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PreAP Chemistry Chapter 3

PreAP Chemistry Chapter 3. Democritus was the early Greek philosopher who is credited with the concept of the atom (atomos) –which means invisible. Democritus was the early Greek philosopher who is credited with the concept of the atom (atomos) –which means invisible

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PreAP Chemistry Chapter 3

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  1. PreAP Chemistry Chapter 3

  2. Democritus was the early Greek philosopher who is credited with the concept of the atom (atomos) –which means invisible

  3. Democritus was the early Greek philosopher who is credited with the concept of the atom (atomos) –which means invisible Law of Definite Proportions states that the elements in a specific compounds always contain the same proportions by mass.

  4. Law of Multiple Proportions states that if two or more different compounds are composed of the same two elements, then the ratio of the masses of the second element combined with a certain mass of the first element is always a ratio of small whole numbers

  5. Dalton is an English school teacher who proposed the law of conservation of mass, the law of definite proportions, and the law of multiple proportions.

  6. Dalton is an English school teacher who proposed the law of conservation of mass, the law of definite proportions, and the law of multiple proportions. He is also known as the Father of the Atomic Theory

  7. Dalton’s atomic theory 1.All matter is composed of very small particles called atoms

  8. Dalton’s atomic theory • All matter is composed of very small particles called atoms • Atoms of a given element are identical in size, mass, and other properties; atoms of different elements differ in these properties.

  9. 3.Atoms cannot be subdivided, created, or destroyed

  10. Atoms cannot be subdivided, created, or destroyed • 4.Atoms of different elements combine in simple whole-number ratios to form chemical compounds.

  11. Atoms cannot be subdivided, created, or destroyed • 4.Atoms of different elements combine in simple whole-number ratios to form chemical compounds. • 5.In chemical reactions, atoms are combined, separated, or rearranged.

  12. Two aspects of Dalton’s atomic theory proven to be incorrect: • We now know atoms are divisible.

  13. Two aspects of Dalton’s atomic theory proven to be incorrect: • We now know atoms are divisible. • b. Atoms of the same element can have different masses.

  14. Atom --smallest particle of an element that retains the properties of that element.

  15. Two regions of an atom 1. Nucleus -- small region near the center of the atom. Composed of two particles—the proton which is positively charged and the neutron which is neutral (zero) charged.

  16. 2. Electron Cloud --composed of negatively charged electrons. It is very large in comparison to the nucleus.

  17. 2. Electron Cloud --composed of negatively charged electrons. It is very large in comparison to the nucleus. Subatomic particles—protons, neutrons, electrons

  18. 2. Electron Cloud --composed of negatively charged electrons. It is very large in comparison to the nucleus. Subatomic particles—protons, neutrons, electrons Cathode Ray tubes — the instrument used in the discovery of the electron

  19. J. J. Thomson is the man credited with the discovery of the electrons in the late 1800’s

  20. J. J. Thomson is the man credited with the discovery of the electrons in the late 1800’s Millikan discovered the mass of the electrons

  21. Knowledge of electrons led to two inferences about atomic structure: 1.Because atoms are electrically neutral, they must contain positive charge to balance the negative electrons.

  22. Knowledge of electrons led to two inferences about atomic structure: 1.Because atoms are electrically neutral, they must contain positive charge to balance the negative electrons. 2.Because electrons have so little mass, atoms must contain other particles to account for most of their mass

  23. Nucleus of the atom—discovered by Lord Ernest Rutherford

  24. Nucleus of the atom—discovered by Lord Ernest Rutherford Gold foil experiment—actually done by Hans Geiger and Ernest Marsden

  25. Observations: • Majority of the alpha (α)particles penetrated foil undeflected. • b.About 1 in 20,000 were slightly deflected • c.About 1 in 20,000 were deflected back to emitter

  26. Conclusions: 1. Mass of the atom and the positive charge are concentrated in small regions called nucleus

  27. Conclusions: 1. Mass of the atom and the positive charge are concentrated in small regions called nucleus 2. Most of the atom is empty

  28. Conclusions: 1. Mass of the atom and the positive charge are concentrated in small regions called nucleus • Most of the atom is empty • 3.Magnitude of charge on the nucleus is different for different atoms

  29. 4. Number of electrons outside the nucleus = number of units of nuclear charge (to account for the fact that the atom is electrically neutral)

  30. 4. Number of electrons outside the nucleus = number of units of nuclear charge (to account for the fact that the atom is electrically neutral) Atoms are electrically neutral because they contain equal numbers of protons and electrons

  31. 1. What kinds of particles are being emitted by the radioactive source? What is their charge?

  32. What kinds of particles are being emitted by the radioactive source? What is their charge? • Alpha Particles, positive

  33. 2. Toward what are the alpha particles being directed?

  34. Toward what are the alpha particles being directed? • Gold foil

  35. What happens when the charged particles strike the surface of the gold foil?

  36. What happens when the charged particles strike the surface of the gold foil? • Most go straight through • Some were slightly deflected • Some were greatly deflected

  37. What was the purpose of the fluorescent screen?

  38. What was the purpose of the fluorescent screen? • See where the alpha particles hit

  39. What did Rutherford conclude from this gold foil experiment regarding the amount of empty space in the atom? Why was he able to conclude this?

  40. What did Rutherford conclude from this gold foil experiment regarding the amount of empty space in the atom? Why was he able to conclude this? • Most of the atom is empty space because most of the particles went straight through.

  41. How does the deflection path of a charged particle that strikes the center of a gold atom differ from that path of a particle that passes only near the center?

  42. How does the deflection path of a charged particle that strikes the center of a gold atom differ from that path of a particle that passes only near the center? • If it hits the center it is deflected back to the emitter. If it passes near the center it is slightly deflected.

  43. Based on this experiment, where is most of the positive charge and mass of an atom found?

  44. Based on this experiment, where is most of the positive charge and mass of an atom found? • Nucleus – in the center

  45. What would have been observed if the positive charge of an atom had been thinly spread out throughout the atom?

  46. What would have been observed if the positive charge of an atom had been thinly spread out throughout the atom? • All the alpha particles would have behaved the same – gone straight through.

  47. Nuclear Forces the short-range proton-neutron, proton-proton, and neutron-neutron forces that hold the nuclear particles together

  48. Nuclear Forces the short-range proton-neutron, proton-proton, and neutron-neutron forces that hold the nuclear particles together Mass of one proton = mass of neutron = mass of 1837 electrons

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