History of Atomic Theory Chapter 5 - Part 2
Objectives - 1 List the 4 parts of Dalton’s Atomic Theory ad explain its significance to the history of modern atomic theory. Diagram and explain the significance of a Crooke’s Tube. Explain how the beam must have been negatively charged particles. Explain how Thomson discovered the existence of the proton, the electron, and found the charge-to- mass ratio of the electron. Explain and draw a picture of the Plum Pudding Model.
Objectives - 2 Explain and draw a picture of Millikan’s Oil Drop Experiment. Explain how the Oil Drop Exp. lead to the discovery of the charge on the electron. Explain how a fundamental principle of the ODE was “like charges repel.” State the discovery of William Roentgen. State the discovery of Henri Becquerel.
Democritus of Abdera
Ancient Greece - 4th century BC first suggested the existence of tiny fundamental particles that make up matter. atoms = indestructible did not agree with the “current” sci theory - but did not explain chemical behavior - and lacked experimental support.
John Dalton
Eaglesfield, England Father of modern atomic theory Pro: advance in the description and nature of chemical reactions. Con: did not hold up when subatomic particles were disovered
Dalton’s Atomic Theory 1. All elements are composed of tiny individual particles - called atoms. 2. All matter is composed of combinations of these atoms. 3. Atoms of different elements are different. 4. Atoms of the same element have the same size, mass, and form.
Dalton’s Atom The atom is a solid indestructible sphere.
William Crookes
British physicist investigated why gases glow
Crookes’ Tube
Crookes’ Experiment used a partially evacuated tube with a low pressure gas and ran a current through it power on: a green glow was emitted as a beam of light ran across the tube If the charge on the plates as switched...
Crookes’ Outcomes It was a beam of particles? How did he know? Determined the particles had a negative charge - due to... Created a cathode ray tube (also called a Crookes Tube) This was the precursor to the TV tube - Thank you Crookes!!!
JJ Thomson
British physicist continued Crookes work Experiment: applied an electric field which bent the light inside the tube back to a straight path and was able to measure this field.
Thomson’s Outcomes discovered the electron used the strength of the field was able to determine the charge-to-mass ratio of this negative particle beam - now so named determined the existence of the proton (because of neutrality)
Thomson’s Model Plum Pudding Model Negatively charged electrons embedded in a positive mass of proton”ness”
JJ’s Pros & Cons Pro: did explain some of the electrical nature of matter. Con: did not say anything about the number of charged particles or their arrangement. Won NOBEL PRIZE in 1906
Robert Millikan
Millikan & Einstein
Robert Millikan US Physicist NOBEL PRIZE 1932
Oil Drop Experiment
Millikan’s Outcomes determined the charge on a single electron using the charge-to-mass ratio from Thomson, many scientists determined the mass of an electron
Wilhelm Roentgen
William Roentgen Discovered x-rays killed his wife
Henri Becquerel
French scientist Left a sample of uranium ore in a drawer with glass photo plates and there was fogging on the plates serendipity
Becquerel’s outcomes concluded something in the sample itself must be capable of “fogging” the plates; the sample must give off some kind of ray without the influence of the sun rays were the product of radioactivity credited with the discovery of radioactivity
Marie & Pierre Curie
Pierre, Pierre’s Assistant, and Marie Curie
Pierre & Marie Curie
The Curie Family: Pierre, Marie, Irene, and Grandfather Curie
Marie & Pierre Curie French physicists intrigued with Becquerel’s work studied radioactivity Marie discovered POLONIUM
Ernest Rutherford
New Zealand discovered the nucleus of the atom Planetary Motion Model
Gold Foil Experiment
Gold Foil Experiment - 2 A beam of alpha particles was directed at a thin sheet of gold foil with a fluorescent screen around it. Most of the alpha particles went straight through it - or had very little deflection. A few were deflected back at very sharp angles. A 15-inch shell fired at a piece of tissue paper and it came back and hit you.
Rutherford concludes... Atoms have almost all of their mass concentrated in a very small positively charged region = the nucleus The nucleus is surrounded by electrons which are at a relatively large distance. Why did the electrons not crash into the nucleus in Rutherford’s model?
Planetary Motion Model Electrons orbit around the nucleus like planets orbit around the sun. The nucleus held (only) protons (for the time being).
Hans Geiger
Student of Rutherford He was one of the people who had to spend long hours (in mostly darkness) counting the particles that hit the screen.
Created the first electrical particle counter - The Geiger counter
Geiger’s contributions Determined that alpha particles were made up of 2 protons and 2 neutrons. (1908) This gives an alpha particle a mass number of ??? and a nuclear charge of ???.
Geiger - Rutherford’s student
Curie-Joliot & Joliot
Irene Curie-Joliot & Frederic Joliot Bombarded beryllium with alpha particles - which created a beam of energy that had great power. It was able to penetrate metals. They thought it was a new form of energy; they thought it was gamma rays.
James Chadwick
British physicist and chemist Found the Curie-Joliot beam of energy was unaffected by magnetic fields - meaning it must be neutral. Particles moved at 1/10 the speed of light - so it was NOT radiant energy - it must be PARTICLES
Chadwick’s Particles The new particles had approximately the same mass as a proton - but these new particles had NO CHARGE. He is credited with the discovery of the neutron.
after Chadwick After neutrons were discovered, isotopes of various elements were discovered.
Neils Bohr
Bohr & Einstein Bohr continued with energy calculations and he further developed the planetary motion model to include neutrons, and specific energies of electrons in a certain path.
By no means have we finished our story. We come revisit atomic history in a little bit to learn more about what other theories have developed and find out where we are now.