Experiments on detection of cosmic ether

Similar documents
Experimental check on the validity of the special theory of relativity

GRAVITY AND UNIVERSE. From the SelectedWorks of Vildyan Shavkyatovich Yanbikov. Vildyan Shavkyatovich Yanbikov

I understand the relationship between energy and a quanta I understand the difference between an electron s ground state and an electron s excited

Astronomy 1504/15014 Section 20

Chapter 5 Electrons In Atoms

Thermal conversion of solar radiation. c =

c = λν 10/23/13 What gives gas-filled lights their colors? Chapter 5 Electrons In Atoms

BLUE-PRINT II XII Physics

An air conditioner is able to cool a building because it removes heat from the indoor air and transfers it outdoors. A chemical refrigerant in the

A system of two lenses is achromatic when the separation between them is

ASTR-1010: Astronomy I Course Notes Section IV

Preview. Atomic Physics Section 1. Section 1 Quantization of Energy. Section 2 Models of the Atom. Section 3 Quantum Mechanics

Explain the mathematical relationship among the speed, wavelength, and frequency of electromagnetic radiation.

Dept. of Physics, MIT Manipal 1

Astronomy 203 practice final examination

10/27/2017 [pgs ]

Chapter 4. Table of Contents. Section 1 The Development of a New Atomic Model. Section 2 The Quantum Model of the Atom

Yellow. Strontium red white. green. yellow violet. green. red. Chapter 4. Arrangement of Electrons in Atoms. Table of Contents

THEORETICAL PROBLEM 2 DOPPLER LASER COOLING AND OPTICAL MOLASSES

Higher -o-o-o- Past Paper questions o-o-o- 3.4 Spectra

Example: model a star using a two layer model: Radiation starts from the inner layer as blackbody radiation at temperature T in. T out.

The Nature of Light I: Electromagnetic Waves Spectra Kirchoff s Laws Temperature Blackbody radiation

Optics in a Fish Tank Demonstrations for the Classroom

1. In Young s double slit experiment, when the illumination is white light, the higherorder fringes are in color.

Chapter 5. Past and Proposed Experiments Detecting Absolute Motion

Transverse and longitudinal mass moving in the inertial frame of reference

Electrons in Atoms. Section 5.1 Light and Quantized Energy Section 5.2 Quantum Theory and the Atom Section 5.3 Electron Configuration

The Basics of Light. Sunrise from the Space Shuttle, STS-47 mission. The Basics of Light

Revision Guide for Chapter 7

is the minimum stopping potential for which the current between the plates reduces to zero.

Write the electron configuration for Chromium (Cr):

Physics and the Quantum Mechanical Model

CHEMISTRY Matter and Change

LECTURE 11 ELECTROMAGNETIC WAVES & POLARIZATION. Instructor: Kazumi Tolich

EXPERIMENTS CHARACTERIZING THE X-RAY EMISSION FROM A SOLID-STATE CATHODE USING A HIGH-CURRENT GLOW DISCHARGE

Atomic Structure. Standing Waves x10 8 m/s. (or Hz or 1/s) λ Node

Chapter 6 Electronic structure of atoms

Experiment 9. Emission Spectra. measure the emission spectrum of a source of light using the digital spectrometer.

Core Concept. PowerPoint Lectures to accompany Physical Science, 8e. Chapter 7 Light. New Symbols for this Chapter 3/29/2011

Chapter 6 Electronic Structure of Atoms

Astronomy 1 Winter 2011

4. Energy, Power, and Photons

Photoionized Gas Ionization Equilibrium

Nature of Light. What is light? Sources of light. an electromagnetic radiation capable of stimulating the retina of the eye.

School. Team Number. Optics

ASTRONOMY 103: THE EVOLVING UNIVERSE. Lecture 4 COSMIC CHEMISTRY Substitute Lecturer: Paul Sell

Answer Key Testname: MT S

AST 102 chapter 5. Radiation and Spectra. Radiation and Spectra. Radiation and Spectra. What is light? What is radiation?

LECTURE 11 ELECTROMAGNETIC WAVES & POLARIZATION. Instructor: Kazumi Tolich

Experiment 3 1. The Michelson Interferometer and the He- Ne Laser Physics 2150 Experiment No. 3 University of Colorado


Waves, Polarization, and Coherence

X Rays must be viewed from space used for detecting exotic objects such as neutron stars and black holes also observing the Sun.

2. What is the wavelength, in nm, of light with an energy content of 550 kj/mol? a nm b nm c. 157 nm d. 217 nm e.

Topic 4 &11 Review Waves & Oscillations

LECTURE 23: LIGHT. Propagation of Light Huygen s Principle

Electrons in Atoms. Section 5.1 Light and Quantized Energy

Observation of Atomic Spectra

CHARA Meeting 2017 Pasadena, California

Atomic Theory. Developing the Nuclear Model of the Atom. Saturday, January 20, 18

Fundamental Concepts of Radiometry p. 1 Electromagnetic Radiation p. 1 Terminology Conventions p. 3 Wavelength Notations and Solid Angle p.

Chapter 5 Electrons In Atoms

Particle Detectors and Quantum Physics (2) Stefan Westerhoff Columbia University NYSPT Summer Institute 2002

EP118 Optics. Content TOPIC 1 LIGHT. Department of Engineering Physics University of Gaziantep

JRE Group of Institutions ASSIGNMENT # 1 Special Theory of Relativity

PH2200 Practice Final Exam Summer 2003

PHYSICS. Ray Optics. Mr Rishi Gopie

WAVE NATURE OF LIGHT

PHYS General Physics II Lab The Balmer Series for Hydrogen Source. c = speed of light = 3 x 10 8 m/s

Seat Number. Print and sign your name, and write your Student ID Number and seat number legibly in the spaces above.

Chapter 7: The Quantum-Mechanical Model of the Atom

Physics 2135 Exam 3 November 18, 2014

B.Tech. First Semester Examination Physics-1 (PHY-101F)

Electromagnetic Radiation

GRADUATE WRITTEN EXAMINATION. Fall 2018 PART I

Name the region of the electromagnetic radiation emitted by the laser. ...

Electromagnetic Radiation. Physical Principles of Remote Sensing

Chapter 4. Spectroscopy. Dr. Tariq Al-Abdullah

Revision Guide. Chapter 7 Quantum Behaviour

5.3. Physics and the Quantum Mechanical Model

Electronic structure of atoms

Discussion Review Test #2. Units 12-19: (1) (2) (3) (4) (5) (6)

2) A linear charge distribution extends along the x axis from 0 to A (where A > 0). In that region, the charge density λ is given by λ = cx where c

AP Chemistry. Chapter 6 Electronic Structure of Atoms

Fluorescence. Incandescence. Electric. Bioluminescence Chemiluminescence. Combustion

Newton s Laws of Motion

Lecture 6: The Physics of Light, Part 1. Astronomy 111 Wednesday September 13, 2017

progressive electromagnetic wave

3. Anaemia can be diagnosed by (a) 15 P 31 (b) 15 P 32 (c) 26 Fe 59 (d) 11 Na 24. (b) α particle (Alpha particle)

YOUR NAME Sample Final Physics 1404 (Dr. Huang)), Correct answers are underlined.

Laboratory Exercise. Atomic Spectra A Kirchoff Potpourri

Photoelectric effect

aka Light Properties of Light are simultaneously

The Grating Spectrometer and Atomic Spectra

Accounts for certain objects being colored. Used in medicine (examples?) Allows us to learn about structure of the atom

Black Body Radiation

Information in Radio Waves

Astronomy. Optics and Telescopes

in Electromagnetics Numerical Method Introduction to Electromagnetics I Lecturer: Charusluk Viphavakit, PhD

Earth: the Goldilocks Planet

Transcription:

From the SelectedWorks of Vildyan Yanbikov 2014 Experiments on detection of cosmic ether Vildyan Yanbikov Available at: https://works.bepress.com/vildyan_yanbikov1/9/

Yanbikov Vil'dyan Shavkyatovich Russian Federation, Volgograd, 400064, Bibliotechnaya street, house 14, apartament 95. Phone: 8-909-391-34-70 e-mail: vildyanyanbikov@yandex.ru Experiments on detection of cosmic ether Аbstract: Proof of the existence of the world ether in outer space may be a measure of the speed relative to the cosmic vacuum. Provides a description of the optical device which is aimed to measure the speed and direction of motion with respect to the space of emptiness. The principle of the optical device is based on the phenomenon of stellar aberration. Keywords: Absolute outer space, the world broadcast, absolute system of readout. 95.55.-n 0

Experiments on detection of cosmic ether Author: Yanbikov Vildyan Shavkyatovich I. Introduction Proof of the existence of the world ether in outer space may be a measure of the speed relative to the cosmic vacuum. Provides a description of the optical device which is aimed to measure the speed and direction of motion with respect to the space of emptiness. The principle of the optical device is based on the phenomenon of stellar aberration. II. The basic part Optical device consists of a cylindrical pipe with a diameter of about 100mm. and long (5-10)m (fig.1, fig.2, fig.3). On one end of which is fixed source of radiation with thin light beam. And the other end of the pipe is closed paper screen. The bottom of the pipe are perpendicular to the axis of the cylinder SD. On the axis of the cylinder SD on a spherical support in a section of one of the grounds of the pipe is fixed end light guide cable. Which is served light beam along the axis of the cylinder SD. Paper screen MN perpendicular to the axis of the cylinder SD. Monitoring is carried out with the external side of the screen. Diameter of the pipe should be such that the beam of light falling on the side walls of the pipe. The axis of the pipe can change the orientation in space within a solid angle 4π. Theoretically, the principle of the optical device is described as follows: With arbitrary orientation of the axis of the pipe SD in space beam from the source of radiation is directed along the axis of SD in point D. After the end of light guide cable is fixed on the ball socket. Then begins the change in orientation of the axis pipes in space. So she took all possible destinations within the solid angle 4π. Is this the position of the axis of the pipe. Where the beam leaves the screen luminous track as far as possible from the point of D. Notes is the maximum distance to the point А1 (fig.1). On the screen is a straight line А1D. Then begins the rotation axis of the pipe around the axis perpendicular to the plane of a triangle SDA1 (fig.1). The luminous track of a beam moves from point along the А1 direct А1D in the direction of point D. Pass the point of D luminous track is deleted from it at a maximum distance along a straight А1D. This is the maximum distance from the point D is celebrated on the screen point А2 (fig.2). Denote by α1 = A1D and α2 = A2D. Half cut A1A2 defined by the formula α = (α1 + α2). We denote the middle segment A1A2 on the screen point D0 ( fig.3 ). At coincidence of a glowing trail on the screen with 1

the point of D0. The direction of the beam SD0 will coincide with a direction of velocity relative to the cosmic ether ( fig.3 ). At coincidence of a glowing trail with one of the points А1 or А2. Rays of light SA1 or SA2 will be perpendicular to the velocity relative to the cosmic ether ( fig.1, fig.2 ). Speed of motion with respect to the cosmic ether is determined by the formula: V = where α = (α1 + α2) ; b = SD ; c is the light velocity in vacuum. In fig.1, fig.2, fig.3 vector V indicates the direction of motion relative to the cosmic ether. For planet Earth this speed presumably equal to approximately 400 km/s. The arrows indicate the direction of propagation of a photon. In practice, the experiment is as follows: Pipe axis at the time of the experiment should be parallel to the surface of the Earth. And there must be a pipe rotation around its axis. When arbitrary position of the pipes in the plane of the Earth's surface. When the source of radiation. The paper screen will be displayed trace from a beam in the form of a luminous spots. Needle punctured paper in the center of the bright spot. Then begins the rotation of pipes 360 degrees around its axis. The puncture should be separated from the glowing spot. Describe a circle with a diameter d1 and return to the center of the bright spot. Measured the diameter d1. We call these operations with a pipe (step 1.). Turn the axis of the pipe in the plane of the Earth's surface to about 10 degrees around the axis perpendicular to the surface of the Earth. Perform the same operation with a pipe (step 2). Get d2. Turn the pipe axis at 10 degrees around the axis perpendicular to the surface of the Earth up to 360 degrees. Perform the same operations with the pipe. We obtain a sequence of diameters d1, d2, d3, d4.... (circles of needle punctures). When pipe rotation in the plane of the Earth's surface. At some point, the pipe axis is perpendicular to the velocity of motion of the Earth relative to the cosmic ether. At the same moment some of diameters dn will be equal to dn = dmax. From this sequence diameters d1, d2, d3, d4.... you should choose a maximum diameter of dmax.. Speed of motion with respect to the cosmic ether will be determined from the formula: V = Where α = dmax ; b - the length of the pipe ; с is the light velocity in vacuum. Presumably when the velocity of the Earth relative to the cosmic ether about 400 km/s. At the length of the pipe 5м. The diameter of a circle puncture will be equal to dmax = 12мм. This value is easy to measure. The existence of an ether in space you can check the rotation of the Earth around its axis. On the flat surface of the Earth is fixed radiation source (laser). At a distance (50-100) m overhead screen. Beam 2

moves on the screen. Marks the position of the bright spot on the screen. The offset of the bright spot on the screen within 12 hours will be proof of the existence of ether in space. Several times to repeat the experience in different directions beam on the surface of the Earth. When different directions beam displacement of the bright spot may be more or less. It depends on the angle between the direction of the beam, and the vector of velocity of the Earth relative to the cosmic ether. Define the speed of propagation of the front of the light wave front. At the moment of its emission, during the transition of the atom from the excited state to the ground. Consider the radiation quantum energy of a hydrogen atom. Let the moment of emission of the quantum energy ε = hν. From the formula Heisenberg x p h take the minimum value of x p = h. The size of the hydrogen atom is equal to about 10-10 m In the initial moment of radiation all the energy of a photon is localized inside the sphere with a diameter of 10-10 m. Then x = 10-10 m. The speed of diffusion of the electromagnetic wave where m is the equivalent photon mass. Substitution in the uncertainty leads to the expression 10-10 = h Equivalent mass m = where h is Planck's constant; c is the speed of light in vacuum; λ - length electromagnetic wave. The minimum speed of the front of the electromagnetic wave at the beginning of the atom emission of a photon is equal range =10 10 λ c m/s. For the optical λ = 0.63*10 6 m. For the speed of the front of the electromagnetic wave. At λ = 0.63*10 6 m. Get the value of 2*10 12 m/s. High speed ( 2*10 12 m/s ) front electromagnetic wave. In the initial moment of radiation quantum energy. The result is very small variance α. Forward front of a light wave. Radiation nearest to the Earth star already has such a high speed. It is the speed of light in a vacuum. This phenomenon is confirmed by the stellar aberration. III. The conclusions It should be noted that the source of radiation ( laser ). Should submit the luminous flux to the bottom of the tube (S point). After quite a long fibre optic cable (hundreds of meters). With the passage of light from the laser to the entrance of the tube. Through fibre optic cable. Front light wave lifted to the trailing edge and starts moving at the speed of light in a vacuum. To obtain positive results in the experiment. For a source of radiation may be to apply the free electron laser in the x-ray range. Perhaps you should apply the radiation source emits a beam of atoms of neutral hydrogen H 0. Instead of 3

laser radiation source, you can use an extraterrestrial source of radiation (the Sun or the nearest bright star). The telescope is routed to a remote light source (the Sun or bright star). At the exit of the telescope by светопроводящему cable thin beam of light is served in the optical device. And is directed along the axis of the SD (fig.4) M E V S b D A1 fig.1. N M A2 V E S b D N fig.2. M E S b D0 V N fig.3. fibre optic cable fig.4. 4

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