CHAPTER 9 Nuclear Energy I. Radioactivity (pg ) I. Radioactivity (pg )
Radioactive Elements
A. Definitions Radioactivity Process of unstable nuclei of elements becoming stable through emitting particles or releasing energy away from the atom Also called nuclear decay
DefinitionsDefinitions During nuclear decay, the element can transform into a different isotope of the same element or to a different element completely. Transmutation process of changing one element into another element by nuclear decay
DefinitionsDefinitions Nuclear radiation is the released energy and matter during nuclear decay. This can have both positive and negative effects for life on earth.
DefinitionsDefinitions Isotopes – elements that have the same number of protons but different number of neutrons in their nuclei.
IsotopesIsotopes Carbon-12, Carbon-13, Carbon-14
Where does this take place? Radioactivity (nuclear decay) happens in the nucleus of the atom.
B. Types of Radiation Alpha ( ) helium nucleus paper 2+ Beta-minus ( -) electron 1- plastic Gamma ( ) high-energy photon 0 lead
Types of Radiation Neutron emission (n) 1 0 n 0 charge
C. Nuclear Decay Why some nuclei decay… to obtain a stable ratio of neutrons to protons Stable Unstable (radioactive)
C. Nuclear Decay Alpha Emission Beta Emission TRANSMUTATIONTRANSMUTATION
ExampleExample Actinium-217 decays by releasing an alpha particle. Write the equation for this decay process and determine what element is formed. Step 1: Write the equation with the original element on the reactant side and products on the right side.
ExampleExample 217 A4 89 Ac Z X + 2 He Step 2: Write math equations for the atomic and mass numbers. 217 = A = Z + 2
ExampleExample Step 3: Rearrange the equations. A = 217 – 4Z = Step 4:Solve for the unknown value, and rewrite the equation with all nuclei. A = 213Z = 87
ExampleExample Ac 87 Fr + 2 He This is an example of alpha decay.
D. Half-life Half-life (t ½ ) time it takes for half of the radioactive nuclei in a sample to decay Example Half-lives polonium seconds lead hours iodine days carbon-145,370 years uranium billion years
Half-lifeHalf-life
If we start out with 1 gram of the parent isotope, after the passage of 1 half-life, there will be 0.5 gram of the parent isotope left.
D. Half-life How much of a 20-g sample of sodium-24 would remain after decaying for 30 hours? Sodium-24 has a half-life of 15 hours. GIVEN: total time = 30 hours t 1/2 = 15 hours original mass = 20 g WORK : number of half-lives = 2 20 g ÷ 2 = 10 g (1 half-life) 10 g ÷ 2 = 5 g (2 half-lives) 5 g of 24 Na would remain.
Nuclear Forces There are two types of forces in the nucleus. Strong nuclear force – helps attract the protons and neutrons in the nucleus and keep them together. Repulsive force- protons repel each other because they are the same charge
Nuclear Forces In stable atoms, the attractive forces are stronger than the repulsive forces.
A. F ission splitting a nucleus into two or more smaller nuclei some mass is converted to large amounts of energy
A. F ission chain reaction - self-feeding reaction
FissionFission Chain reactions can be controlled and used to create electricity in nuclear power plants. The minimum amount of a substance that can undergo a fission reaction and sustain a chain reaction is called critical mass.
B. Fusion combining of two nuclei to form one nucleus of larger mass produces even more energy than fission occurs naturally in stars
FusionFusion
Nuclear Radiation in Life Background radiation is nuclear radiation that is around you from natural sources like the sun, soil, rocks, and space. A rem or millirem (1 rem = 1000millirems) is the unit for radiation.
Nuclear Radiation in Life A safe limit is set at 5000 millirems/year. Occupation – X-ray tech, flight attendant Where you live- high elevation, near rocks Activities - smoking
A. Nuclear Power Fission Reactors
A. Nuclear Power Fusion Reactors (not yet sustainable) Tokamak Fusion Test Reactor Princeton University National Spherical Torus Experiment
A. Nuclear Power 235 U is limited danger of meltdown toxic waste thermal pollution Hydrogen is abundant no danger of meltdown no toxic waste not yet sustainable FISSIONFISSION FUSIONFUSION vs.
Other benefits to radiation Smoke detectors Disease detection Ultra sound CT scan MRI Cancer treatment