Chapter 44.1⎪⎪⎭⎫ ⎝⎛-=kTE N N n gc i exp 2υ ⎪⎪⎭⎫ ⎝⎛-⎪⎭⎫ ⎝⎛=kT E T N N g O cO exp 3003υwhere cO N and O N υ are the values at 300 K.(b) Germanium_______________________________________ 4.2Plot_______________________________________ 4.3(a) ⎪⎪⎭⎫⎝⎛-=kT E N N n g c i exp 2υ ()()()319192113001004.1108.2105⎪⎭⎫⎝⎛⨯⨯=⨯T()()⎥⎦⎤⎢⎣⎡-⨯3000259.012.1exp T()3382330010912.2105.2⎪⎭⎫⎝⎛⨯=⨯T()()()()⎥⎦⎤⎢⎣⎡-⨯T 0259.030012.1expBy trial and error, 5.367≅T K(b)()252122105.2105⨯=⨯=i n()()()()()⎥⎦⎤⎢⎣⎡-⎪⎭⎫⎝⎛⨯=T T 0259.030012.1exp 30010912.2338By trial and error, 5.417≅T K_______________________________________ 4.4At 200=T K, ()⎪⎭⎫⎝⎛=3002000259.0kT017267.0=eVAt 400=T K, ()⎪⎭⎫⎝⎛=3004000259.0kT034533.0=eV()()()()17222102210025.31040.11070.7200400⨯=⨯⨯=ii nn⎥⎦⎤⎢⎣⎡-⎥⎦⎤⎢⎣⎡-⨯⎪⎭⎫⎝⎛⎪⎭⎫ ⎝⎛=017267.0exp 034533.0exp 30020030040033g g E E⎥⎦⎤⎢⎣⎡-=034533.0017267.0exp 8g g E E()[]9578.289139.57exp 810025.317-=⨯g Eor()1714.38810025.3ln 9561.2817=⎪⎪⎭⎫⎝⎛⨯=g E or 318.1=g E eVNow ()32103004001070.7⎪⎭⎫⎝⎛=⨯o co N N υ⎪⎭⎫ ⎝⎛-⨯034533.0318.1exp ()()172110658.2370.210929.5-⨯=⨯o co N N υ so 371041.9⨯=o co N N υcm 6-_______________________________________ 4.5()()⎪⎭⎫ ⎝⎛-=⎪⎭⎫ ⎝⎛-⎪⎭⎫ ⎝⎛-=kT kT kT A n B n i i 20.0exp 90.0exp 10.1exp For 200=T K, 017267.0=kT eV For 300=T K, 0259.0=kT eV For 400=T K, 034533.0=kT eV(a) For 200=T K, ()()610325.9017267.020.0exp -⨯=⎪⎭⎫ ⎝⎛-=A n B n i i (b) For 300=T K, ()()41043.40259.020.0exp -⨯=⎪⎭⎫ ⎝⎛-=A n B n i i (c) For 400=T K, ()()31005.3034533.020.0exp -⨯=⎪⎭⎫ ⎝⎛-=A n B n i i _______________________________________ 4.6(a) ()⎥⎦⎤⎢⎣⎡---∝kT E E E E f g F c F c exp()⎥⎦⎤⎢⎣⎡---∝kT E E E E c c exp()⎥⎦⎤⎢⎣⎡--⨯kT E E F c exp Let x E E c =-Then ⎪⎭⎫⎝⎛-∝kT x x f g F c expTo find the maximum value: ()⎪⎭⎫⎝⎛-∝-kT x x dx f g d F c exp 212/10exp 12/1=⎪⎭⎫ ⎝⎛-⋅-kT x x kT which yields2212/12/1kTx kT x x =⇒= The maximum value occurs at2kTE E c +=(b)()()⎥⎦⎤⎢⎣⎡---∝-kT E E E E f g F F exp 1υυ()⎥⎦⎤⎢⎣⎡---∝kT E E E E υυexp()⎥⎦⎤⎢⎣⎡--⨯kT E E F υexp Let x E E =-υThen ()⎪⎭⎫ ⎝⎛-∝-kT x x f g F exp 1υTo find the maximum value()[]0exp 1=⎥⎦⎤⎢⎣⎡⎪⎭⎫ ⎝⎛-∝-kT x x dx d dx f g d F υ Same as part (a). Maximum occurs at2kTx =or2kTE E -=υ_______________________________________ 4.7()()()()⎥⎦⎤⎢⎣⎡---⎥⎦⎤⎢⎣⎡---=kT E E E E kT E E E E E n E n c c c c 221121exp expwherekT E E c 41+= and 22kTE E c += Then()()()⎥⎦⎤⎢⎣⎡--=kT E E kT kTE n E n 2121exp 24()5.3exp 22214exp 22-=⎥⎦⎤⎢⎣⎡⎪⎭⎫ ⎝⎛--=or()()0854.021=E n E n_______________________________________ 4.8Plot_______________________________________ 4.9Plot_______________________________________ 4.10⎪⎪⎭⎫ ⎝⎛=-**ln 43n p midgap Fi m m kT E E Silicon: o p m m 56.0*=, o n m m 08.1*=0128.0-=-midgap Fi E E eV Germanium: o pm m 37.0*=,o n m m 55.0*=0077.0-=-midgap Fi E E eV Gallium Arsenide: o p m m 48.0*=,o n m m 067.0*= 0382.0+=-midgap Fi E E eV _______________________________________ 4.11 ()⎪⎪⎭⎫⎝⎛=-c midgap Fi N N kT E E υln 21()()kT kT 4952.0108.21004.1ln 211919-=⎪⎪⎭⎫ ⎝⎛⨯⨯=_______________________________________ 4.12(a) ⎪⎪⎭⎫ ⎝⎛=-**ln 43n pmidgap Fi m m kT E E()⎪⎭⎫⎝⎛=21.170.0ln 0259.04363.10-⇒meV(b) ()⎪⎭⎫⎝⎛=-080.075.0ln 0259.043midgap Fi E E47.43+⇒meV_______________________________________ 4.13Let ()==K E g c constant Then()()dE E fE g n FE co c⎰∞=dE kT E E Kc E F⎰∞⎪⎪⎭⎫⎝⎛-+=exp 11()dE kT E E K cE F ⎰∞⎥⎦⎤⎢⎣⎡--≅exp Let kT E E c-=η so that ηd kT dE ⋅=We can write ()()c F c F E E E E E E -+-=-so that()()()η-⋅⎥⎦⎤⎢⎣⎡--=⎥⎦⎤⎢⎣⎡--exp exp exp kT E E kT E E F c F The integral can then be written as()()ηηd kT E E kT K n F c o ⎰∞-⎥⎦⎤⎢⎣⎡--⋅⋅=0exp exp which becomes()⎥⎦⎤⎢⎣⎡--⋅⋅=kT E E kT K n F c o exp _______________________________________ 4.14Let ()()c c E E C E g -=1 for c E E ≥ Then()()dE E fE g n FE co c⎰∞=()dE kT E E E E C c E Fc ⎰∞⎪⎪⎭⎫⎝⎛-+-=exp 11()()dE kT E E E E C F E C c⎥⎦⎤⎢⎣⎡---≅⎰∞exp 1LetkTE E c-=η so that ηd kT dE ⋅= We can write()()F c c F E E E E E E -+-=-Then()⎥⎦⎤⎢⎣⎡--=kT E E C n F c o exp 1()()dE kT E E E E c E c c⎥⎦⎤⎢⎣⎡---⨯⎰∞exp or()⎥⎦⎤⎢⎣⎡--=kT E E C n F c o exp 1 ()()()[]()ηηηd kT kT -⨯⎰∞exp 0We find that()()()11exp exp 0+=---=-∞∞⎰ηηηηηdSo()()⎥⎦⎤⎢⎣⎡--=kT E E kT C n F c o exp 21 _______________________________________ 4.15We have ⎪⎪⎭⎫⎝⎛=∈*1m m a r o r o For germanium, 16=∈r , o m m 55.0*= Then()()()53.02955.01161=⎪⎭⎫⎝⎛=o a roroA r 4.151=The ionization energy can be written as ()6.132*⎪⎪⎭⎫⎝⎛∈∈⎪⎪⎭⎫ ⎝⎛=s o o m m E eV ()()029.06.131655.02=⇒=E eV_______________________________________ 4.16We have ⎪⎪⎭⎫⎝⎛=∈*1m m a r o r o For gallium arsenide, 1.13=∈r ,o m m 067.0*= Then()()oA r 10453.0067.011.131=⎪⎭⎫⎝⎛=The ionization energy is()()()6.131.13067.06.1322*=⎪⎪⎭⎫ ⎝⎛∈∈⎪⎪⎭⎫ ⎝⎛=s o o m m E or0053.0=E eV_______________________________________ 4.17(a) ⎪⎪⎭⎫⎝⎛=-o c F c n N kT E E ln()⎪⎪⎭⎫⎝⎛⨯⨯=1519107108.2ln 0259.02148.0=eV(b) ()F c g F E E E E E --=-υ90518.02148.012.1=-=eV(c) ()⎥⎦⎤⎢⎣⎡--=kT E E N p F o υυexp()⎥⎦⎤⎢⎣⎡-⨯=0259.090518.0exp 1004.119 31090.6⨯=cm 3- (d) Holes(e) ⎪⎪⎭⎫⎝⎛=-i o Fi F n n kT E E ln()⎪⎪⎭⎫⎝⎛⨯⨯=1015105.1107ln 0259.0338.0=eV_______________________________________ 4.18(a) ⎪⎪⎭⎫⎝⎛=-o F p N kT E E υυln()⎪⎪⎭⎫⎝⎛⨯⨯=16191021004.1ln 0259.0162.0=eV (b) ()υE E E E E F g F c --=- 958.0162.012.1=-=eV(c) ()⎪⎭⎫⎝⎛-⨯=0259.0958.0exp 108.219o n31041.2⨯=cm 3-(d) ⎪⎪⎭⎫⎝⎛=-i o F Fi n p kT E E ln()⎪⎪⎭⎫⎝⎛⨯⨯=1016105.1102ln 0259.0365.0=eV_______________________________________ 4.19(a) ⎪⎪⎭⎫⎝⎛=-o c F c n N kT E E ln()⎪⎪⎭⎫⎝⎛⨯⨯=519102108.2ln 0259.08436.0=eV ()F c g F E E E E E --=-υ 8436.012.1-= 2764.0=-υE E F eV(b) ()⎪⎭⎫⎝⎛-⨯=0259.027637.0exp 1004.119o p1410414.2⨯=cm 3-(c) p-type_______________________________________ 4.20(a) ()032375.03003750259.0=⎪⎭⎫⎝⎛=kT eV()⎥⎦⎤⎢⎣⎡-⎪⎭⎫ ⎝⎛⨯=032375.028.0exp 300375107.42/317o n 141015.1⨯=cm 3-()28.042.1-=--=-F c g F E E E E E υ 14.1=eV()⎥⎦⎤⎢⎣⎡-⎪⎭⎫⎝⎛⨯=032375.014.1exp 3003751072/318o p 31099.4⨯=cm 3-(b) ()⎪⎪⎭⎫⎝⎛⨯⨯=-14171015.1107.4ln 0259.0F c E E2154.0=eV()2154.042.1-=--=-F c g F E E E E E υ 2046.1=eV()⎥⎦⎤⎢⎣⎡-⨯=0259.02046.1exp 10718o p21042.4-⨯=cm 3-_______________________________________ 4.21(a) ()032375.03003750259.0=⎪⎭⎫⎝⎛=kT eV()⎥⎦⎤⎢⎣⎡-⎪⎭⎫⎝⎛⨯=032375.028.0exp 300375108.22/319o n 151086.6⨯= cm 3-()28.012.1-=--=-F c g F E E E E E υ 840.0=eV()⎥⎦⎤⎢⎣⎡-⎪⎭⎫⎝⎛⨯=032375.0840.0exp 3003751004.12/319o p 71084.7⨯=cm 3-(b) ⎪⎪⎭⎫⎝⎛=-o c F c n N kT E E ln()⎪⎪⎭⎫⎝⎛⨯⨯=151910862.6108.2ln 0259.02153.0=eV9047.02153.012.1=-=-υE E F eV()⎥⎦⎤⎢⎣⎡-⨯=0259.0904668.0exp 1004.119o p 31004.7⨯=cm 3-_______________________________________ 4.22(a) p-type(b) 28.0412.14===-g F E E E υeV()⎥⎦⎤⎢⎣⎡--=kT E E N p F o υυexp ()⎥⎦⎤⎢⎣⎡-⨯=0259.028.0exp 1004.119141010.2⨯=cm 3- ()υE E E E E F g F c --=- 84.028.012.1=-=eV()⎥⎦⎤⎢⎣⎡--=kT E E N n F c c o exp ()⎥⎦⎤⎢⎣⎡-⨯=0259.084.0exp 108.219 51030.2⨯=cm 3-_______________________________________ 4.23(a) ⎥⎦⎤⎢⎣⎡-=kT E E n n Fi Fi o exp ()⎥⎦⎤⎢⎣⎡⨯=0259.022.0exp 105.110131033.7⨯=cm 3-⎥⎦⎤⎢⎣⎡-=kT E E n p F Fii o exp ()⎥⎦⎤⎢⎣⎡-⨯=0259.022.0exp 105.11061007.3⨯=cm 3-(b) ⎥⎦⎤⎢⎣⎡-=kT E E n n Fi Fi o exp()⎥⎦⎤⎢⎣⎡⨯=0259.022.0exp 108.16 91080.8⨯=cm 3-⎥⎦⎤⎢⎣⎡-=kT E E n p F Fii o exp()⎥⎦⎤⎢⎣⎡-⨯=0259.022.0exp 108.16 21068.3⨯=cm 3-_______________________________________ 4.24(a) ⎪⎪⎭⎫⎝⎛=-o F p N kT E E υυln()⎪⎪⎭⎫⎝⎛⨯⨯=151********.1ln 0259.01979.0=eV (b) ()υE E E E E F g F c --=- 92212.019788.012.1=-=eV(c) ()⎥⎦⎤⎢⎣⎡-⨯=0259.092212.0exp 108.219o n31066.9⨯=cm 3- (d) Holes(e) ⎪⎪⎭⎫⎝⎛=-i o F Fi n p kT E E ln()⎪⎪⎭⎫⎝⎛⨯⨯=1015105.1105ln 0259.03294.0=eV _______________________________________ 4.25()034533.03004000259.0=⎪⎭⎫⎝⎛=kT eV()2/3193004001004.1⎪⎭⎫⎝⎛⨯=υN1910601.1⨯=cm 3-()2/319300400108.2⎪⎭⎫⎝⎛⨯=c N19103109.4⨯=cm 3-()()1919210601.1103109.4⨯⨯=i n⎥⎦⎤⎢⎣⎡-⨯034533.012.1exp 24106702.5⨯=1210381.2⨯=⇒i n cm 3- (a) ⎪⎪⎭⎫ ⎝⎛=-oF pN kT E E υυln ()⎪⎪⎭⎫⎝⎛⨯⨯=151910510601.1ln 034533.02787.0=eV(b) 84127.027873.012.1=-=-F c E E eV(c) ()⎥⎦⎤⎢⎣⎡-⨯=034533.084127.0exp 103109.419o n910134.1⨯=cm 3- (d) Holes(e) ⎪⎪⎭⎫⎝⎛=-i o F Fi n p kT E E ln()⎪⎪⎭⎫⎝⎛⨯⨯=121510381.2105ln 034533.02642.0=eV _______________________________________ 4.26(a) ()⎥⎦⎤⎢⎣⎡-⨯=0259.025.0exp 10718o p141050.4⨯=cm 3-17.125.042.1=-=-F c E E eV()⎥⎦⎤⎢⎣⎡-⨯=0259.017.1exp 107.417o n21013.1-⨯=cm 3-(b) 034533.0=kT eV ()2/318300400107⎪⎭⎫⎝⎛⨯=υN1910078.1⨯=cm 3- ()2/317300400107.4⎪⎭⎫⎝⎛⨯=c N1710236.7⨯=cm 3- ⎪⎪⎭⎫⎝⎛=-o F p N kT E E υυln()⎪⎪⎭⎫⎝⎛⨯⨯=14191050.410078.1ln 034533.03482.0=eV072.13482.042.1=-=-F c E E eV()⎥⎦⎤⎢⎣⎡-⨯=034533.007177.1exp 10236.717o n 41040.2⨯=cm 3-_____________________________________ 4.27(a) ()⎥⎦⎤⎢⎣⎡-⨯=0259.025.0exp 1004.119o p141068.6⨯=cm 3-870.025.012.1=-=-F c E E eV()⎥⎦⎤⎢⎣⎡-⨯=0259.0870.0exp 108.219o n41023.7⨯=o n cm 3- (b) 034533.0=kT eV ()2/3193004001004.1⎪⎭⎫⎝⎛⨯=υN1910601.1⨯=cm 3- ()2/319300400108.2⎪⎭⎫ ⎝⎛⨯=c N1910311.4⨯=cm 3-⎪⎪⎭⎫⎝⎛=-o F p N kT E E υυln()⎪⎪⎭⎫⎝⎛⨯⨯=14191068.610601.1ln 034533.03482.0=eV7718.03482.012.1=-=-F c E E eV()⎥⎦⎤⎢⎣⎡-⨯=034533.077175.0exp 10311.419o n91049.8⨯=cm 3-_______________________________________ 4.28(a) ()F c o F N n ηπ2/12=For 2kT E E c F +=,5.02==-=kTkT kT E E c F F η Then ()0.12/1≅F F η()()0.1108.2219⨯=πo n191016.3⨯=cm 3-(b) ()F c o F N n ηπ2/12=()()0.1107.4217⨯=π171030.5⨯=cm 3-_______________________________________ 4.29()F o F N p ηπυ'=2/12()()FF ηπ'⨯=⨯2/119191004.12105So ()26.42/1='FF η We find kTE E FF-=≅'υη0.3()()0777.00259.00.3==-F E E υeV_______________________________________ 4.30(a) 44==-=kTkTkT E E c F F ηThen ()0.62/1≅F F η ()F c o F N n ηπ2/12=()()0.6108.2219⨯=π201090.1⨯=cm 3-(b) ()()0.6107.4217⨯=πo n181018.3⨯=cm 3-_______________________________________ 4.31For the electron concentration ()()()E f E g E n F c =The Boltzmann approximation applies, so ()()c nE E hm E n -=32/3*24π()⎥⎦⎤⎢⎣⎡--⨯kT E E F exp or()()()⎥⎦⎤⎢⎣⎡--=kT E E h m E n F c nexp 2432/3*π()⎥⎦⎤⎢⎣⎡---⨯kT E E kT E E kTc c exp DefinekTE E x c-= Then()()()x x K x n E n -=→exp To find maximum ()()x n E n →, set()()x x K dx x dn -⎢⎣⎡==-exp 2102/1 +()()⎥⎦⎤--x x exp 12/1or()⎥⎦⎤⎢⎣⎡--=-x x Kx 21exp 02/1which yieldskT E E kT E E x c c 2121+=⇒-==For the hole concentration ()()()[]E f E g E p F -=1υUsing the Boltzmann approximation ()()E E h m E p p-=υπ32/3*24()⎥⎦⎤⎢⎣⎡--⨯kT E E F exp or()()()⎥⎦⎤⎢⎣⎡--=kT E E h mE pF pυπexp 2432/3*()⎥⎦⎤⎢⎣⎡---⨯kT E E kT E E kTυυexp DefinekTEE x -='υThen()()x x K x p '-''='exp To find maximum value of ()()x p E p '→,set()0=''x d x dp Using the results from above,we find the maximum atkT E E 21-=υ_______________________________________4.32(a) Silicon: We have()⎥⎦⎤⎢⎣⎡--=kT E E N n F c c o exp We can write()()F d d c F c E E E E E E -+-=- For045.0=-d c E E eV andkT E E F d 3=-eV we can write()⎥⎦⎤⎢⎣⎡--⨯=30259.0045.0exp 108.219o n()()737.4exp 108.219-⨯= or171045.2⨯=o n cm 3- We also have()⎥⎦⎤⎢⎣⎡--=kT E E N p F o υυexp Again, we can write()()υυE E E E E E a a F F -+-=- ForkT E E a F 3=- and045.0=-υE E a eV Then()⎥⎦⎤⎢⎣⎡--⨯=0259.0045.03exp 1004.119o p ()()737.4exp 1004.119-⨯= or161012.9⨯=o p cm 3-(b) GaAs: assume 0058.0=-d c E E eV Then()⎥⎦⎤⎢⎣⎡--⨯=30259.00058.0exp 107.417o n ()()224.3exp 107.417-⨯= or161087.1⨯=o n cm 3-Assume 0345.0=-υE E a eV Then()⎥⎦⎤⎢⎣⎡--⨯=30259.00345.0exp 10718o p ()()332.4exp 10718-⨯=or161020.9⨯=o p cm 3-_______________________________________ 4.33Plot_______________________________________ 4.34(a) 151510310154⨯=-⨯=o p cm 3- ()415210105.7103105.1⨯=⨯⨯=o n cm 3-(b) 16103⨯==d o N n cm 3- ()316210105.7103105.1⨯=⨯⨯=o p cm 3-(c) 10105.1⨯===i o o n p n cm 3-(d) ()()3191923003751004.1108.2⎪⎭⎫⎝⎛⨯⨯=in()()()()⎥⎦⎤⎢⎣⎡-⨯3750259.030012.1exp1110334.7⨯=⇒i n cm 3- 15104⨯==a o N p cm 3-()8152111034.110410334.7⨯=⨯⨯=on cm 3-(e) ()()3191923004501004.1108.2⎪⎭⎫⎝⎛⨯⨯=in()()()()⎥⎦⎤⎢⎣⎡-⨯4500259.030012.1exp1310722.1⨯=⇒i n cm 3-()2132141410722.1210210⨯+⎪⎪⎭⎫ ⎝⎛+=o n1410029.1⨯=cm 3-()12142131088.210029.110722.1⨯=⨯⨯=o p cm 3-_______________________________________ 4.35(a) 151510104-⨯=-=d a o N N p 15103⨯=cm 3-()3152621008.1103108.1-⨯=⨯⨯==o i o p n n cm 3-(b) 16103⨯==d o N n cm 3- ()416261008.1103108.1-⨯=⨯⨯=op cm 3-(c) 6108.1⨯===i o o n p n cm 3-(d) ()()318172300375100.7107.4⎪⎭⎫⎝⎛⨯⨯=in()()()()⎥⎦⎤⎢⎣⎡-⨯3750259.030042.1exp810580.7⨯=⇒i n cm 3- 15104⨯==a o N p cm 3-()215281044.110410580.7⨯=⨯⨯=on cm 3-(e) ()()318172300450100.7107.4⎪⎭⎫⎝⎛⨯⨯=in()()()()⎥⎦⎤⎢⎣⎡-⨯4500259.030042.1exp1010853.3⨯=⇒i n cm 3- 1410==d o N n cm 3-()7142101048.11010853.3⨯=⨯=op cm 3-_______________________________________ 4.36(a) Ge: 13104.2⨯=i n cm 3-(i)2222i dd o n N N n +⎪⎪⎭⎫ ⎝⎛+=()21321515104.221022102⨯+⎪⎪⎭⎫ ⎝⎛⨯+⨯=or15102⨯=≅d o N n cm 3-()152132102104.2⨯⨯==o i o n n p111088.2⨯= cm 3- (ii)151610710⨯-=-≅d a o N N p 15103⨯=cm 3- ()152132103104.2⨯⨯==o i o p n n111092.1⨯=cm 3-(b) GaAs: 6108.1⨯=i n cm 3- (i)15102⨯=≅d o N n cm()315261062.1102108.1-⨯=⨯⨯=op cm 3-(ii)15103⨯=-≅d a o N N p cm 3-()315261008.1103108.1-⨯=⨯⨯=on cm 3-(c) The result implies that there is only one minority carrier in a volume of 310cm 3. _______________________________________ 4.37(a) For the donor level⎪⎪⎭⎫ ⎝⎛-+=kT E E N n F d d d exp 2111⎪⎭⎫ ⎝⎛+=0259.020.0exp 2111or41085.8-⨯=dd N n(b) We have()⎪⎪⎭⎫ ⎝⎛-+=kT E E E f F F exp 11Now()()F c c F E E E E E E -+-=- or245.0+=-kT E E FThen()⎪⎭⎫ ⎝⎛++=0259.0245.01exp 11E f For()51087.2-⨯=E f F_______________________________________ 4.38(a) ⇒>d a N N p-type (b) Silicon:1313101105.2⨯-⨯=-=d a o N N p or13105.1⨯=o p cm 3- Then()7132102105.1105.1105.1⨯=⨯⨯==o i o p n n cm 3- Germanium:2222i da d a o n N N N N p +⎪⎪⎭⎫ ⎝⎛-+-=()21321313104.22105.12105.1⨯+⎪⎪⎭⎫⎝⎛⨯+⎪⎪⎭⎫ ⎝⎛⨯=or131026.3⨯=o p cm 3- Then()131321321076.110264.3104.2⨯=⨯⨯==o i o p n n cm 3-Gallium Arsenide:13105.1⨯=-=d a o N N p cm 3- and()216.0105.1108.113262=⨯⨯==o i o p n n cm 3- _______________________________________ 4.39(a) ⇒>a d N N n-type(b) 1515102.1102⨯-⨯=-≅a d o N N n 14108⨯=cm 3-()51421021081.2108105.1⨯=⨯⨯==o i o n n p cm 3-(c) ()d a ao N N N p -+'≅ 151515102102.1104⨯-⨯+'=⨯aN 15108.4⨯='⇒aN cm 3-()41521010625.5104105.1⨯=⨯⨯=on cm 3-_______________________________________ 4.40()155210210125.1102105.1⨯=⨯⨯==o i o p n n cm 3- ⇒>o o p n n-type_______________________________________ 4.41()()318192300250100.61004.1⎪⎭⎫⎝⎛⨯⨯=i n()()⎥⎦⎤⎢⎣⎡-⨯3002500259.066.0exp24108936.1⨯=1210376.1⨯=⇒i n cm 3- 2222414i o o i o i o n n n n p n n =⇒==i o n n 21=⇒So 111088.6⨯=o n cm 3-,Then 121075.2⨯=o p cm 3-2222i aa o n N N p +⎪⎪⎭⎫ ⎝⎛+= 212210752.2⎪⎪⎭⎫ ⎝⎛-⨯a N242108936.12⨯+⎪⎪⎭⎫ ⎝⎛=a N()21224210752.2105735.7⎪⎪⎭⎫ ⎝⎛+⨯-⨯aa N N 242108936.12⨯+⎪⎪⎭⎫ ⎝⎛=a N so that 1210064.2⨯=a N cm 3-_______________________________________ 4.42Plot_______________________________________ 4.43Plot_______________________________________ 4.44Plot_______________________________________ 4.452222i ad a d o n N N N N n +⎪⎪⎭⎫ ⎝⎛-+-= 2102.1102101.1141414⨯-⨯=⨯2214142102.1102i n +⎪⎪⎭⎫⎝⎛⨯-⨯+()()221321314104104101.1i n +⨯=⨯-⨯22727106.1109.4i n +⨯=⨯ so 131074.5⨯=i n cm 3-1314272103101.1103.3⨯=⨯⨯==o i o n n p cm 3- _______________________________________ 4.46(a) ⇒>d a N N p-typeMajority carriers are holes1616105.1103⨯-⨯=-=d a o N N p16105.1⨯=cm 3-Minority carriers are electrons()4162102105.1105.1105.1⨯=⨯⨯==o i o p n n cm 3- (b) Boron atoms must be addedd a ao N N N p -+'=161616105.1103105⨯-⨯+'=⨯aN So 16105.3⨯='aN cm 3-()316210105.4105105.1⨯=⨯⨯=o n cm 3-_______________________________________ 4.47(a) ⇒<<i o n p n-type (b) oi o o i o p n n n n p 22=⇒=on ()16421010125.1102105.1⨯=⨯⨯=cm 3-⇒electrons are majority carriers4102⨯=o p cm 3-⇒holes are minority carriers (c) a d o N N n -=151610710125.1⨯-=⨯d N so 1610825.1⨯=d N cm 3-_______________________________________ 4.48⎪⎪⎭⎫⎝⎛=-i o F Fi n p kT E E ln2222i a a o n N N p +⎪⎪⎭⎫ ⎝⎛+= and1510=N cm 3-_______________________________________ 4.49(a) ⎪⎪⎭⎫⎝⎛=-d c F c N N kT E E ln()⎪⎪⎭⎫⎝⎛⨯=d N 19108.2ln 0259.0 For 1410cm 3-, 3249.0=-F c E E eV 1510cm 3-, 2652.0=-F c E E eV 1610cm 3-, 2056.0=-F c E E eV 1710cm 3-, 1459.0=-F c E E eV(b) ⎪⎪⎭⎫⎝⎛=-i d Fi F n N kT E E ln()⎪⎪⎭⎫⎝⎛⨯=10105.1ln 0259.0d N For 1410cm 3-, 2280.0=-Fi F E E eV 1510cm 3-, 2877.0=-Fi F E E eV 1610cm 3-, 3473.0=-Fi F E E eV 1710cm 3-, 4070.0=-Fi F E E eV _______________________________________ 4.50(a) 2222i dd o n N N n +⎪⎪⎭⎫ ⎝⎛+= 151005.105.1⨯==d o N n cm 3- ()21515105.01005.1⨯-⨯()2215105.0i n +⨯=so 2821025.5⨯=i nNow()()3191923001004.1108.2⎪⎭⎫ ⎝⎛⨯⨯=T n i()()⎥⎦⎤⎢⎣⎡-⨯3000259.012.1exp T()3382830010912.21025.5⎪⎭⎫ ⎝⎛⨯=⨯T⎥⎦⎤⎢⎣⎡-⨯T 973.12972exp By trial and error, 5.536=T K (b) At 300=T K,⎪⎪⎭⎫⎝⎛=-o c F c n N kT E E ln()⎪⎪⎭⎫⎝⎛⨯=-151910108.2ln 0259.0F c E E2652.0=eV At 5.536=T K,()046318.03005.5360259.0=⎪⎭⎫⎝⎛=kT eV()2/3193005.536108.2⎪⎭⎫⎝⎛⨯=c N1910696.6⨯=cm 3-⎪⎪⎭⎫⎝⎛=-o c F c n N kT E E ln()⎪⎪⎭⎫⎝⎛⨯⨯=-15191005.110696.6ln 046318.0F c E E5124.0=eV then ()2472.0=-∆F c E E eV (c) Closer to the intrinsic energy level._______________________________________ 4.51⎪⎪⎭⎫⎝⎛=-i o F Fi n p kT E E ln At 200=T K, 017267.0=kT eV 400=T K, 034533.0=kT eV 600=T K, 0518.0=kT eVAt 200=T K,()()3191923002001004.1108.2⎪⎭⎫⎝⎛⨯⨯=in⎥⎦⎤⎢⎣⎡-⨯017267.012.1exp410638.7⨯=⇒i n cm 3- At 400=T K,()()3191923004001004.1108.2⎪⎭⎫⎝⎛⨯⨯=in⎥⎦⎤⎢⎣⎡-⨯034533.012.1exp 1210381.2⨯=⇒i n cm 3- At 600=T K,()()3191923006001004.1108.2⎪⎭⎫⎝⎛⨯⨯=in⎥⎦⎤⎢⎣⎡-⨯0518.012.1exp1410740.9⨯=⇒i n cm 3- At 200=T K and 400=T K, 15103⨯==a o N p cm 3- At 600=T K,2222i a a o n N N p +⎪⎪⎭⎫⎝⎛+=()2142151510740.921032103⨯+⎪⎪⎭⎫ ⎝⎛⨯+⨯=1510288.3⨯=cm 3-Then, 200=T K, 4212.0=-F Fi E E eV 400=T K, 2465.0=-F Fi E E eV600=T K, 0630.0=-F Fi E E eV_______________________________________ 4.52(a)()⎪⎪⎭⎫⎝⎛⨯=⎪⎪⎭⎫ ⎝⎛=-6108.1ln 0259.0ln a i a F Fi N n N kT E EFor 1410=a N cm 3-,4619.0=-F Fi E E eV1510=a N cm 3-,5215.0=-F Fi E E eV1610=a N cm 3-,5811.0=-F Fi E E eV1710=a N cm 3-,6408.0=-F Fi E E eV (b)()⎪⎪⎭⎫⎝⎛⨯=⎪⎪⎭⎫ ⎝⎛=-a a F N N N kT E E 18100.7ln 0259.0ln υυ For 1410=a N cm 3-,2889.0=-υE E F eV1510=a N cm 3-,2293.0=-υE E F eV1610=a N cm 3-,1697.0=-υE E F eV1710=a N cm 3-,1100.0=-υE E F eV_______________________________________ 4.53(a) ⎪⎪⎭⎫ ⎝⎛=-**ln 43n p midgap Fi m m kT E E ()()10ln 0259.043= or0447.0+=-midgap Fi E E eV(b) Impurity atoms to be added so 45.0=-F midgap E E eV (i) p-type, so add acceptor atoms (ii)4947.045.00447.0=+=-F Fi E E eV Then⎪⎪⎭⎫⎝⎛-=kT E E n p F Fi i o exp()⎪⎭⎫⎝⎛=0259.04947.0exp 105or131097.1⨯==a o N p cm 3-_______________________________________4.54()⎥⎦⎤⎢⎣⎡--=-=kT E E N N N n F c c a d o exp so()⎪⎭⎫⎝⎛-⨯+⨯=0259.0215.0exp 108.21051915d N15151095.6105⨯+⨯=or16102.1⨯=d N cm 3-_______________________________________ 4.55(a) Silicon(i)⎪⎪⎭⎫⎝⎛=-d c F c N N kT E E ln()2188.0106108.2ln 0259.01519=⎪⎪⎭⎫⎝⎛⨯⨯=eV(ii)1929.00259.02188.0=-=-F c E E eV()⎥⎦⎤⎢⎣⎡--=kT E E N N F c c d exp()⎥⎦⎤⎢⎣⎡-⨯=0259.01929.0exp 108.2191610631.1⨯=d N cm 3-15106⨯+'=dN 1610031.1⨯='⇒dN cm 3- Additionaldonor atoms (b) GaAs(i)()⎪⎪⎭⎫⎝⎛⨯=-151710107.4ln 0259.0F c E E15936.0=eV(ii)13346.00259.015936.0=-=-F c E E eV()⎥⎦⎤⎢⎣⎡-⨯=0259.013346.0exp 107.417d N1510718.2⨯=cm 3-1510+'=dN 1510718.1⨯='⇒dN cm 3- Additionaldonor atoms _______________________________________4.56 (a) ⎪⎪⎭⎫ ⎝⎛=-a F Fi N N kT E E υln()⎪⎪⎭⎫⎝⎛⨯⨯=16191021004.1ln 0259.01620.0=eV(b) ⎪⎪⎭⎫⎝⎛=-d c Fi F N N kT E E ln ()1876.0102108.2ln 0259.01619=⎪⎪⎭⎫⎝⎛⨯⨯=eV (c) For part (a); 16102⨯=o p cm 3-()162102102105.1⨯⨯==o i o p n n410125.1⨯=cm 3-For part (b): 16102⨯=o n cm 3-()162102102105.1⨯⨯==o i o n n p410125.1⨯=cm 3-_______________________________________4.57⎥⎦⎤⎢⎣⎡-=kT E E n n Fi F i o exp ()⎥⎦⎤⎢⎣⎡⨯=0259.055.0exp 108.1615100.3⨯=cm 3-Add additional acceptor impurities a d o N N n -= a N -⨯=⨯151510710315104⨯=⇒a N cm 3-_______________________________________ 4.58(a) ⎪⎪⎭⎫⎝⎛=-i o F Fi n p kT E E ln ()3161.0105.1103ln 0259.01015=⎪⎪⎭⎫⎝⎛⨯⨯=eV (b) ⎪⎪⎭⎫⎝⎛=-i o Fi F n n kT E E ln ()3758.0105.1103ln 0259.01016=⎪⎪⎭⎫⎝⎛⨯⨯=eV(c) Fi F E E =(d) ⎪⎪⎭⎫⎝⎛=-i o F Fi n p kT E E ln ()⎪⎪⎭⎫ ⎝⎛⨯⨯⎪⎭⎫ ⎝⎛=111510334.7104ln 3003750259.0 2786.0=eV(e) ⎪⎪⎭⎫ ⎝⎛=-i o Fi F n n kT E E ln()⎪⎪⎭⎫ ⎝⎛⨯⨯⎪⎭⎫ ⎝⎛=131410722.110029.1ln 3004500259.0 06945.0=eV _______________________________________ 4.59 (a) ⎪⎪⎭⎫ ⎝⎛=-o F p N kT E E υυln()2009.0103100.7ln 0259.01518=⎪⎪⎭⎫ ⎝⎛⨯⨯=eV(b) ()⎪⎪⎭⎫ ⎝⎛⨯⨯=--4181008.1100.7ln 0259.0υE E F 360.1=eV(c) ()⎪⎪⎭⎫⎝⎛⨯⨯=-618108.1100.7ln 0259.0υE E F7508.0=eV(d) ()⎪⎭⎫⎝⎛=-3003750259.0υE E F()()⎥⎥⎦⎤⎢⎢⎣⎡⨯⨯⨯152/318104300375100.7ln 2526.0=eV(e) ()⎪⎭⎫⎝⎛=-3004500259.0υE E F()()⎥⎥⎦⎤⎢⎢⎣⎡⨯⨯⨯72/3181048.1300450100.7ln 068.1=eV_______________________________________ 4.60n-type⎪⎪⎭⎫⎝⎛=-i o Fi F n n kT E E ln()3504.0105.110125.1ln 0259.01016=⎪⎪⎭⎫⎝⎛⨯⨯=eV ______________________________________ 4.612222i aa o n N N p +⎪⎪⎭⎫ ⎝⎛+= 21051008.51515⨯=⨯22152105i n +⎪⎪⎭⎫ ⎝⎛⨯+()21515105.21008.5⨯-⨯()2215105.2i n +⨯=230301025.6106564.6i n +⨯=⨯29210064.4⨯=⇒i n⎥⎦⎤⎢⎣⎡-=kT E N N n g c i exp 2υ()030217.03003500259.0=⎪⎭⎫⎝⎛=kT eV()1921910633.1300350102.1⨯=⎪⎭⎫ ⎝⎛⨯=c N cm 3-()192191045.2300350108.1⨯=⎪⎭⎫ ⎝⎛⨯=υN cm 3- Now()()1919291045.210633.110064.4⨯⨯=⨯⎥⎦⎤⎢⎣⎡-⨯030217.0exp g ESo()()()⎥⎦⎤⎢⎣⎡⨯⨯⨯=29191910064.41045.210633.1ln 030217.0g E 6257.0=⇒g E eV_______________________________________ 4.62(a) Replace Ga atoms ⇒Silicon acts as adonor()()1415105.310705.0⨯=⨯=d N cm 3-Replace As atoms ⇒Silicon acts as anacceptor()()15151065.610795.0⨯=⨯=a N cm 3-(b) ⇒>d a N N p-type(c) 1415105.31065.6⨯-⨯=-=d a o N N p 15103.6⨯=cm 3-()4152621014.5103.6108.1-⨯=⨯⨯==o i o p n n cm 3- (d) ⎪⎪⎭⎫⎝⎛=-i o F Fi n p kT E E ln()5692.0108.1103.6ln 0259.0615=⎪⎪⎭⎫⎝⎛⨯⨯=eV_______________________________________。