Presentation is loading. Please wait.

Presentation is loading. Please wait.

Early Models of the Atom

Published byDwayne Thomas Modified over 6 years ago

Similar presentations

Presentation on theme: "Early Models of the Atom"— Presentation transcript:

1 Early Models of the Atom
Contents: J. J. Thomson The electron Plum pudding model of the atom Rutherford Gold foil experiment Nucleus model Solving closest approach problems Whiteboard

2 Richard Feynman: “If, in some cataclysm, all of scientific knowledge were to be destroyed, and only one sentence passed on to the next generation of creatures, what statement would contain the most information in the fewest words? I believe it is the atomic hypothesis that all things are made of atoms — little particles that move around in perpetual motion, attracting each other when they are a little distance apart, but repelling upon being squeezed into one another. In that one sentence, you will see, there is an enormous amount of information about the world, if just a little imagination and thinking are applied.”

3 J.J. Thomson 1856 - 1940 Discovers the electron e/m ratio
                                            “Plum Pudding” model

4 Ernest Rutherford ( ) Scattering of  (an  is 2p2n – He nucleus) surprising results:                                

5 Most Alphas are not deflected much
More deflection closer to nuclei

6 Ernest Rutherford (1837-1937) But is also has problems:
Rutherford’s atom: (It has a nucleus) But is also has problems: Why doesn’t the electron radiate energy? How does this explain the spectral lines they had been observing? I won’t Bohr you with the solution to this right now… You can see cm, mm even .1 mm on a meter stick and that’s about it. So the smallest thing visible to you is about 1E-4 m, and atoms are about a million times smaller than that. So to picture that, know that a 1 cm stack of paper is 100 sheets, so a meter stack is 10,000 sheets, and therefore a 100 m stack would be a million sheets of paper. so one in a million is one sheet of paper compared to a stack 100 m tall. If the atom is as wide as a soccer field, the nucleus is 1 mm wide. Size of atoms – you can see E-4 m cm, mm, .1 mm, 100 papers, 1m paper 100 m paper,

7 Nuclear Radius R - Nuclear radius (m) Ro - Fermi Radius (1.20x10-15 m)
A - Mass # (#p +#n) Example 1: What is the radius of a Uranium 235 nucleus? (A = 235)

8 Solving closest approach
QN Qp Example 2: What is the closest approach of an alpha particle (m = 6.644x10−27 kg) going 2.6 x 106 m/s if it approaches a carbon nucleus head on?

9 Solving closest approach
QN Qp Example 3: Through what potential must you accelerate an alpha particle to penetrate a Uranium-235 (Z = 92) nucleus? (r = 7.4 fm) (1 fm = 1x10-15 m) PE r

10 Solving closest approach
Ek = 1/2mv2 V = W/q, W = Vq V = kq/r Vqp = 1/2mv2 kinetic = potential 1/2mv2 = qp(kqN/r) r QN Qp Example 2: What is the closest approach of an alpha particle (m = 6.644x10−27 kg) going 2.6 x 106 m/s if it approaches a carbon nucleus head on? Ek = 1/2mv2 = 1/2 (6.644x10−27 kg)(2.6 x 106 m/s)2 = E-14 J PE = Qp(kQN/r), r = Qp(kQN/PE) = (2x1.602E-19)(8.99E9)(6x1.602E-19)/( E-14 J) = E-13 m from center of the nucleus

11 Solving closest approach
Ek = 1/2mv2 V = W/q, W = Vq V = kq/r Vqp = 1/2mv2 kinetic = potential 1/2mv2 = qp(kqN/r) PE r Example 3: Through what potential must you accelerate an alpha particle to penetrate a Uranium (Z = 92) nucleus? (r = 7.4 fm) (1 fm = 1x10-15 m). Ek = V(2e) = (2e)(kqN/r) so V = (kqN/r) = (8.99E9)(92*1.602E-19)/(7.4E-15) = 17,905, V or about 18 MV

12 Closest Approach and Radius
Whiteboards: Closest Approach and Radius 1-3

13 What is the closest approach in nm of an Alpha particle going 15,000 m/s to a Gold nucleus. (3)
Mα = 6.644x10−27 kg Z = 79 for Gold 1/2mv2 = Qp(kQN/r) Ek = 1/2mv2 = 1/2(6.644E-27)(15000)2 = E-19 J Ek = (kQN/r)Qα, r = kQNQα/Ek = (8.99E9)(79*1.602E-19)(2*1.602E-19)/(7.4745E-19) = E-08 m = 49 nm 49 nm

14 What is the radius of a Carbon-12 nucleus?
Mα = 6.644x10−27 kg Z = 79 for Gold 1/2mv2 = Qp(kQN/r) Ek = 1/2mv2 = 1/2(6.644E-27)(15000)2 = E-19 J Ek = (kQN/r)Qα, r = kQNQα/Ek = (8.99E9)(79*1.602E-19)(2*1.602E-19)/(7.4745E-19) = E-08 m = 49 nm 2.75 fm

15 An Alpha particle’s closest approach brings it to within 47 fm of a Gold nucleus. What is its energy in eV (3) 1 fm = 1x10-15 m Z = 79 Find V at that distance, the alpha energy is twice that in eV because it has twice the charge of an electron. V = kQ/r = (8.99E9)(79*1.602E-19)/(47E-15) = 2,420, V = 2.42 MV so the alpha energy is 4.84 MeV 4.8 MeV

Download ppt "Early Models of the Atom"

Similar presentations

Unit 3: Atomic Theory Section A.2 – A.3

Unit 3: Atomic Theory Section A.2 – A.3
The Gold Foil and the Nucleus

The Gold Foil and the Nucleus
The following question was posed to the physicist Richard Feynman, winner of the Nobel Prize for his work on the theory of quantum electrodynamics: If,

The following question was posed to the physicist Richard Feynman, winner of the Nobel Prize for his work on the theory of quantum electrodynamics: If,
The Parts of an Atom.

The Parts of an Atom.
ATOMIC THEORY.

ATOMIC THEORY.
Section 2: Atomic Discoveries

Section 2: Atomic Discoveries
Discovery of the Nucleus Nuclear Physics Lesson 1.

Discovery of the Nucleus Nuclear Physics Lesson 1.
Atomic Theory 15,000 kilotons.  Dismissed idea of the atom. Early Greeks Two schools of thought:  Matter is made of indestructible particles called.

Atomic Theory 15,000 kilotons.  Dismissed idea of the atom. Early Greeks Two schools of thought:  Matter is made of indestructible particles called.
Early Experiments to Characterize the Atom 2. 4 Chapter 2 Atoms, Molecules, and Ions.

Early Experiments to Characterize the Atom 2. 4 Chapter 2 Atoms, Molecules, and Ions.
Nuclear Radius Probing Matter.

Nuclear Radius Probing Matter.
Review Problem Set 1. Plan for this week’s lab Lab syllabus, then sign agreement Check in with your lab partner Safety video Tuesday, IC 420 Section E:

Review Problem Set 1. Plan for this week’s lab Lab syllabus, then sign agreement Check in with your lab partner Safety video Tuesday, IC 420 Section E:
HISTORY OF THE ATOM JJ Thomson Neils Bohr Earnest Rutherford Albert Einstein.

HISTORY OF THE ATOM JJ Thomson Neils Bohr Earnest Rutherford Albert Einstein.
Atomic Structure. Model A: The plum pudding model J.J. Thompson Negative charges like raisins in plumb pudding Positive charge is spread out like the.

Atomic Structure. Model A: The plum pudding model J.J. Thompson Negative charges like raisins in plumb pudding Positive charge is spread out like the.
Accelerated ions Contents: Electron Volts and accelerated ions.

Accelerated ions Contents: Electron Volts and accelerated ions.
Atoms: The Building Blocks of Matter Chapter 4 Ancient Atomic Theory Ancient Atomic Theory Modern Atomic Theory P.24 Warm up: Has our view of atoms changed.

Atoms: The Building Blocks of Matter Chapter 4 Ancient Atomic Theory Ancient Atomic Theory Modern Atomic Theory P.24 Warm up: Has our view of atoms changed.
History at a Glance Atoms John Dalton 1803 Created Atomic Theory (studied chemical reactions) 1.All elements are composed of tiny indivisible particles.

History at a Glance Atoms John Dalton 1803 Created Atomic Theory (studied chemical reactions) 1.All elements are composed of tiny indivisible particles.
History of the Atom Chapter 4. The Atom… a Working Model The history of the atom has shown that through the years, the model had needed to be modified.

History of the Atom Chapter 4. The Atom… a Working Model The history of the atom has shown that through the years, the model had needed to be modified.
Section 4.2 Defining the atom. The Atom What we know now: Definition: Atoms are the smallest particle of an element that retains the properties of that.

Section 4.2 Defining the atom. The Atom What we know now: Definition: Atoms are the smallest particle of an element that retains the properties of that.
Contact forces. “If, in some cataclysm ( 大灾难 ), all of scientific knowledge were to be destroyed, and only one sentence passed on to the next generations.

Contact forces. “If, in some cataclysm ( 大灾难 ), all of scientific knowledge were to be destroyed, and only one sentence passed on to the next generations.
The Discovery of the Nucleus Rutherford's alpha scattering experiments were the first experiments in which individual particles were systematically scattered.

The Discovery of the Nucleus Rutherford's alpha scattering experiments were the first experiments in which individual particles were systematically scattered.

Similar presentations

Ads by Google