Presentation is loading. Please wait.

Presentation is loading. Please wait.

Light and Atoms Physics 113 Goderya Chapter(s): 7 Learning Outcomes:

Published byDella Turner Modified over 8 years ago

Similar presentations

Presentation on theme: "Light and Atoms Physics 113 Goderya Chapter(s): 7 Learning Outcomes:"— Presentation transcript:

1 Light and Atoms Physics 113 Goderya Chapter(s): 7 Learning Outcomes:

2 The Atom Smallest part of matter Nucleus, Protons, Neutrons and Electrons The elementary particle Quark Symbol - Z X A Z = Atomic Number Number of protons A = Mass Number Electron (-) Nucleus Protons (+)NeutronsQuarks

3 Hydrogen Atom One proton in the nucleus one electron orbiting the nucleus Symbol - 1 H 1 Electron (-) Nucleus Proton (+) 1H11H1

4 Helium Atom Two proton and two neutrons in the nucleus Two electrons orbiting the nucleus Symbol - 2 He 4 2 He 4

5 The Chemical Elements Each chemical element has a specific atomic configuration. The periodic table will show this for any known chemical element.

6 The Bohr Atom Model The Energy of the electron orbits are quantized That is each orbit carries a discrete energy value The closer the orbit to the nucleus, the more negative is its energy value -E 1 -E 2 -E 3 -E 4 n1n1 n4n4 n3n3 n2n2 -E 1 < -E 2 < -E 3 < -E 4

7 The Bohr Atom Model Electrons can jump from one energy orbit to the other and absorb or emit energy The energy of each orbit is calculated by E n = -13.6 / n 2 (Z 2 ) eV n is orbit number and Z is the atomic number eV = electron Volts 1 eV = 1.602 x 10 -19 J -E l -E h n l n h

8 The Bohr Atom Model When an electron jumps from a higher orbit to a lower orbit the change in energy is ∆E = E h - E l The wavelength of emitted light is 1/  = Z 2 R (1/n l 2 - 1/n h 2 ) R is Rydberg constant = 1.097 x 10 -2 nm -1 -E l -E h n l n h Spectral line

9 The Bohr Atom Model Electrons can only jump to certain defined levels when it gains or loses energy. Because n h and n l are integers -E l -E h n l n h ∆E = E h - E l

10 The Bohr Atom Model Emission: (colored spectral lines) Transition from n h to n l level. ∆E = E h - E l Absorption: (dark spectral line) Transition from n h to n l level. -∆E = E h - E l -E l -E h n l n h Spectral line

11 F4-8 The Atomic Spectrum The emission of light from an atom can be mapped in a diagram called the spectrum 300nm 700nm500nm Orbit 6->2Orbit 5->2 Orbit 4->2Orbit 3->2 Hydrogen Helium

12 Lines of Hydrogen Most prominent lines in many astronomical objects: Balmer lines of hydrogen

13 The Balmer Lines n = 1 n = 2 n = 4 n = 5 n = 3 HH HH HH The only hydrogen lines in the visible wavelength range. Transitions from 2 nd to higher levels of hydrogen 2 nd to 3 rd level = H  (Balmer alpha line) 2 nd to 4 th level = H  (Balmer beta line) …

14 F4-9 Finger print of an Atom Every atom and molecule has its own distinct spectrum Spectra differ in number of lines and the spacing between the lines

Download ppt "Light and Atoms Physics 113 Goderya Chapter(s): 7 Learning Outcomes:"

Similar presentations

The atom and its nucleus

The atom and its nucleus
Atomic Emission Spectra. The Electromagnetic Spectrum High frequency Short wavelength High energy lower frequency longer wavelength lower energy.

Atomic Emission Spectra. The Electromagnetic Spectrum High frequency Short wavelength High energy lower frequency longer wavelength lower energy.
Aim: How can we explain energy transitions in an atom? Do Now: What were the limitations of the Rutherford model of the atom and how did the Bohr model.

Aim: How can we explain energy transitions in an atom? Do Now: What were the limitations of the Rutherford model of the atom and how did the Bohr model.
The Hydrogen Spectrum Experiment 6 amplitude Wavelength -λ.

The Hydrogen Spectrum Experiment 6 amplitude Wavelength -λ.
 When a gas in a tube is subjected to a voltage, the gas ionizes, and emits light.  We can analyze that light by looking at it through a spectroscope.

 When a gas in a tube is subjected to a voltage, the gas ionizes, and emits light.  We can analyze that light by looking at it through a spectroscope.
Atomic Spectroscopy Introduction To The Textbook “Atomic Astrophysics and Spectroscopy” (AAS) Anil Pradhan and Sultana Nahar Cambridge University Press.

Atomic Spectroscopy Introduction To The Textbook “Atomic Astrophysics and Spectroscopy” (AAS) Anil Pradhan and Sultana Nahar Cambridge University Press.
1 Light as a Particle In 1888, Heinrich Hertz discovered that electrons could be ejected from a sample by shining light on it. This is known as the photoelectric.

1 Light as a Particle In 1888, Heinrich Hertz discovered that electrons could be ejected from a sample by shining light on it. This is known as the photoelectric.
ATOMIC STRUCTURE. Atomic Structure All matter is composed of atoms. Understanding the structure of atoms is critical to understanding the properties of.

ATOMIC STRUCTURE. Atomic Structure All matter is composed of atoms. Understanding the structure of atoms is critical to understanding the properties of.
ISP 205 - Astronomy Gary D. Westfall1Lecture 6 The Nature of Light Light and other forms of radiation carry information to us from distance astronomical.

ISP Astronomy Gary D. Westfall1Lecture 6 The Nature of Light Light and other forms of radiation carry information to us from distance astronomical.
Dr. Jie ZouPHY 13711 Chapter 42 Atomic Physics. Dr. Jie ZouPHY 13712 Outline Atomic spectra of gases Early models of the atom Bohr’s model of the hydrogen.

Dr. Jie ZouPHY Chapter 42 Atomic Physics. Dr. Jie ZouPHY Outline Atomic spectra of gases Early models of the atom Bohr’s model of the hydrogen.
Lecture 2110/24/05. Light Emission vs. Absorption Black body.

Lecture 2110/24/05. Light Emission vs. Absorption Black body.
THE BOHR MODEL OF THE ATOM October 23, 2009. The Bohr Model of Hydrogen Atom Light absorbed or emitted is from electrons moving between energy levels.

THE BOHR MODEL OF THE ATOM October 23, The Bohr Model of Hydrogen Atom Light absorbed or emitted is from electrons moving between energy levels.
What can happen when an atom absorbs energy?

What can happen when an atom absorbs energy?
Aim: How to distinguish electrons in the excited state DO NOW: PREPARE FOR QUIZ. 10 MIN.

Aim: How to distinguish electrons in the excited state DO NOW: PREPARE FOR QUIZ. 10 MIN.
Physics 1C Lecture 29A.

Physics 1C Lecture 29A.
Chapter 10.2 Radiation Tells Us the Temperature, Size, and Composition of Stars.

Chapter 10.2 Radiation Tells Us the Temperature, Size, and Composition of Stars.
Spectroscopy and Electron Configurations

Spectroscopy and Electron Configurations
Guiding Questions 1. How fast does light travel? How can this speed be measured? 2. Why do we think light is a wave? What kind of wave is it? 3. How is.

Guiding Questions 1. How fast does light travel? How can this speed be measured? 2. Why do we think light is a wave? What kind of wave is it? 3. How is.
Nature of Light chapter 14 1600s – 1900s Is Light a wave or a stream of particles.

Nature of Light chapter s – 1900s Is Light a wave or a stream of particles.
Shedding Light on the Structure of the Atom

Shedding Light on the Structure of the Atom

Similar presentations

Ads by Google