Lecture Electrical Engineering: Lecture 6 - Dr. Nasim Zafar

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COMSATS Institute of Information Technology Virtual campus Islamabad Dr. Nasim Zafar Electronics 1 EEE 231 – BS Electrical Engineering Fall Semester – 2012 Revision: 1. Semiconductor Materials:  Elemental semiconductors  Intrinsic and Extrinsic Semiconductor  Compound semiconductors III – V II – V  Gap, GaAs e.g ZnS, CdTe Mixed or Tertiary Compounds e.g. GaAsP 2. Applications: • Si  diodes, rectifiers, transistors and integrated circuits etc • GaAs, GaP  emission and absorption of light • ZnS  fluorescent materials Revision: 3. The Band Theory of Solids Quantum Mechanics  discrete energy levels E  2 4 mo Z e  2 4  o n  2 – S1 – P3 – model for four valency – Si – atom in the diamond lattice  four nearest neighbors – Sharing of four electrons  S1 – P3 – level, the covalent bonding! Pauli’s Exclusion principle for overlapping S 1 – P3 electron wave functions  Bands Revision: 4. Band Gap and Material Classification Insulators  Eg: 5 – 8 eV Semiconductor  Eg: 0.66 eV – 2/3 eV Metals  overlapping The classification takes into account i. Electronic configuration ii. Energy Band-gap Examples: Wide: Eg  5 eV (diamond) Eg ~ 8 eV (SiO2) Narrow: Eg = Si = 1.12, GaAs = 1.42 5. Charge Carriers in Semiconductors Electrons and Holes in Semiconductors • Intrinsic Materials • Doped – Extrinsic Materials • Effective Mass E  Hydrogenic Model: B  M n e 4 2  4      0 s   2 M n 1  . E  0.1eV Mo  2 H s E 0.045~ 0.072 B (P) (Ga) Lecture No: 6 P-N Junction - Semiconductor Diodes Outcome: Upon completion of this topic on P-N Junctions, you will be able to appreciate: • Knowledge of the formation of p-n junctions to explain the diode operation and to draw its I-V characteristics. so that you can draw the band diagram to explain their I-V characteristics and functionalities. • Diode break down mechanisms; including the Avalanche breakdown and Zenor break down; The Zener Diodes. • Understanding of the operation mechanism of solar cells, LEDs, lasers and FETs. Semiconductor Devices: Semiconductor devices are electronic components that use the electronic properties of semiconductor materials, principally ; silicon, germanium, and gallium arsenide. Semiconductor devices include various types of Semiconductor Diodes, Solar Cells, light-emitting diodes LEDs. Bipolar Junction Transistors. Silicon controlled rectifier, digital and analog integrated circuits. Solar Photovoltaic panels are large semiconductor devices that directly convert light energy into electrical energy. Dr. Nasim Zafar THE P-N JUNCTION The P-N Junction  The “potential” or voltage across the silicon changes in the depletion region and goes from + in the n region to – in the p region The P-N Junction Formation of depletion region in PN Junction Forward Biased P N-Junction Depletion Region and Potential Barrier Reduces Biased P-N Junction – Biased P-N Junction, i.e. P-N Junction with voltage applied across it – Forward Biased: p-side more positive than n-side; – Reverse Biased: n-side more positive than p-side; – Forward Biased Diode: • the direction of the electric field is from p-side towards n-side •  p-type charge carriers (positive holes) in p-side are pushed towards and across the p-n boundary, • n-type carriers (negative electrons) in n-side are pushed towards and across n-p boundary  current flows across p-n boundary Introduction: Semiconductor Electronics owes its rapid development to the P-N junctions. P-N junction is the most elementary structure used in semiconductor devices and microelectronics and opto-electronics. The most common junctions that occur in micro electronics are the P-N junctions and the metal-semiconductor junctions. Junctions are also made of different (not similar) semiconductor materials or compound semiconductor materials. This class of devices is called the heterojunctions; they are important in special applications such as high speed and photonic devices. There is , of course, an enormous choice available for semiconductor materials and compound semiconductors that can be joined/used. A major requirement is that the dissimilar materials must fit each other; the crystal structure in some way should be continuous. Intensive research is on and there are attempts to combine silicon technology with other semiconductor materials. Reverse biased diode – reverse biased diode: applied voltage makes n-side more positive than p-side  electric field direction is from n-side towards p-side  pushes charge carriers away from the p-n boundary  depletion region widens, and no current flows – diode only conducts when positive voltage applied to p-side and negative voltage to nside – diodes used in “rectifiers”, to convert ac voltage to dc. Reverse biased diode Depletion region becomes wider, barrier potential higher P-N Junctions - Semiconductor Diodes: Introduction Fabrication Techniques Equilibrium & Non-Equilibrium Conditions: • • Forward and Reverse Biased Junctions Current-Voltage (I-V ) Characteristics Introduction: p-n junction = semiconductor in which impurity changes abruptly from p-type to n-type ; “diffusion” = movement due to difference in concentration, from higher to lower concentration; in absence of electric field across the junction, holes “diffuse” towards and across boundary into n-type and capture electrons; electrons diffuse across boundary, fall into holes (“recombination of majority carriers”);  formation of a “depletion region” (= region without free charge carriers) around the boundary; charged ions are left behind (cannot move): negative ions left on p-side  net negative charge on p-side of the junction; positive ions left on n-side  net positive charge on n-side of the junction  electric field across junction which prevents further diffusion Fabrication Techniques: Epitaxial Growth Technique Diffusion Method Ion Implant Epitaxial Growth of Silicon • Epitaxy grows additional silicon on top of existing silicon (substrate) – uses chemical vapor deposition – new silicon has same crystal structure as original • Silicon is placed in chamber at high temperature – 1200 o C (2150 o F) • Appropriate gases are fed into the chamber – other gases add impurities to the mix • Can grow n type, then switch to p type very quickly Diffusion Method • It is also possible to introduce dopants into silicon by heating them so they diffuse into the silicon top High temperatures cause diffusion • Can be done with constant concentration in atmosphere • Or with constant number of atoms per unit area • Diffusion causes spreading of doped areas side Ion Implantation of Dopants • One way to reduce the spreading found with diffusion is to use ion implantation: – also gives better uniformity of dopant – yields faster devices – lower temperature process • Ions are accelerated from 5 Kev to 10 Mev and directed at silicon – higher energy gives greater depth penetration – total dose is measured by flux • number of ions per cm2 • typically 1012 per cm2 - 1016 per cm2 • Flux is over entire surface of silicon I-V I-VCharacteristics Characteristics of of PN PN Junctions Junctions  Diode characteristics * Forward bias current * Reverse bias current Kwangwoon University Semiconductor Devices. device lab. Ideal I-V Characteristics 1) The abrupt depletion layer approximation applies. - abrupt boundaries & neutral outside of the depletion region 2) The Maxwell-Boltzmann approximation applies. 3) The Concept of low injection applies. Biasing the P-N Junction THINK OF THE DIODE AS A SWITCH Forward Bias Reverse Bias Applies - voltage to the n region and + voltage to the p region Applies + voltage to n region and – voltage to p region CURRENT! NO CURRENT Depletion region, Space-Charge Region: • Region of charges left behind: The diffusion of electrons and holes, mobile charge carriers, creates ionized impurity across the p n junction. • • • Region is totally depleted of mobile charges - depletion region The space charge in this region is determined mainly by the ionized acceptors (- q NA) and the ionized donors (+qND). Electric field forms due to fixed charges in the depletion region (Built-in-Potential). •Depletion region has high resistance due to lack of mobile charges. Current-Voltage Characteristics THE IDEAL DIODE Positive voltage yields finite current Negative voltage yields zero current REAL DIODE Various Current Components VA = 0 E p VA < 0 VA > 0 E n Hole diffusion current E p Hole diffusion current Hole drift current n Hole diffusion current Hole drift current e drift current Electron diffusion current Electron drift current Electron diffusion current Electron drift current Electron diffusion current Electron drift current 30 Qualitative Description of Current Flow Equilibrium Reverse bias Forward bias P-N Junction–Forward Bias • positive voltage placed on p-type material • holes in p-type move away from positive terminal, electrons in ntype move further from negative terminal • depletion region becomes smaller - resistance of device decreases • voltage increased until critical voltage is reached, depletion region disappears, current can flow freely P-N Junction–Reverse Bias • positive voltage placed on n-type material • electrons in n-type move closer to positive terminal, holes in p-type move closer to negative terminal • width of depletion region increases • allowed current is essentially zero (small “drift” current) Forward Biased Junctions Effects of Forward Bias on Diffusion Current: When the forward-bias-voltage of the diode is increased, the barrier for electron and hole diffusion current decreases linearly. Since the carrier concentration decreases exponentially with energy in both bands, diffusion current increases exponentially as the barrier is reduced. As the reverse-bias-voltage is increased, the diffusion current decrease rapidly to zero, since the fall-off in current is exponential. 34 Reverse Biased Junction Effect of Reverse Bias on Drift current When the reverse-bias-voltage is increased, the net electric field increases, but drift current does not change. In this case, drift current is limited NOT by HOW FAST carriers are swept across the depletion layer, but rather HOW OFTEN. The number of carriers drifting across the depletion layer is small because the number of minority carriers that diffuse towards the edge of the depletion layer is small. To a first approximation, the drift current does not change with the applied voltage. 35  Current-Voltage Relationship Quantitative Approach Kwangwoon University Semiconductor Devices. device lab. Application of PN Junctions BJT (Bipolar Junction Transistor) P N J U N C T I O N HBT (Heterojunction Bipolar Transistor) Rectifiers Switching diode Junction diode Tunnel diode PN Junction diode Photo-diode Breakdown diode Varactor diode Solar cell Photodetector Light Emitting diode & Laser Diode JFET FET (Field Effect Transistor) MOSFET - memory MESFET - HEMT Semiconductor Devices Summary: Semiconductor Devices: Semiconductor Diodes, Solar Cells, LEDs. Bipolar Junction Transistors. Solar Photovoltaic Biased P-N Junction: – Forward Biased: p-side more positive than n-side; – Reverse Biased: n-side more positive than p-side; Fabrication Techniques: Epitaxial Growth Technique Diffusion Method Ion Implant Current-Voltage Relationship P-N Junction I-V characteristics Voltage-Current relationship for a p-n junction (diode) Boundary Conditions: Vbi Vt ln Na Nd (Vbi : built  in potential barrier ) ni If forward bias is applied to the PN junction n p  n po P n  P no eV a exp( ) kT eV a exp( ) kT Minority Carrier Distribution  n  rigion D p   2 (  p n ( x ))   2 x p E Steady state condition :  (  p n ( x )) pn  (  p n ( x ))  g '  x  po t (Pn ( x)) 0, g ' 0, E 0 t V x  x pn ( x)  pno [exp( a )  1] exp( n ) Vt Ln Steady state condition : xp  x eVa n p ( x) n po [exp( )  1] exp( ) kT Ln Semiconductor Devices Ideal PN Junction Current J p ( xn )  eD p J p ( xn )  dpn ( x) dx eD p pno Lp x xn V [exp( a )  1] Vt Similarly , J n (  x p ) eDn J n ( x p )  dn p ( x) dx eDn p po Ln x  x p V [exp( a )  1] Vt J J n (  x p )  J p ( xn ) J s (eVa J s ( eD p pno Lp  Vt  1) eDn n po Ln ) Semiconductor Devices Forward Bias Recombination Current Recombination rate of excess carriers (Shockley-Read-Hall model) 2 R CnC p N t (np  ni ) C n ( n  n' )  C p ( p  p ' ) (np  ni2 ) R  po (n  n)   no ( p  p) R = Rmax at x=o Rmax ni eVa  exp( ) 2 0 2kT w J rec  eRdx  0 eWni eV exp( a ) 2 o 2kT J rec  J ro exp( eV a ) 2 kT Semiconductor Devices Reverse Bias-Generation Current Recombination rate of excess carriers (Shockley-Read-Hall model) Total reverse bias current density, JR J R J s  J gen In depletion region, n=p=0 Js  eD p pno Et Ei일때 2 R CnC p N t (np  ni ) C n ( n  n' )  C p ( p  p ' ) R  CnC p N t ni 2 Cn n'C p p '  G Lp  eDn n po Ln J gen ni  e W 2 o n  p ni  po  no  o일 때 R  ni 2 o J gen e Rdx  ni e W  G 2 o Semiconductor Devices Total Forward Bias Current Total forward bias current density, J J J rec  J D J rec J ro exp( eV a ) 2 kT ln J rec ln J D eVa ro 2 kT eVa  ln J s  kT  ln J  eVa J  J s exp[  1] kT In general, (n : ideality factor) eVa I  I S [exp( )  1], nkT (1  n  2 ) Semiconductor Devices Application of PN Junctions BJT (Bipolar Junction Transistor) P N J U N C T I O N HBT (Heterojunction Bipolar Transistor) Rectifiers Switching diode Junction diode Tunnel diode PN Junction diode Photo-diode Breakdown diode Varactor diode Solar cell Photodetector Light Emitting diode & Laser Diode JFET FET (Field Effect Transistor) MOSFET - memory MESFET - HEMT Semiconductor Devices Summary: Semiconductor Devices: Semiconductor Diodes, Solar Cells, LEDs. Bipolar Junction Transistors. Solar Photovoltaic Biased P-N Junction: – Forward Biased: p-side more positive than n-side; – Reverse Biased: n-side more positive than p-side; Fabrication Techniques: Epitaxial Growth Technique Diffusion Method Ion Implant Current-Voltage Relationship
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