EECS143 Microfabrication Technology

Similar documents
EE143 Fall 2016 Microfabrication Technologies. Evolution of Devices

EECS130 Integrated Circuit Devices

Lecture 1. OUTLINE Basic Semiconductor Physics. Reading: Chapter 2.1. Semiconductors Intrinsic (undoped) silicon Doping Carrier concentrations

Semiconductor Device Physics

Lecture 2 Electrons and Holes in Semiconductors

Lecture 3b. Bonding Model and Dopants. Reading: (Cont d) Notes and Anderson 2 sections

EE130: Integrated Circuit Devices

Semiconductors. Semiconductors also can collect and generate photons, so they are important in optoelectronic or photonic applications.

Chapter 1 Overview of Semiconductor Materials and Physics

ELECTRONIC I Lecture 1 Introduction to semiconductor. By Asst. Prof Dr. Jassim K. Hmood

Bohr s Model, Energy Bands, Electrons and Holes

Crystal Properties. MS415 Lec. 2. High performance, high current. ZnO. GaN

Solid State Device Fundamentals

Lecture 2. Semiconductor Physics. Sunday 4/10/2015 Semiconductor Physics 1-1

EE301 Electronics I , Fall

Review of Semiconductor Fundamentals

Semiconductor physics I. The Crystal Structure of Solids

smal band gap Saturday, April 9, 2011

1 Review of semiconductor materials and physics

Chapter 1 Semiconductor basics

Basic cell design. Si cell

A semiconductor is an almost insulating material, in which by contamination (doping) positive or negative charge carriers can be introduced.

Atoms? All matters on earth made of atoms (made up of elements or combination of elements).

Engineering 2000 Chapter 8 Semiconductors. ENG2000: R.I. Hornsey Semi: 1

CHAPTER 2: ENERGY BANDS & CARRIER CONCENTRATION IN THERMAL EQUILIBRIUM. M.N.A. Halif & S.N. Sabki

ELECTRONIC DEVICES AND CIRCUITS SUMMARY

Lecture 7: Extrinsic semiconductors - Fermi level

Ch. 2: Energy Bands And Charge Carriers In Semiconductors

EE495/695 Introduction to Semiconductors I. Y. Baghzouz ECE Department UNLV

Introduction to Engineering Materials ENGR2000. Dr.Coates

Basic Semiconductor Physics

Key Questions. ECE 340 Lecture 6 : Intrinsic and Extrinsic Material I 9/10/12. Class Outline: Effective Mass Intrinsic Material

Electrical Resistance

3.1 Introduction to Semiconductors. Y. Baghzouz ECE Department UNLV

Semiconductors. SEM and EDAX images of an integrated circuit. SEM EDAX: Si EDAX: Al. Institut für Werkstoffe der ElektrotechnikIWE

UNIVERSITY OF CALIFORNIA College of Engineering Department of Electrical Engineering and Computer Sciences. EECS 130 Professor Ali Javey Fall 2006

The Semiconductor in Equilibrium

Lecture 2. Unit Cells and Miller Indexes. Reading: (Cont d) Anderson 2 1.8,

First-Hand Investigation: Modeling of Semiconductors

ESE 372 / Spring 2013 / Lecture 5 Metal Oxide Semiconductor Field Effect Transistor

ECE 250 Electronic Devices 1. Electronic Device Modeling

ECE 442. Spring, Lecture -2

Direct and Indirect Semiconductor

Introduction to Semiconductor Physics. Prof.P. Ravindran, Department of Physics, Central University of Tamil Nadu, India

LECTURE 23. MOS transistor. 1 We need a smart switch, i.e., an electronically controlled switch. Lecture Digital Circuits, Logic

EE 346: Semiconductor Devices

Solid State Device Fundamentals

UNIVERSITY OF CALIFORNIA College of Engineering Department of Electrical Engineering and Computer Sciences. Professor Ali Javey. Spring 2009.

Semiconductors 1. Explain different types of semiconductors in detail with necessary bond diagrams. Intrinsic semiconductors:

Charge Carriers in Semiconductor

Chap. 11 Semiconductor Diodes

CLASS 12th. Semiconductors

EE 346: Semiconductor Devices. 02/08/2017 Tewodros A. Zewde 1

Chemistry Instrumental Analysis Lecture 8. Chem 4631

EE 446/646 Photovoltaic Devices I. Y. Baghzouz

Calculating Band Structure

Review of Optical Properties of Materials

Electrons are shared in covalent bonds between atoms of Si. A bound electron has the lowest energy state.

Solid State Electronics EC210 Arab Academy for Science and Technology AAST Cairo Fall Lecture 10: Semiconductors

ECE 340 Lecture 6 : Intrinsic and Extrinsic Material I Class Outline:

Electronics The basics of semiconductor physics

Three Most Important Topics (MIT) Today

ESE370: Circuit-Level Modeling, Design, and Optimization for Digital Systems

Solid State Device Fundamentals

Course overview. Me: Dr Luke Wilson. The course: Physics and applications of semiconductors. Office: E17 open door policy

UConn ECE 4211, Semiconductor Devices and Nanostructures Lecture Week 1 January 17, 2017

LN 3 IDLE MIND SOLUTIONS

Electron Energy, E E = 0. Free electron. 3s Band 2p Band Overlapping energy bands. 3p 3s 2p 2s. 2s Band. Electrons. 1s ATOM SOLID.

EXTRINSIC SEMICONDUCTOR

Ga and P Atoms to Covalent Solid GaP

David J. Starling Penn State Hazleton PHYS 214

Lecture 1. Introduction to Electronic Materials. Reading: Pierret 1.1, 1.2, 1.4,

Chapter 12: Semiconductors

Section 12: Intro to Devices

Diamond. Covalent Insulators and Semiconductors. Silicon, Germanium, Gray Tin. Chem 462 September 24, 2004

The Periodic Table III IV V

SEMICONDUCTOR PHYSICS

UNIVERSITY OF CALIFORNIA College of Engineering Department of Electrical Engineering and Computer Sciences. Fall Exam 1

Semiconductor Devices and Circuits Fall Midterm Exam. Instructor: Dr. Dietmar Knipp, Professor of Electrical Engineering. Name: Mat. -Nr.

EE 5211 Analog Integrated Circuit Design. Hua Tang Fall 2012

Semiconductor Fundamentals. Professor Chee Hing Tan

Advantages / Disadvantages of semiconductor detectors

Lecture 2 - Carrier Statistics in Equilibrium. September 5, 2002

The photovoltaic effect occurs in semiconductors where there are distinct valence and

Classification of Solids

Lecture 02 Semiconductor Physics

Recitation 2: Equilibrium Electron and Hole Concentration from Doping

Mat E 272 Lecture 25: Electrical properties of materials

Qualitative Picture of the Ideal Diode. G.R. Tynan UC San Diego MAE 119 Lecture Notes

Semiconductor Detectors

CLASS 1 & 2 REVISION ON SEMICONDUCTOR PHYSICS. Reference: Electronic Devices by Floyd

! Previously: simple models (0 and 1 st order) " Comfortable with basic functions and circuits. ! This week and next (4 lectures)

Semiconductor-Detectors

ECE 335: Electronic Engineering Lecture 2: Semiconductors

ESE370: Circuit-Level Modeling, Design, and Optimization for Digital Systems

I. Introduction II. Solid State Physics Detection of Light Bernhard Brandl 1

Section 12: Intro to Devices

Molecules and Condensed Matter

Minimal Update of Solid State Physics

KATIHAL FİZİĞİ MNT-510

Transcription:

EECS143 Microfabrication Technology Professor Ali Javey Introduction to Materials Lecture 1

Evolution of Devices Yesterday s Transistor (1947) Today s Transistor (2006)

Why Semiconductors? Conductors e.g Metals Insulators e.g. Sand (SiO 2 ) Semiconductors conductivity between conductors and insulators Generally crystalline in structure In recent years, non-crystalline semiconductors have become commercially very important Polycrystalline amorphous crystalline

What are semiconductors Elements: Si, Ge, C Binary: GaAs, InSb, SiC, CdSe, etc. Ternary+: AlGaAs, InGaAs, etc.

Electrons and Holes in Semiconductors Silicon Crystal Structure Unit cell of silicon crystal is cubic. Each Si atom has 4 nearest neighbors. 5.43 Å

Silicon Wafers and Crystal Planes z z z y y y x (100) x x (011) (111) The standard notation for crystal planes is based on the cubic unit cell. (011) flat (100) plane Si (111) plane Silicon wafers are usually cut along the (100) plane with a flat or notch to help orient the wafer during IC fabrication.

Bond Model of Electrons and Holes (Intrinsic Si) Si Si Si Si Si Si Si Si Si Silicon crystal in a two-dimensional representation. Si Si Si Si Si Si Si Si Si Si Si Si Si Si Si Si Si Si When an electron breaks loose and becomes a conduction electron, a hole is also created.

Dopants in Silicon Si Si Si Si Si Si Si As Si Si B Si Si Si Si N-type Si Si Si Si P-type Si As (Arsenic), a Group V element, introduces conduction electrons and creates N-type silicon, and is called a donor. B (Boron), a Group III element, introduces holes and creates P-type silicon, and is called an acceptor. Donors and acceptors are known as dopants.

Types of charges in semiconductors Hole Electron Mobile Charge Carriers they contribute to current flow with electric field is applied. Ionized Donor Ionized Acceptor Immobile Charges they DO NOT contribute to current flow with electric field is applied. However, they affect the local electric field EE143 Vivek Subramanian Slide 1-9

Doped Si and Charge What is the net charge of your Si when it is electron and hole doped?

GaAs, III-V Compound Semiconductors, and Their Dopants Ga As Ga Ga As Ga As As Ga As Ga GaAs has the same crystal structure as Si. GaAs, GaP, GaN are III-V compound semiconductors, important for optoelectronics. Which group of elements are candidates for donors? acceptors?

From Atoms to Crystals p conduction band Energy s valence band isolated atoms Decreasing atomic separation lattice spacing Energy states of Si atom (a) expand into energy bands of Si crystal (b). The lower bands are filled and higher bands are empty in a semiconductor. The highest filled band is the valence band. The lowest empty band is the conduction band.

Energy Band Diagram Conduction band E c E g Band gap E v Valence band Energy band diagram shows the bottom edge of conduction band, E c, and top edge of valence band, E v. E c and E v are separated by the band gap energy, E g.

Measuring the Band Gap Energy by Light Absorption electron photons photon energy: h v > E g E g E c E v hole E g can be determined from the minimum energy (hν) of photons that are absorbed by the semiconductor. Bandgap energies of selected semiconductors Material PbTe Ge Si GaAs GaP Diamond E g (ev) 0.31 0.67 1.12 1.42 2.25 6.0

Semiconductors, Insulators, and Conductors E c E g=1.1 ev E c Ev E g= 9 ev E v Top of conduction band empty filled E c Si (Semiconductor) SiO 2 (Insulator) Conductor Totally filled bands and totally empty bands do not allow current flow. (Just as there is no motion of liquid in a totally filled or. totally empty bottle.) Metal conduction band is half-filled. Semiconductors have lower E g 's than insulators and can be doped.

Donor and Acceptor Levels in the Band Model Conduction Band Donor Level E c E d Donor ionization energy Acceptor Level Valence Band Acceptor ionization energy E a E v Ionization energy of selected donors and acceptors in silicon Donors Acceptors Dopant Sb P As B Al In Ionization energy, E c E d or E a E v (mev) 39 44 54 45 57 160 m 0 q 4 Hydrogen: E ion = = 13.6 ev 8ε 02 h 2

Dopants and Free Carriers Donors n-type Acceptors p-type Dopant ionization energy ~50meV (very low).

General Effects of Doping on n and p Charge neutrality: N _ a N + d n + N a _ p N + d : number of ionized acceptors /cm3 : number of ionized donors /cm3 = 0 Assuming total ionization of acceptors and donors: N a N d n + N p = 0 a N d : number of acceptors /cm3 : number of donors /cm3

Density of States E E c ΔΕ E c g c g(e) E v E v g v g c ( E) g g c v number of states in ΔE ΔE volume 1 ev cm 3 * * mn 2mn ( E) 2 3 π h * * mp 2mp ( E) 2 3 π h ( E E ) c ( E E) v

Thermal Equilibrium

Thermal Equilibrium An Analogy for Thermal Equilibrium Sand particles Dish Vibrating Table There is a certain probability for the electrons in the conduction band to occupy high-energy states under the agitation of thermal energy (vibrating atoms, etc.)

At E=E F, f(e)=1/2

Effect of T on f(e) T=0K

Question If f(e) is the probability of a state being occupied by an electron, what is the probability of a state being occupied by a hole?

N c is called the effective density of states (of the conduction band).

N v is called the effective density of states of the valence band.

Intrinsic Semiconductor Extremely pure semiconductor sample containing an insignificant amount of impurity atoms. n = p = n i E f lies in the middle of the band gap Material Ge Si GaAs E g (ev) 0.67 1.12 1.42 n i (1/cm 3 ) 2 x 10 13 1 x 10 10 2 x 10 6

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback