Generalization of Einstein’s Theory of Brownian Motion Mahmoud A. Melehy University of Connecticut Storrs, CT 06269-1157.

Slides:

Advertisements

Similar presentations

Where is the Electron Located?

Advertisements

Electricity and It’s charge

Electricity. Electrostatic The Electric Field Electric charge. Conductors and Insulators Coulomb´s Law The Electric field. Electric Field Lines Calculating.

Electric Potential Energy 8.1. A _________ is a combination of electrochemical cells connected together (or a single electrochemical cell). Electrochemical.

Electrical Principles Chapter 1 Matter, Atoms, Conductors, Insulators, SemiConductors, Elements, Molecules, Compounds, and Electron Flow.

ELECTRICITY AND MAGNETISM. INSULATORS AND CONDUCTORS Conductors are materials that are good at carrying an electric charge. Good conductors of electricity.

Electrostatics 1 Personal Ad Electron rich…seeks Electron poor for bonding, conducting, and long term relationship. Resistance a plus.

Electric Forces and Electric Fields

Electrostatics.

Transport phenomena in chemical processes part II Michał Araszkiewicz PhD.

The Photoelectric Effect

Recommended Books Arthur Beiser, “Schaum's Outline of Applied Physics,” Fourth Edition, 2004, McGraw-Hill, ISBN: University Physics with Modern.

Albert Einstein. Introduction Albert Einstein was born on March 14, 1879 in Germany. He is widely known as the physicist who developed the theory of General.

Chapter 5: Electricity and Magnetism. Electricity and Magnetism.

Chapter 17 Electric Forces and Fields 17-1 Electric Charge Properties of Electric Charge  Ancient Greeks discovered static charge when they observed amber.

Static Electricity 4 th form IGCSE Textbook: Chapter 8, p. 66.

Electricity & Magnetism

Electrostatic and Electrodynamics Your Name. At the completion of this chapter, the student should be able to do the following : Define electrification.

Matter is made up of small particles called atoms. Atoms are made up of smaller, sub-atomic particles called protons, neutrons, and electrons. Sub-atomic.

Electricity Chapter 7.

Electricity Chapter 10. Recall this info… All matter is made of atoms which are the smallest particle of an element that has all the properties of that.

Heat is a form of:. Everything in the universe has heat energy! Your BODY, your CAR…even ICE!

Introduction to Electricity

Physics 106 Lesson #9 Electrochemical Cells and Batteries Dr. Andrew Tomasch 2405 Randall Lab

Chapter 32 Electrostatics.

Electrostatics Physics. A. Definition  The study of electrical charge that can be collected and held in one place.

Lecture Outline Chapter 15 College Physics, 7 th Edition Wilson / Buffa / Lou © 2010 Pearson Education, Inc.

Ch Electricity I. Electric Charge  Atoms and Charge  Conductors  Insulators  Static Electricity  Electric Discharge.

Thermodynamic variables Path FunctionState Function B I II A III (V B -V A ) I = (V B -V A ) II = (V B -V A ) III (state Function) (Path Function)

Chapter 7 Energy and Energy Balance By : Mrs. Norazian Mohamed Noor

1 Electrostatics (static electricity) 2 Electric Charges: Electric charge is a fundamental quantity that is responsible for all electric phenomena. Charge.

Static Electricity. Water and Static Electricity Video on Video on

Physics 106 Lesson #8 Static Electricity

Unit 7: Part 1 Electric Charge, Forces, and Fields.

Law of Conservation of Energy Energy cannot be created or destroyed. Most forms of energy can be transformed into other forms. Usually changes into thermal.

(VB-VA)I = (VB-VA)II = (VB-VA)III

Electricity. Electricity  Is a natural form of energy that can take many different forms. It is defined briefly as the flow of electric charge. Lightning.

Thermionic Valves.

Changes in State Chapter 2 Section 2. Energy How does the ice go from being a solid back to being a liquid? Energy is the ability to do work Energy.

College Physics, 7th Edition

Electrostatics. Electrostatics A. Definition:  The study of electric charges that can be collected and held in one place  Non-moving, no flow B. Examples.

ELECTROSTATICS.

PSC 4011 Electricity: What’s the connection?. PSC 4011: Static Electricity & Magnetism  Electricity describes all of the phenomena caused by positive.

Charge A proton, electron, or an excess of protons or electrons. + - Proton Electron A positive charge A negative charge

Electric Charge and Electric Force. Matter is made up of atoms. Atoms are made up of  Electrons  Protons  Neutrons.

Static Electricity Phenomena Lightning A Cat Leather car seats Ben Franklin and the kite. Sliding your feet on a rug.

1 Semiconductor Devices  Metal-semiconductor junction  Rectifier (Schottky contact or Schottky barrier)  Ohmic contact  p – n rectifier  Zener diode.

Chapter 22 Electromagnetic Induction Induced Emf and Induced Current There are a number of ways a magnetic field can be used to generate an electric.

Static Electricity. Electricity Electricity is the set of physical phenomena associated with the presence and flow of electric charge. Electricity gives.

Science Notes for Foundation Course

Unit 12 Electrostatics. Electrostatics  Electricity at Rest  It involves 1. Electric Charges 2. The Forces Between Them 2. The Forces Between Them 3.

Dr. Owen Clarkin School of Mechanical & Manufacturing Engineering Summary of Energy Topics Chapter 1: Thermodynamics / Energy Introduction Chapter 2: Systems.

Surface Properties of Biological Materials

Static Electricity By Christos.

Chapter 6 Energy and Energy Balance

Electrical Properties of Materials

ELECTRICITY NOTES Chapter 17.

Chapter 21, Electric Charge, and electric Field

An introduction to thermodynamics

Electric Charges, Forces, and Fields

CH-12: Electrostatic Phenomena

Blue Station - Metrics Define volume. Define density. Define weight.

6.1 Electric Charge and Static Electricity

ELECTRIC CHARGE.

States of Matter and describing them

Temperature and Thermal Energy

Monday, April 29 Reminders:

Methods of Charging S Explain attraction of neutral objects using the particle model of electricity. S Explain electrostatic phenomena.

Presentation transcript:

Generalization of Einstein’s Theory of Brownian Motion Mahmoud A. Melehy University of Connecticut Storrs, CT

Albert Einstein ( ) Nobel Prize 1921

Thermal Momentum Significance of Einstein’s Postulate Type: translational, vibrational, and/or rotational H 2, at 300 K, v rms = 1.93 km/s = 6,960 km/hour Conduction electrons in Cu, v rms = 1,570 km/s = 5.65x10 6 km/hour.

The Principle of Detailed Balancing

The Gibbs Equation and Physical definition of Chemical Potential

The Gibbs Equation The Gibbs-Duhem Equation

The Gibbs Equation The Gibbs-Duhem Equation

Thermodynamic Generalization of The Maxwell-Einstein Diffusion Force

The Principle of Detailed Balancing

Analogy with Electric Circuits −-− V or L

Theory & Experiment for Ge & Si Diodes

In Sb and Ga As Diodes

Solar Cell Theory & Experiment

New Consequences of the First & Second Laws

Interfacial Forces, Entropy Change

Interfacial Electrification

Water Film on Glass

Water Film on Corian

Surface Charge on Corian

Surface Charge on Styrofoam

Surface Charge on Mahogany Wood

Dipole-Charge Effects on Water-Glass Interfaces

Forces Shaping Tornadoes

Tornadoes and Lightning

Dew Accumulation on Grass

Phenomenon of Rising Mist Canadian Niagra Falls

Phenomenon of Rising Mist Canadian Niagra Falls

Example of Conduction Electrons in Metals and Semiconductors Consistency of Einstein’ Theory of Brownian Motion with: 1. The first and second laws of thermodynamics. 2. The quantum theory.

Thermal Momentum and Entropy Uniqueness For any one constituent, the Gibbs-Duhem equation: Quantum mechanics allows to writing: Therefore, (1)





Summary and Conclusion Generalizing thermodynamically Einstein’s theory of Brownian motion has led to an interfacial transport theory, which, in turn led to many consequences, including: Revealing that the first and second laws of thermodynamics require the existence of electric charges on most surfaces, membranes and other interfaces. This nearly universal property of interfaces makes it possible to readily explain

many diverse phenomena, such as: ‘surface’ tension, capillarity, particle adhesion, the separation of charges upon phase change, atmospheric electricity, fog and cloud suspension, and even one mysterious phenomenon that has been observed since ancient times: the generation of static electricity by rubbing two different, insulating surfaces against one another. How much had this particular phenomenon been explained before is described, in the May, 1986 issue of Physics Today, by D. M. Burland, and L. B. Schein, who

have stated: "That some materials can acquire an electric charge by contact or rubbing has been known at least since the time of Thales of Miletus, around 600 B.C., and much work has been done on understanding the phenomenology of the effect, particularly in the 18th, and 19th centuries; nevertheless the underlying physics of electrostatic charging of insulators remains unclear.“ Generalizing Einstein’s theory of Brownian motion to interfacial systems has unlocked this ancient mystery, and many other ones too. Thank you.