A Simple Physical Model of a Fractal Cosmos Introduction Fractal particles The big picture Summary.

Slides:

Advertisements

Similar presentations

Stellar Structure Section 6: Introduction to Stellar Evolution Lecture 18 – Mass-radius relation for black dwarfs Chandrasekhar limiting mass Comparison.

Advertisements

End States Read Your Textbook: Foundations of Astronomy

AS 4002 Star Formation & Plasma Astrophysics BACKGROUND: Maxwell’s Equations (mks) H (the magnetic field) and D (the electric displacement) to eliminate.

Electricity and Magnetism

Moment of Inertia of Neutron Star Crust Calculations vs. Glitches Observations Joanna Porębska Jagiellonian University – prof. Marek Kutschera & Nuclear.

Degenerate Fermi Gas.

13 Black Holes and Neutron Stars Dead Stars Copyright – A. Hobart.

Stellar Interior. Solar Facts Radius: –R  = 7  10 5 km = 109 R E Mass : –M  = 2  kg –M  = 333,000 M E Density: –   = 1.4 g/cm 3 –(water is.

X-Ray image of Crab Nebula Pulsar Credit: NASA/CXC/ASU/J. Hester et al.) Liliana Caballero With Pf. Horowitz Molecular Dynamics Simulations of Non-uniform.

2/9/2006Welcome to LIGO1 Welcome to LIGO!. 2/9/2006Welcome to LIGO2 LIGO: A detector that measures very tiny displacements How tiny?

Or Can all laws of nature be reduced to one single system?

Black Holes Written for Summer Honors Black Holes Massive stars greater than 10 M  upon collapse compress their cores so much that no pressure.

Nuclear models. Models we will consider… Independent particle shell model Look at data that motivates the model Construct a model Make and test predictions.

Neutron Stars and Black Holes PHYS390: Astrophysics Professor Lee Carkner Lecture 18.

P460 - Quan. Stats. III1 Nuclei Protons and neutrons in nuclei separately fill their energy levels: 1s, 1p, 1d, 2s, 2p, 2d, 3s…………… (we’ll see in 461 their.

White Dwarfs PHYS390 Astrophysics Professor Lee Carkner Lecture 17.

Physics 121: Electricity & Magnetism – Lecture 9 Magnetic Fields Dale E. Gary Wenda Cao NJIT Physics Department.

Nuclear Electromagnetic Moments

Chapter 27 Magnetism. Introduction Our approach –Review of E&M interaction ideas –Magnetic fields & magnets (initial ideas) –Magnetic field and currents.

02/19/2014PHY 712 Spring Lecture 151 PHY 712 Electrodynamics 10-10:50 AM MWF Olin 107 Plan for Lecture 15: Finish reading Chapter 6 1.Some details.

02/18/2015PHY 712 Spring Lecture 151 PHY 712 Electrodynamics 9-9:50 AM MWF Olin 103 Plan for Lecture 15: Finish reading Chapter 6 1.Some details.

Physics 2112 Lecture 23 Electricity & Magnetism Lecture 23, Slide 1.

9 Water bombs Mário Lipovský.

Williams Research Gravity Pharis E. Williams 19 th Natural Philosophy Alliance Albuquerque, NM July, 2012.

Warmup: Concept: PS-2.1 Compare the subatomic particles.

Modern Physics Modern Physics Global Mechanics Global Mechanics Astrophysics Astrophysics Cosmology and The Little Bang Cosmology and The Little Bang.

Chapter 13 Black Holes. What do you think? Are black holes just holes in space? What is at the surface of a black hole? What power or force enables black.

Yi-Zen Chu BCCS Case Western Reserve University 9 December 2008 The n-body problem in General Relativity from perturbative field theory arXiv:

Vibrations and Waves AP Physics Lecture Notes m Vibrations and Waves.

Stars. I.Introduction A. Some ‘observations’ During the 20 th Century 1. Our Sun is not the center of our Galaxy.

Correspondence of The Principle of Maximum Entropy With other Laws of Physics Maximum Proper Time Least Action Least Time Minimum Energy How may the Maximum.

Associate Professor: C. H.L IAO. Contents:  3.1 Introduction 99  3.2 Simple Harmonic Oscillator 100  3.3 Harmonic Oscillations in Two Dimensions 104.

Chapter 16 Sound /good-and-bad-vibrations.html.

Immediate Objectives 1. To describe the physical basis for clock retardation experimental results (e.g., particle lifetimes) 2. To describe the physical.

Parity violation in electron quasielastic scattering Kyungsik Kim School of Liberal Arts and Science, Korea Aerospace University, Korea 1.Introduction.

Sound   Introduction   Longitudinal waves with regions of high and low pressure that travel through a medium   Audible, Infrasonic, Ultrasonic 

Physics II: Electricity & Magnetism Sections 23.1 to 23.9.

High Mass Stellar Evolution Astrophysics Lesson 13.

Neutron Stars By: Matthew Buza. Star Power Importance of Stars and their role in the universe. Importance of Stars and their role in the universe. Overview.

1 The Origin of Mass: - Inertial Mass - München 2009 by Albrecht Giese, Hamburg The Origin of Mass 1.

Today:  Finish Chapter 20  Review Session  Midterm 2: Fri Apr 17 Chs 9, 11, 13, 14, 15, 19, 20.

Hydrogen Atom and QM in 3-D 1. HW 8, problem 6.32 and A review of the hydrogen atom 2. Quiz Topics in this chapter:  The hydrogen atom  The.

1 Honors Physics 1 Summary and Review - Fall 2013 Quantitative and experimental tools Mathematical tools Newton’s Laws and Applications –Linear motion.

Special Relativity 1. Quiz 1.22 (10 minutes) and a few comments on quiz So far we know that Special Relativity is valid for all speeds. But it is.

Neutron Star. Gravitational Crush The balance point to maintain degenerate matter is 1.4 M . When the mass of the core is greater than 1.4 M , electrons.

Atoms & Starlight (Chapter 6).

Low frequency observation of both pulsar wind and magnetodipole radiation from switch on-off pulsars Ya.N. Istomin P.N. Lebedev Physical Institute, Moscow,

Black Holes Pierre Cieniewicz. What are they? A Black Hole (BH) is a place in space from which nothing can escape The reason for this is gravity Some.

Time Standards and Particle Interactions in a Fractal Cosmos By Harry A. Schmitz May 25, 2005.

1 Linear Wave Equation The maximum values of the transverse speed and transverse acceleration are v y, max =  A a y, max =  2 A The transverse speed.

Chapter 13: Neutron Stars and Black Holes. When a massive star begins its core collapse, the electrons get compressed into the protons to form neutrons.

Electrostatics Chapter Properties of Physical Objects Mass/Inertial: – Gravity mass: inertia in gravitational interaction – Kinetic mass: inertia.

By: David N. Sutton. Why Three ?  We experience three dimensions because points in space are aligned in three directions from any reference.  I will.

MAGNETIZATION AND SPIN MAGNETIC MOMENTS Among macroscopic objects we find those which have a permanent magnetic field, even if there are no obvious macroscopic.

Detection Physics and Technology of Gravitational Waves --- GR and Principle of GW detection --- Kazuaki Kuroda ICRR, University of Tokyo 7 th August,

T HE VORTICAL MECHANISM OF GENERATION & COLLIMATION OF THE ASTROPHYSICAL JETS M.G. A BRAHAMYAN Yerevan State University, Armenia.

Or what was before nothing. By David N. Sutton 5/1/2012.

Einstein’s Zurich Notebook

Chapter 2 Molecular Mechanics

يقول الخلاق العليم: (والله أخرجكم من بطون أمهاتكم لا تعلمون شيئًا وجعل لكم السمع والأبصار والأفئدة قليلاً ما تشكرون) ("النحل" 78)) . الإهتزازات والموجات.

What makes the universe?

Now we will study Sound in detail!

Neutron stars and beyond

General Relativity: Part II

Finish reading Chapter 6

Picture 1 10 protons 10 neutrons = an electron.

Law of Conservation of Energy

Nuclear Symmetry Energy and Compact Stars

Review of Chapter 17 Dec. 7th 2004.

Finish reading Chapter 6

Presentation transcript:

A Simple Physical Model of a Fractal Cosmos Introduction Fractal particles The big picture Summary

Multiverses Go Mainstream Eternal Inflation … based on QFT Black Holes (BHs) within BHs … based on GR Fractal Cosmos … a simple physical model

A Simple Nomenclature for a Fractal Cosmos Universes – Substrates – Strata Particles – Substrate particles – Stratum particles

A Simple Physical Model of a Fractal Cosmos Introduction Fractal particles The big picture Summary

Three Dimensional Standing Waves (3D SW’s) – Milo Wolff 1. “Beyond the Point Particle - A Wave Structure for the Electron” Galilean Electrodynamics 6 No. 5, October 1995, pages (updated 15 May 1998) 2. “Derivation of the Relativistic Doppler shift and mass-increase formulas without assuming special relativity,” NPA, Flagstaff, (See also GED, 9 No. 6, pages , 1998).

“The Physical and Philosophical Nature of the Universe,” by Harry W. Schmitz Book One, Part One, Chapters Physical Concepts 2. Pulsar Analysis 3. Wave Pattern Analysis 4. Time Standards 5. Energy Focusing Effects 6. Nucleon Analysis 7. Electron Analysis

Particles

Energy Density vs. Radius

Initial Moments of Pulsar

Simple Harmonic Motion Two States of Maximum Potential Energy 1) Max. potential energy due to pressure 2) Max. potential energy due to gravity

Reversible Energy Total for the universe Core of one particle

Number of particles in a universe

A Simple Physical Model of a Fractal Cosmos Introduction Fractal particles The big picture Summary A Simple Physical Model of a Fractal Cosmos

The Big Picture

Substrate of our universe Neutron star Every nucleon extends to the surface Ultimate universe Penultimate universe

Series of Universes NameRrN stratum N substrate Ultimate Penultimate ??

Convergence In contact with substrates Physical nature of our existence Natural philosophy

Applications Relativity Electric potential Particle interactions

Interacting Nucleons

A Mathematical Object Analogous to number line (N, Z, Q, R and C) Foundation of natural philosophy Inductive reasoning n  n + 1

Thank You! Harry A. Schmitz 5 Marwood Road South Port Washington, New York (516)