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Ch. 9: RADIOACTIVITY AND NUCLEAR REACTIONS

Ch. 9: RADIOACTIVITY AND NUCLEAR REACTIONS. Section 1-- RADIOACTIVITY. What is an atom?. An atom is the smallest piece of matter. Ex. The element silver is composed of only silver atoms . The element hydrogen is composed of only hydrogen atoms . .

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Ch. 9: RADIOACTIVITY AND NUCLEAR REACTIONS

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  1. Ch. 9: RADIOACTIVITY AND NUCLEAR REACTIONS • Section 1--RADIOACTIVITY

  2. What is an atom? • An atomis the smallest piece of matter. • Ex. The element silver is composed of only silver atoms. The element hydrogen is composed of only hydrogen atoms. • Atoms are composed of protons, neutrons, and electrons. • Nucleus= protons  + charge neutrons  no charge (neutral) • Outside the nucleus= electrons  - charge

  3. Atomic Number = # of protonsAtomic Mass = # of protons & # of neutrons Element Atomic #  Symbol  Atomic Mass  Uranium 92 U 238.029

  4. PROTONS • The total amount of charge in a nucleus is determined by the number of protons, which also is called the atomic number. • Atomic number = number of protons

  5. ELECTRONS • Negatively charged electronsare electrically attracted to the positively charged nucleus and swarm around it. • An electronhas a charge that is equal, but opposite to a proton’s charge. • Atoms usually contain the same number of protonsas electrons. • # of protons = # of electrons

  6. PROTONS AND NEUTRONS IN THE NUCLEUS • Protons and neutrons are packed together tightly in the nucleus. • The region outside the nucleus in which the electrons are located is large compared to the size of the nucleus.

  7. Nucleus/AtomVS. Marble/Stadium • The size of a nucleusin an atomcan be compared to a marble sitting in the middle of an empty college football stadium.

  8. Where is the majority of an atom’s mass? • The nucleus contains almost all the mass of the atom, because the mass of one proton or neutron is almost 2,000 times greater than the mass of an electron.

  9. MASSES

  10. HOW ARE PROTONS AND NEUTRONS HELD TOGETHER SO TIGHTLY IN THE NUCLEUS? • Usually only positive (+) and negative (-) charges attract, but another force, called the STRONG FORCE, causes protons and neutrons to be attracted to each other. (STRONG FORCE HOLDS NUCLEUS TOGETHER)

  11. FOUR BASIC FORCES • 1) GRAVITY • 2) ELECTROMAGNETIC • 3) STRONG (NUCLEAR) The strong force is one of the four basic forces and is about 100 times stronger than the electric force. • 4) WEAK (NUCLEAR)

  12. SHORT-RANGE FORCE • Protons and neutrons have to be close together, like they are in the nucleus, to be attracted by the strong force (SHORT-RANGE FORCE) (ONLY WORKS OVER SHORT DISTANCES—small atoms)

  13. LONG-RANGE FORCE • The electric force is a long-range force, so protons that are far apart still are repelled by the electric force. (ONLY WORKS OVER LONG DISTANCES—LARGE ATOMS)

  14. STRONG FORCE

  15. FORCESSTRONG VS. ELECTRIC

  16. RADIOACTIVITY • SMALL ATOMS • SF >(greater) EF • STABLE • LARGE ATOMS • EF >(greater) SF • Unstable • Particles repel; give off matter and energy. • This process ofnuclear decay is called radioactivity.

  17. LARGE ATOMS • LARGE nuclei tend to be UNSTABLE and can break apart or decay. • ALL nuclei that contain more than 83 protons ARE radioactive (ATOMIC NUMBER >greater than 83)

  18. ISOTOPES • Nuclei that have the same number of protons, but different number of neutrons are called isotopes. • EXAMPLE— U-235, U-238 Same element (URANIUM) At. # = 92 Different # of neutrons (U-235 = 143 n)best (U-238 = 146 n)

  19. CHAPTER 9: RADIOACTIVITY AND NUCLEAR REACTIONS Section2—NUCLEAR DECAY

  20. WHAT IS NUCLEAR RADIATION? • When an UNSTABLE nucleus decays, particles and energy are emitted from the decaying nucleus. • These particlesand energyare called NUCLEAR RADIATION. (Also known as NUCLEAR DECAY AND RADIOACTIVITY)

  21. WHAT ARE THE 3 TYPES OF NUCLEAR RADIATION? • The 3 types of nuclear radiation are alpha, beta, and gamma. • Alpha and betaradiation are particles (matter) • Gamma radiation is not a particle; it behaves like a wave; similar to light; electromagnetic radiation; most dangerous

  22. ALPHA PARTICLES • Made of protons and neutrons • Cannot pass through low density materials, such as a sheet of paper • SMOKE DETECTORS some give off alpha particles; smoke disrupts process and alarm goes off (Americium-241)

  23. What happens when an atom no longer has the same number of protons? • It is no longer the same element. (The number of protons identifies the element as a particular element) • Transmutationis the process of changing one element to another through nuclear decay.

  24. TRANSMUTATION

  25. BETA PARTICLES • Made of protons, neutrons, and electrons • Caused by another basic force—the WEAK FORCE • Much faster and can pass through low density materials, such as paper, but are stopped by aluminum foil

  26. GAMMA RAYS • They are NOT made of protons, neutrons, or electrons • They are a form of radiation called electromagnetic waves • They are able to travel through low and medium density materials, such as paperand aluminum foil; but are blocked by high density materials, such as lead and concrete

  27. Is RADIATION harmful? • Damage from alpha and beta particlesand gamma rays can cause cells in your body to quit functioning properly, which can lead to illness and disease. • How does someone protect themselves? 1. TIME (around material) 2. DISTANCE (from material) 3. SHIELDING (safety equipment) 4. ROUTINE MONITORING

  28. RADIOACTIVE HALF-LIFE • The half-life of a radioactive isotope is the amount of time it takes for half of thenuclei in a sample to decay. • Some decay to stable atoms in less than a second. • Some require millions of years to decay.

  29. RADIOACTIVE DATING • Some geologists, biologists, and archaeologists are interested in the ages of ROCKS and FOSSILS found on Earth. • CARBON DATING–carbon-14 is often used to find the ages of objects once living. (Also, potassium-40) • URANIUM DATING–uranium-235 can be used to estimate the ages of rocks.

  30. CHAPTER 9: RADIOACTIVITY AND NUCLEAR REACTIONS Section 3: DETECTING RADIOACTIVITY

  31. Because you can’t see or feel alpha and beta particles or gamma rays, you must use instruments to detect their presence. • A Geiger counter is a device that measures radioactivity by producing an electric current when radiation is present. The intensity of radiation present is determined by the number of clicks or flashes of light per second.

  32. BACKGROUND RADIATION • This type of radiation is not produced by humans. It comes mainly from Earth’s rocks, soils, and atmosphere (building materials—bricks, wood, and stones; food, water, and air)

  33. RADON GAS • The largest source of background radiation comes from radon gas. Radon is produced in Earth’s crust by the decay of Uranium-238. Radon gas can seep into houses and basements from the surrounding soil and rocks.

  34. CHAPTER 9: Radioactivity and Nuclear Reactions Section 4: NUCLEAR REACTIONS

  35. What is the first step in a game of pool? • A similar result occurs when a neutron is shot into the large nucleus of a uranium-235 atom. The nucleus is split. • The process of splitting 1 nucleus into 2 nuclei with smaller masses is called nuclear fission. The word “fission” means to divide. • FISSION RHYMES WITH DIVISION

  36. FISSION The total mass of the products is slightly less than the mass of the original nucleus and the neutron. The small amount of missing mass is converted into a tremendous amount of energy.

  37. CHAIN REACTION A chain reaction is an ongoing series of fission reactions. (Billions of reactions can occur each second) ↑ REACTIONS= ↑ ENERGY

  38. Nuclear fission is used to generate electricity and is used in nuclear weapons. • The critical mass is the amount of fissionable material required so that each fission reaction produces approximately 1 more fission reaction (keeps chain reaction going—so won’t die out or grow out of control).

  39. NUCLEAR FISSION

  40. U-235 VS. DYNAMITE • U-235 (1 nucleus) • Dynamite (1 molecule) • U-235 30 million times more energy

  41. U-235 VS. COAL • 1 gram of U-235 • 2 tons of COAL

  42. NUCLEAR FUSION • Even more energycan be released in another type of nuclear reaction called nuclear fusion. • In nuclear fusion, 2 nuclei with low masses are combined to form one nucleus of larger mass.

  43. NUCLEAR FUSION of the Sun • Extremely high temperatures are found in the center of stars, including the Sun. • These high temps (millions of degrees Celsius) are related to nuclear fusion.

  44. NUCLEAR FUSION of the Sun • A small amount of mass is changed into an enormous amount of ENERGY. • Earth receives a small amount of this energy as HEAT and LIGHT. • As the Sun ages, HYDROGEN nuclei are converted to HELIUM. (ONLY 1% OF SUN’S MASS HAS BEEN CONVERTED TO ENERGY—ENOUGH FOR 5 BILLION MORE YEARS)

  45. FUSION VS. FISSION Nuclear fission—splits nuclei apart (RHYMES WITH DIVISION) NUCLEAR FUSION—FUSES NUCLEI TOGETHER (SUN)

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