Quantization Concept
plank constant
2.3 Energy band theory
Core electrons
Valence electrons
Quantization Concept
Energy Band Formation (I) Band theory of solids
Two atoms brought together to form molecule splitting of energy levels for outer electron shells
The Shell Model
L shell with two sub shells Nucleus
1s K L 2s 2p
1s22s22p2 or [He]2s22p2
The shell model of the atom in which the electrons are confined to live within certain shells and in sub shells within shells.
�Energy Band Formation (I)
Energy Band Formation
Broadening of allowed energy levels into allowed energy bands separated by forbidden-energy gaps as more atoms influence each electron in a solid.
Allowed energy levels of an electron acted on by the Coulomb potential of an atomic nucleus.
Splitting of energy states into allowed bands separated by a forbidden energy gap as the atomic spacing decreases.
The electrical properties of a crystalline material correspond to specific allowed and forbidden energies associated with an atomic separation related to the lattice constant of the crystal.
One-dimensional representation
Two-dimensional diagram in which energy is plotted versus distance.
Energy Band Formation (III)
Conceptual development of the energy band model.
N isolated Si-atoms
Electron energy Electron energy
Energy Band Formation (II) Energy Bandgap
where no states exist
Electron energy
Pauli Exclusion Principle
Crystalline Si N -atoms 4N allowed-states (Conduction Band)
No states
Mostly empty
Etop Ec Ev Ebottom
Only 2 electrons, of spin 1/2, can occupy the same energy state at the same point in space. As atoms are brought closer towards one another and begin to bond together, their energy levels must split into bands of discrete levels so closely spaced in energy, they can be considered a continuum of allowed energy.
p s n=3
Eg
Mostly filled
6N p-states total 2N s-states total (4N electrons total)
4N allowed-states (Valance Band)
Electron energy
p s
4N empty states
2N+2N filled states
isolated Si atoms
Decreasing atom spacing
Si lattice spacing
Strongly bonded materials: small interatomic distances. Thus, the strongly bonded materials can have larger energy bandgaps than do weakly bonded materials.
�Energy Band Formation (Si)
Energy levels in Si as a function of inter-atomic spacing
The 2N electrons in the 3s sub-shell and the 2N electrons in the 3p sub-shell undergo sp3 hybridization.
Energy Band Formation
Energy levels in Si as a function of inter-atomic spacing
conduction band (empty)
valence band (filled)
The core levels (n=1,2) in Si are completely filled with electrons.
Energy Band Formation
Energy band diagrams.
N electrons filling half of the 2N allowed states, as can occur in a Metal.
A completely empty band separated by an energy gap Eg from a band whose 2N states are completely filled by 2N electrons, representative of an Insulator.
�Metals, Semiconductors, and Insulators
Typical band structures of Metal
Electron Energy,
Vacuum level
Chap. 2 Carrier Modeling 2.2 Semiconductor models
Metals, Semiconductors, and Insulators
Typical band structures of Semiconductor
Covalent bond Si ion core (+4e)
Free electron 3s Band 2 p Band
Electron energy, E
Ec+ Ec Band gap = Eg Ev
Valence Band (VB) Full of electrons at 0 K. ConductionBand(CB) Empty of electrons at 0 K.
E =0
Overlapping energy bands
3p 3s 2p 2s 2 s Band
Electrons
1s ATOM
1s
SOLID
In a metal the various energy bands overlap to give a single band of energies that is only partially full of electrons. There are states with energies up to the vacuum level where the electron is free.
A simplified two dimensional view of a region of the Si crystal showing covalent bonds.
The energy band diagram of electrons in the Si crystal at absolute zero of temperature.
Chap. 2 Carrier Modeling
Chap. 2 Carrier Modeling 2.2 Semiconductor models
Carrier Modeling
Electron Motion in Energy Band
Atomic Bonding in Solids
Ionic bonding Metallic bonding Covalent bonding Van der Waals bonding Mixed bonding
Current flowing
Energy Band Formation Metals, Semiconductors, and Insulators Electron Motion in Energy Band Energy Band Diagram Direct and Indirect Energy bandgap Electrons and Holes Effective Mass Impurity Doping (p-, n-type Semiconductors) Electron motion in an allowed band is analogous to fluid motion in a glass tube with sealed ends; the fluid can move in a half-filled tube just as electrons can move in a metal.
E=0
E0
�Chap. 2 Carrier Modeling 2.2 Semiconductor models
Chap. 2 Carrier Modeling 2.2 Semiconductor models
Electron Motion in Energy Band
Electron Motion in Energy Band
Fluid analogy for a Semiconductor
E=0
E0
No flow can occur in either the completely filled or completely empty tube.
No fluid motion can occur in a completely filled tube with sealed ends.
Fluid can move in both tubes if some of it is transferred from the filled tube to the empty one, leaving unfilled volume in the lower tube.
Chap. 2 Carrier Modeling
Chap. 2 Carrier Modeling 2.2 Semiconductor models
Carrier Modeling
Metals, Semiconductors, and Insulators
Atomic Bonding in Solids
Ionic bonding Metallic bonding Covalent bonding Van der Waals bonding Mixed bonding
Carrier Flow for Metal
Energy Band Formation Metals, Semiconductors, and Insulators Electron Motion in Energy Band Energy Band Diagram Direct and Indirect Energy bandgap Electrons and Holes Effective Mass Impurity Doping (p-, n-type Semiconductors)
Carrier Flow for Metals.mov
Carrier Flow for Semiconductor
Carrier Flow for Semiconductors.mov
�Chap. 2 Carrier Modeling 2.2 Semiconductor models
Metals, Semiconductors, and Insulators
Chap. 2 Carrier Modeling 2.2 Semiconductor models
Material Classification based on Size of Bandgap
Ease of achieving thermal population of conduction band determines whether a material is an insulator, metal, or semiconductor.
Typical band structures at 0 K.
Insulator
Semiconductor
Insulator
Semiconductor
Metal
Metal
Chap. 2 Carrier Modeling 2.2 Semiconductor models
Metals, Semiconductors, and Insulators
Range of conductivities exhibited by various materials.
Problem 2.18 (text book)
Insulators
Many ceramics Alumina Diamond Inorganic Glasses
Semiconductors
Conductors
Superconductors Metals
Degenerately doped Si Alloys Te Graphite NiCrAg
Mica Polypropylene PVDF Soda silica glass Borosilicate Pure SnO2 PET
SiO2
10-18 10-15
Amorphous Intrinsic GaAs As2Se3
10-12 10-9 10-6
Intrinsic Si
10-3
100
103
106
109
1012
Conductivity (m)-1
�Energy Band Diagram
E-k diagram, Bloch function.
PE(r) r
Energy Band Diagram
E-k diagram, Bloch function.
PE of the electron around an isolated atom When N atoms are arranged to form the crystal then there is an overlap of individual electron PE functions.
d 2 2m e + 2 [ E V ( x )] = 0 dx 2 h
Schrdinger equation
V ( x ) = V ( x + ma ) m = 1,2,3...
Periodic Potential
V(x) a 0 a
PE of the electron, V(x), inside the crystal is periodic with a period a.
x
x=L
k ( x ) = U k ( x ) e i k x
Periodic Wave function
x=0
2a
3a
Bloch Wavefunction
Moving through Lattice.mov
There are many Bloch wavefunction solutions to the one-dimensional crystal each identified with a particular k value, say kn which act as a kind of quantum number. Each k (x) solution corresponds to a particular kn and represents a state with an energy Ek.
Surface
Crystal
Surface
The electron potential energy [PE, V(x)], inside the crystal is periodic with the same periodicity as that of the crystal, a. Far away outside the crystal, by choice, V = 0 (the electron is free and PE = 0).
Chap. 2 Carrier Modeling 2.2 Semiconductor models
Energy Band Diagram
E-k diagram of a direct bandgap semiconductor
The E-k D iag ram
Ek
Energy Band Diagram
The energy is plotted as a function of the wave number, k, along the main crystallographic directions in the crystal. Si Ge GaAs
The Energy B and D iag ram
CB Conduction B and (CB ) Eg V alence B and (V B ) h+ Ev O ccupied k eEm pty k Ec h e-
Ec Ev
h+ VB
k
/a /a
The E-k curve consists of many discrete points with each point corresponding to a possible state, wavefunction k (x), that is allowed to exist in the crystal. The points are so close that we normally draw the E-k relationship as a continuous curve. In the energy range Ev to Ec there are no points [k (x), solutions].
The bottom axis describe different directions of the crystal.
�Chap. 2 Carrier Modeling 2.2 Semiconductor models
Chap. 2 Carrier Modeling 2.2 Semiconductor models
Energy Band Diagram
E-k diagram
Direct and Indirect Energy Band Diagram
E CB Direct Bandgap Eg VB k GaAs k k Ec Ev Photon
Indirect Bandgap, Eg CB kcb VB kvb Si Ec Ev k k VB Er
CB Ec Phonon Ev k
Si with a recombination center
In GaAs the minimum of the CB is directly above the maximum of the VB. direct bandgap semiconductor.
Recombination of an electron In Si, the minimum of the CB is displaced from the maximum of and a hole in Si involves a recombination center. the VB. indirect bandgap semiconductor
(a) Direct transition with accompanying photon emission. (b) Indirect transition via defect level.
Chap. 2 Carrier Modeling 2.2 Semiconductor models
Chap. 2 Carrier Modeling 2.2 Semiconductor models
Energy Band
A simplified energy band diagram with the highest almost-filled band and the lowest almost-empty band.
Metals vs. Semiconductors
Pertinent energy levels
vacuum level
: electron affinity
work function
work function
electron affinity
conduction band edge
valence band edge
Metal
Only the work function is given for the metal.
Semiconductor
Semiconductor is described by the work function qs, the electron affinity qs, and the band gap (Ec Ev).
�Chap. 2 Carrier Modeling 2.3 Carrier properties
Electrons and Holes
Generation of Electrons and Holes
Electron energy, E
Ec+
Electrons and Holes
Electrons: Electrons in the conduction band that are free to move throughout the crystal.
Holes:
Missing electrons normally found in the valence band (or empty states in the valence band that would normally be filled).
CB h > Eg
Ec
Free e Eg Hole h+
hole
Ev
VB
0
A photon with an energy greater then Eg can excitation an electron from the VB to the CB.
Each line between Si-Si atoms is a valence electron in a bond. When a photon breaks a Si-Si bond, a free electron and a hole in the Si-Si bond is created.
These particles carry electricity. Thus, we call these carriers
Effective Mass (I)
Carrier Movement Within the Crystal
An electron moving in respond to an applied electric field. E E
Density of States Effective Masses at 300 K
within a Vacuum within a Semiconductor crystal
F = q E = mn
F = q E = m0
dv dt
dv dt
Ge and GaAs have lighter electrons than Si which results in faster devices
( m0 = Electron rest mass, 9.11x10-31 kg )
It allow us to conceive of electron and holes as quasi-classical particles and to employ classical particle relationships in semiconductor crystals or in most device analysis.
�Chap. 2 Carrier Modeling 2.2 Semiconductor models
Effective Mass (II)
Electrons are not free but interact with periodic potential of the lattice. Wave-particle motion is not as same as in free space.
Energy Band Diagram
The energy is plotted as a function of the wave number, k, along the main crystallographic directions in the crystal. Si Ge GaAs
p = hk
E = h
Plank-Einstein-De Broglie Relation
Moving through Lattice.mov
The bottom axis describe different directions of the crystal.
Curvature of the band determine m*. m* is positive in CB min., negative in VB max.
Exercise
Indicate where the effective mass of the electron is greatest and least on the band diagram.
Effective Mass Approximation
The motion of electrons in a crystal can be visualized and described in a quasi-classical manner. In most instances The electron can be thought of as a particle. The electronic motion can be modeled using Newtonian mechanics. The effect of crystalline forces and quantum mechanical properties are incorporated into the effective mass factor. m* > 0 : near the bottoms of all bands m* < 0 : near the tops of all bands Carriers in a crystal with energies near the top or bottom of an energy band typically exhibit a constant (energy-independent) effective mass. `
d 2E 2 = constant : near band edge dk
�Chap. 2 Carrier Modeling 2.3 Carrier properties
Covalent Bonding
Covalent Bonding
Chap. 2 Carrier Modeling 2.3 Carrier properties
Band Occupation at Low Temperature (0 K)
Band Occupation at Low Temperature (0 K)
�Chap. 2 Carrier Modeling 2.3 Carrier properties
Band Occupation at Low Temperature (0 K)
Band Occupation at Low Temperature (0 K)
Chap. 2 Carrier Modeling 2.3 Carrier properties
Chap. 2 Carrier Modeling 2.3 Carrier properties
Impurity Doping
Concept of a Donor Adding extra Electrons
The need for more control over carrier concentration
Without help the total number of carriers (electrons and holes) is limited to 2ni. For most materials, this is not that much, and leads to very high resistance and few useful applications. We need to add carriers by modifying the crystal. This process is known as doping the crystal.
Regarding Doping, ...
�Chap. 2 Carrier Modeling 2.3 Carrier properties
Chap. 2 Carrier Modeling 2.3 Carrier properties
Concept of a Donor Adding extra Electrons
Binding Energies of Impurity
Hydrogen Like Impurity Potential (Binding Energies)
Effective mass should be used to account the influence of the periodic potential of crystal. Relative dielectric constant of the semiconductor should be used (instead of the free space permittivity). : Electrons in donor atoms : Holes in acceptor atoms
Binding energies in Si: 0.03 ~ 0.06 eV Binding energies in Ge: ~ 0.01 eV
Chap. 2 Carrier Modeling 2.3 Carrier properties
Chap. 2 Carrier Modeling 2.3 Carrier properties
Impurity Doping
Concept of a Donor Adding extra Electrons
Band diagram equivalent view
Donor
Acceptor
�Chap. 2 Carrier Modeling 2.3 Carrier properties
Chap. 2 Carrier Modeling 2.3 Carrier properties
Concept of a Donor Adding extra Electrons
Concept of a Donor Adding extra Electrons
V(x), PE (x) V(x)
n-type Impurity Doping of Si
Electron Energy
Electron Energy
x
PE (x) = eV
Energy Band Diagram in an Applied Field
E CB e As+ Ec ~0.05 eV E d As+ As+ As+ As+
Ec EF Ev E c eV E F eV
Energy band diagram of an n-type semiconductor connected to a voltage supply of V volts. The whole energy diagram tilts because the electron now has an electrostatic potential energy as well. Current flowing
Ev As atom sites every 106 Si atoms
Distance into crystal
A B
E v eV
The four valence electrons of As allow it to bond just like Si but the 5th electron is left orbiting the As site. The energy required to release to free fifth- electron into the CB is very small.
Energy band diagram for an n-type Si doped with 1 ppm As. There are donor energy levels just below Ec around As+ sites.
n-Type Semiconductor
Chap. 2 Carrier Modeling 2.3 Carrier properties
Concept of a Acceptor Adding extra Holes
Hole Movement
All regions of material are neutrally charged
One less bond means the acceptor is electrically satisfied.
One less bond means the neighboring Silicon is left with an empty state.
(Really it is thethe Acceptor leaving behind a positively charged hole. valance electrons jumping from atom to atom that creates the hole motion)
The positively charged hole cantheto the Acceptor the crystal. Another Empty state is located next empty state located next to valence electron can fill move throughout
�Chap. 2 Carrier Modeling 2.3 Carrier properties
Chap. 2 Carrier Modeling 2.3 Carrier properties
Hole Movement
Concept of a Acceptor Adding extra Holes
Band diagram equivalent view Region around the acceptor has one extra electron and thus is negatively charged.
Region around the hole has one less electron and thus is positively charged.
The positively charged hole can move throughout the crystal.
(Really it is the valance electrons jumping from atom to atom that creates the hole motion)
Chap. 2 Carrier Modeling 2.3 Carrier properties
Chap. 2 Carrier Modeling 2.3 Carrier properties
Concept of a Acceptor Adding extra Holes
p-type Impurity Doping of Si
Electron energy B atom sites every 106 Si atoms
Intrinsic, n-Type, p-Type Semiconductors
Energy band diagrams
Ec
h+
B
x Distance
CB Ec EFi Ec EFn Ev Ec EFp Ev
into crystal
Ea Ev
B h+
~0.05 eV
VB
Ev VB
Boron doped Si crystal. B has only three valence electrons. When it substitute for a Si atom one of its bond has an electron missing and therefore a hole.
Energy band diagram for a p-type Si crystal doped with 1 ppm B. There are acceptor energy levels just above Ev around B- site. These acceptor levels accept electrons from the VB and therefore create holes in the VB.
Intrinsic semiconductors In all cases,
n-type semiconductors
p-type semiconductors
np=ni2
Note that donor and acceptor energy levels are not shown.
�Chap. 2 Carrier Modeling 2.3 Carrier properties
Chap. 2 Carrier Modeling 2.3 Carrier properties
Heavily Doped n-Type, p-Type Semiconductors
Impurity Doping
E CB
Impurities forming a band
EFn Ec Ev
CB
Ec Ev EFp VB
Degenerate p-type semiconductor
g(E)
Degenerate n-type semiconductor. Large number of donors form a band that overlaps the CB.
Chap. 2 Carrier Modeling 2.3 Carrier properties
Impurity Doping
Donor / Acceptor Levels (Band Model)
Donor Level ED Ec
Donor ionization energy
Acceptor Level
Acceptor ionization energy
Valence Band
EA
Ev
Ionization energy of selected donors and acceptors in silicon
Donors
Dopant Ionization energy, E c -E d or E a -E v (meV) Sb 39 P 45 As 54 B 45
Acceptors
Al 67 In 160
Valence Band
�Impurity Doping
Position of energy levels within the bandgap of Si for common dopants.
donor: impurity atom that increases n acceptor: impurity atom that increases p n-type material: contains more electrons than holes p-type material: contains more holes than electrons majority carrier: the most abundant carrier minority carrier: the least abundant carrier intrinsic semiconductor: n = p = ni extrinsic semiconductor: doped semiconductor
Terminology
Summary of Important terms and symbols
The band gap energy is the energy required to free an electron from a covalent bond.
EG for Si at 300K = 1.12eV Insulators have large EG; semiconductors have small EG
Summary
Dopants in Si:
Reside on lattice sites (substituting for Si) Group-V elements contribute conduction electrons, and are call ed donors Group-III elements contribute holes, and are called acceptors Very low ionization energies (<50 meV) ionized at room temperature
Dopant concentrations typically range from 1014 cm-3 to 1020 cm3
Bandgap Energy: Energy required to remove a valence electron and allow it to freely conduct. Intrinsic Semiconductor: A native semiconductor with no dopants. Electrons in the conduction band equal holes in the valence band. The concentration of electrons (=holes) is the intrinsic concentration, ni. Extrinsic Semiconductor: A doped semiconductor. Many electrical properties controlled by the dopants, not the intrinsic semiconductor. Donor: An impurity added to a semiconductor that adds an additional electron not found in the native semiconductor. Acceptor: An impurity added to a semiconductor that adds an additional hole not found in the native semiconductor. Dopant: Either an acceptor or donor. N-type material: When electron concentrations (n=number of electrons/cm3) exceed the hole concentration (normally through doping with donors). P-type material: When hole concentrations (p=number of holes/cm3) exceed the electron concentration (normally through doping with acceptors). Majority carrier: The carrier that exists in higher population (i.e. n if n>p, p if p>n) Minority carrier: The carrier that exists in lower population (i.e. n if n<p, p if p<n) Other important terms: Insulator, semiconductor, metal, amorphous, polycrystalline, crystalline (or single crystal), lattice, unit cell, primitive unit cell, zincblende, lattice constant, elemental semiconductor, compound semiconductor, binary, ternary, quaternary, atomic density, Miller indices
