electron charge of 1.6022 x 10-19 coulombs. The scale current and thus the overall
`diode current are related in SPICE by an area factor (not associated with or to be confused
`with the scale term we use in layouts, Eq. (2.2)). The SPICE (Simulation Program with
`Integrated Circuit Emphasis) circuit simulation program assumes that the value of Is
`supplied in the model statement was measured for a device with a reference area of 1. If
`an area factor of 2 is supplied for a diode, then Is is doubled in Eq. (2.4).
`
`2.4.1 A Brief Introduction to PN Junction Physics
`
`A conducting material is made up of atoms that have easily shared orbiting electrons. As
`a simple example, copper is a better conductor than aluminum because the copper atom's
`electrons aren't as tightly coupled to its nucleus allowing its electrons to move around
`more easily. An insulator has, for example, eight valence electrons tightly coupled to the
`atom's nucleus. A significant electric field is required to break these electrons away from
`their nucleus (and thus for current conduction). A semiconductor,
`like silicon, has four
`valence electrons. Silicon's conductivity falls between an insulator and a conductor (and
`thus the name "semiconductor"). As silicon atoms are brought together, they form both a
`periodic crystal structure and bands of energy that restrict the allowable energies an
`electron can occupy. At absolute zero temperature, (T = 0 K), all of the valence electrons
`in the semiconductor crystal reside in the valence energy band, Ev. As temperature
`
`
`
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`CMOS Circuit Design, Layout, and Simulation
`40
`
`increases, the electrons gain energy (heat is absorbed by the silicon crystal), which causes
`some of the valence electrons to break free and move to a conducting energy level, Ee.
`Figure 2.11 shows the movement of an electron from the valence band to the conduction
`band. Note that there aren't any allowable energies between E. and Ee in the silicon
`crystal structure (if the atom were by itself, that is, not in a crystal structure this exact
`limitation isn't present). Further note that when the electron moves from the valence
`energy band to the conduction energy band, a hole is left in the valence band. Having an
`electron in the conduction band increases the material's conductivity (the electron can
`move around easily in the semiconductor material because it's not tightly coupled to an
`atom's nucleus). At the same time a hole in the valence band increases the material's
`conductivity ( electrons in the valence band can move around more easily by simply
`falling into the open hole). The key point is that increasing the number of electrons or
`holes increases the materials conductivity. Since the hole is more tightly coupled to the
`atom's nucleus (actually the electrons in the valence band), its mobility (ability to move
`around) is lower than the electron's mobility in the conduction band. This point is
`fundamentally important. The fact that the mobility of a hole is lower than the mobility
`of an electron (in silicon) results in, among other things, the size of PMOS devices being
`larger than the size of NMOS devices (when designing circuits) in order for each device
`to have the same drive strength.
`
`f'""® ~:
`
`E,I
`••••••••••o•••••••••
`hole
`
`Figure 2.11 An electron moving to the conduction band, leaving
`behind a hole in the valence band.
`
`Carrier Concentrations
`
`Pure silicon is often called intrinsic silicon. As the temperature of the silicon crystal is
`increased it absorbs heat. Some of the electrons in the valence band gain enough energy
`to jump the bandgap energy of silicon, Eg (see also Eq. (23.21)), as seen in Fig. 2.11. This
`movement of an electron from the valence band to the conduction band is called
`generation. When the electron loses energy and falls back into the valence band, it is
`called recombination. The time the electron spends in the conduction band, before it
`recombines ( drops back to the valence energy band), is random and often characterized by
`the carrier lifetime, tr(a root-mean-square, RMS, value of the random times the electrons
`spend in the conduction band of the silicon crystal). While discussing the actual processes
`involved with generation-recombination (GR) is outside the scope of this book, the
`carrier lifetime is a practical important parameter for circuit design. Another important
`parameter is the number of electrons in the conduction band ( and thus the number of
`holes in the valence band) at a given time (again a random number). These carriers are
`called intrinsic carriers, n;. At room temperature
`
`n;"" 14.5 x 109 carriers!cm 3
`
`(2.5)
`
`
`
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`Chapter 2 The Well
`41
`
`noting that cm 3 indicates a volume. If we call the number of free electrons (meaning
`electrons excited up in the conduction band of silicon) n and the number of holes p, then
`for intrinsic silicon,
`
`n = p = n;"" 14.5 x 109 carriers/cm 3
`This may seem like a lot of carriers. However, the number of silicon atoms, Ns; , in a
`given volume of crystalline silicon is
`Ns; = 50 x 1021 atomslcm 3
`so there is only one excited electron/hole pair for (roughly) every 1012 silicon atoms.
`
`(2.7)
`
`(2.6)
`
`Next let's add different materials to intrinsic silicon (called doping the silicon) to
`change silicon's electrical properties. If we add a small amount of a material containing
`atoms with five valence electrons like phosphorous (silicon has four), then the added
`atom would bond with the silicon atoms and the donated electron would be free to move
`around (and easily excited to the conduction band). If we call the density of this added
`donor material ND with units of atoms/cm 3 and we assume the number of atoms added to
`the silicon is much larger than the intrinsic carrier concentration, then we can write the
`number of free electrons (the electron concentration n) in the material as
`
`n:::::,ND whenNs;>>ND>>n;
`
`(2.8)
`
`A material with added donor atoms is said to be an "n-type" material. Similarly, if we
`were to add a small material to silicon with atoms having three valence electrons (like
`boron), the added material would bond with the silicon resulting in a hole in the valence
`band. Again, this increases the conductivity of silicon because, now, the electrons in the
`valence band can move into the hole (having the effect of making it look like the hole is
`moving). The added material in this situation is said to be an acceptor material. The
`added material accepts an electron from the silicon crystal. If the density of the added
`acceptor material is labeled NA , then the hole concentration, p , in the material is
`
`p ""NA when Ns; >> NA >> n;
`
`(2.9)
`
`A material with added acceptor atoms is said to be a "p-type" material.
`
`If we dope a material with donor atoms, the number of free electrons in the
`material, n, goes up, as indicated by Eq. (2.8). We would expect, then, the number of free
`holes in the material to go down (some of those free electrons fall easily into the available
`holes reducing the number of holes in the material). The relationship between the number
`of holes, electrons, and intrinsic carrier concentration, is governed by the mass-action law
`
`(2.10)
`
`Consider the following example.
`
`Example 2.2
`is doped with phosphorous having a density, ND , of 1018
`Suppose silicon
`atoms/cm 3
`• Estimate the doped silicon's hole and electron concentration.
`
`The electron concentration, from Eq. (2.8) is, n = 1018 electrons/cm 3 (one electron
`for each donor atom). The hole concentration is found using the mass-action law
`as
`
`
`
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`42
`CMOS Circuit Design, Layout, and Simulation
`
`= 210 holes/cm 3
`
`2
`
`)
`
`n 2
`(14 5 X 109
`p = _..!._ =
`·
`101s
`n
`Basically, all of the holes are filled. Note that with a doping density of l 0 18 there
`is one dopant atom for every 50,000 silicon atoms. If we continue to increase the
`doping concentration, our assumption that Ns; >> ND isn't valid and the material is
`said to be degenerate (no longer mainly silicon). A degenerate semiconductor
`doesn't follow the mass-action law (or any of the equations for silicon we
`present).•
`
`Fermi Energy Level
`
`To describe the carrier concentration in a semiconductor, the Fermi energy level is often
`used. The Fermi energy level is useful when determining the contact potentials in
`materials. For example, the pot