Pisgah High School Chemistry Mike Jones The Hydrogen Spectrum Rev 020804 Canton, NC.

Slides:

Advertisements

Similar presentations

Excited Elements.

Advertisements

EMISSION AND ABSORPTION SPECTRA. Spectra A spectrum is the pattern formed when a beam of light (EM – radiation) is broken up into its component frequencies.

Atomic Emission Spectra. The Electromagnetic Spectrum High frequency Short wavelength High energy lower frequency longer wavelength lower energy.

Chemistry Daily 10’s Week 5.

How atoms produce light

1 Light as a Particle The photoelectric effect. In 1888, Heinrich Hertz discovered that electrons could be ejected from a sample by shining light on it.

Astronomical Spectroscopy. The Electromagnetic Spectrum.

What do you see? Old woman? Or young girl?  Is turning a light on and off a chemical or physical change? ◦ Physical change  What creates light?

Energy and Electrons Rev 11/05/08 Part One Pisgah High School M. Jones.

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.

Electron Arrangement and EMR – Virtual Lab Line Spectra

Properties of Light Is Light a Wave or a Particle?

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.

The Atom Chapter 9. Homework Assignment Chap 9 Review Questions (p 187): 1 – 22 Multiple Choice Questions:

Lecture 2110/24/05. Light Emission vs. Absorption Black body.

Atoms and the Periodic Table Chapter 8. Visible light consists of electromagnetic waves Electromagnetic radiation: emission and transmission of energy.

Advanced Higher Chemistry Unit 1 Spectroscopy. Spectroscopy  Spectroscopy is used to give information regarding the structure of atoms or molecules.

Advanced Higher Chemistry

Atoms and the Periodic Table Chapter 8. Homework Assignment Chap 8 Read p 223 – 231; Applying the Concepts (p 243): 1 – 13, 15 – 17, 19, 23.

Lecture 2010/19/05. wavelength Amplitude Node Electromagnetic Radiation (Light as waves) Moving Waves.

2.3 Electron Arrangement Atomic Emission Spectra &

Electromagnetic Spectrum The emission of light is fundamentally related to the behavior of electrons.

NCCS & Properties of Light The Wave Description of Light Electromagnetic radiation is a form of energy that exhibits wavelike behavior.

The Electromagnetic Spectrum and Light. Wavelength - The distance between two consecutive peaks of a wave.

Spectroscopy and Electron Configurations

Chapter 4 – The Address of the Electron!)

Lab 12 Atomic spectra and atomic structure

 The Bohr model was proposed:  1913  by Neils Bohr  After observing the H line emission spectrum.

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

Electronic Structure. Bohr Bohr proposed that the __________ atom has only certain allowable energy states.

Modern Atomic Theory (a.k.a. the electron chapter!) Chemistry 1: Chapters 5, 6, and 7 Chemistry 1 Honors: Chapter 11 SAVE PAPER AND INK!!! When you print.

Electromagnetic Spectrum

The Bohr Model of the Atom. The behavior of electrons in atoms is revealed by the light given off when the electrons are “excited” (made to absorb energy).

Warmup Use the periodic table and the diagram below to write and sketch (when possible) the orbitals for: Na P Ag.

Warm-Up Lithium has an atomic weight of g/mol. When g of lithium is heated, it emits an energy measured at 262,500 joules. What is the energy.

Quantum The amount of energy needed to move an electron from it’s present energy level to the next higher one.

 Fusion – process of 2 nuclei that combine to make one (a new element ) and emitting large amounts of energy.  The sun is a giant ball of hydrogen.

Light, Energy, & Electrons. Discrepant Events/Questions.

Electrons in Atoms Light is a kind of electromagnetic radiation. All forms of electromagnetic radiation move at 3.00 x 10 8 m/s. The origin is the baseline.

Emission Spectra and Bohr-Rydberg

The Bohr Model: Atoms with Orbits pg LO: I can explain what line spectra represent.

Electromagnetic Waves Electromagnetic energy is created by objects in outer space and by humans.

Types of Spectra.

Electrons, Energy, and Light Waves

Models, Waves, and Light Models of the Atom Many different models: – Dalton-billiard ball model (1803) – Thompson – plum-pudding model (1897) – Rutherford.

Prepared by Lawrence Kok Tutorial on Electromagnetic Radiation, Emission Line spectrum and Bohr Model.

Warm-Up What is the difference between the Bohr’s Model of the Atom and the Quantum Model of the atom. What wavelength is associated with an electron.

Bohr’s Model of the Atom

Electromagnetic Spectrum

Bohr Model Of Atom.

Bohr Model Of Atom.

Why Light, why now?.

The Molecular Nature of Matter and Change

SCH4C Matter & Qualitative Analysis

Nature of light and atomic spectrum

The Hydrogen Spectrum Mike Jones Pisgah High School Chemistry

Quantum Mechanical Atom Part I: Electromagnetic Radiation Chapter 8 Section 1 & 2 of Jespersen 6th ed) Dr. C. Yau Spring 2014.

Quantum Mechanical Atom Part I: Electromagnetic Radiation Chapter 8 Section 1 & 2 of Jespersen 6th ed) Dr. C. Yau Spring 2013.

The Hydrogen Spectrum Mike Jones Pisgah High School Chemistry

Electrons in Atoms Bohr Model of the Atom

Bohr, Emissions, and Spectra

Quantum Theory.

Electrons in Atoms Bohr Model of the Atom

Chemistry “Electrons in Atoms”

Spectroscopy and Stationary States

Arrangement of Electrons in Atoms

Development of Quantum Mechanics Bohr’s Contribution

White Light - Dispersion

Presentation transcript:

Pisgah High School Chemistry Mike Jones The Hydrogen Spectrum Rev Canton, NC

In this experiment you will measure the wavelengths of the lines in the visible portion of the hydrogen spectrum and compare them to the calculated values predicted by the Bohr Model.

This is a spectroscope We can use it to measure the wavelengths of the lines in atomic spectra.

A high voltage is applied to a narrow tube filled with hydrogen gas and light is produced.

Behind the eyepiece is a transmission diffraction grating which separates the light into its components.

The spectral lines produced by the the diffraction grating appear superimposed over the scale.

The light from the hydrogen discharge tube passes through a narrow slit.

The spectral lines appear superimposed over the scale so that their wavelengths can be determined.

The wavelength is the number times meters. Or the wavelength is the number times 100 nanometers.

Light from the spectrum tube coming through the slit Measure the wavelength of each line in meters and nanometers. Actual photograph of hydrogen spectrum. - M. Jones 2/5/04

Now you will predict the wavelength of light emitted as the electron moves from a higher energy level to a lower energy level. You will be given the energy level the electron comes from, and the energy level the electron goes to.

Use Bohr’s equation to predict the energy of each allowed state. n is the principal quantum number and has values of 1, 2, 3 … 7

R h is called the Rydberg Constant, R h has a value of 2.18 x J.

Next, find the difference between the two allowed energy states.  E = E final – E initial Then, compute the wavelength.

Initial energy level n initial = Final energy level n final = Initial energy (J) E inital = Final energy (J) E final = Energy difference in (J)  E = Wavelength (m)  Wavelength (nm)  Complete a table like the one below.

You will now combine your results with the results of other students to compile a list of all of the possible transitions from a higher energy level to a lower energy level, which give off light. A table like the following one will be on the board.

Electrons come from these higher energy levels and go to … …these lower levels These transitions do not result in an emission. Enter the wavelengths in nanometers here.

Finally, compare the wavelengths you measured to the wavelengths predicted by the Bohr model. How do they compare? Were all of these lines visible? In what parts of the electromagnetic spectrum do they appear?

Do the results of your experiment support the Bohr Model? Why or why not? What additional experiments could you do in order to further test the model?

Send questions, comments, and suggestions to: Mike Jones Pisgah High School 1 Black Bear Drive Canton, NC