Atoms and Nuclear Chemistry Atoms Isotopes Calculating Average Atomic Mass Radioactivity
Atoms An atom is the smallest particle of an element that has all of the properties of that element.
Composition of the Atom Nucleus Positively charged Very Dense most of the mass of the atom is found in the nucleus Electron Cloud Area surrounding the nucleus Negatively charged Occupies most of the volume of the atom
Subatomic Particles Subatomic Particle Symbol Charge Location in Atom Mass Proton p +, Positive in the nucleus 1.673 10-24 g Electron e -, Negative outside of the nucleus 9.109 10-28 g Neutron n, Neutral in the nucleus 1.675 10-24 g The identity of an element is determined by the number of protons in the nucleus. The chemical behavior of an element is determined by the arrangement of the electrons in the atom.
Atomic Mass Units (Amu) Special unit used for measuring the mass of an atom. One amu is equal to 1/12 the mass of a carbon-12 atom.
Atomic Mass Units (Amu) Masses of Subatomic Particles in Amu Particle Mass (amu) Proton 1.007276 1 Neutron 1.008665 1 Electron 0.0005486
Charge of an Atom Atoms are electrically neutral. The number of protons in an atom equals the number of electrons.
Ions Ions are formed when an atom gains or loses electrons. anion negatively charged ion formed when an atom gains electrons cation positively charged ion formed when an atom loses electrons We will talk more about ions later this year.
Atomic Number What is it? the number of protons in the nucleus of an atom. found on the periodic table Determine the atomic number for each of the following elements. Li N Mg 3 7 12
What is it? Mass Number the sum of the neutrons and protons in the nucleus of an atom (whole number) Mass number is not given on the periodic table for most elements (Do not round the atomic mass on the periodic table to find mass number!) Ways to indicate mass number: Hyphen notation Nuclear Symbol Chlorine-35 This is not a fraction. Do not write a fraction bar!
Write the hyphen notation and nuclear symbol for the element containing 4 protons and 5 neutrons. Beryllium-9 Determine the number of neutrons in Argon-40. The atomic number for argon is 18. 40-18 = 22.
Element (hyphen notation) Complete the following table. Nuclear Symbol Atomic Number Mass Number Sodium -22 22 Number of Protons Number of Neutrons Number of Electrons 11 11 11 11 9 19 9 Fluorine-19 9 10 Bromine-80 35 80 35 45 35 Calcium-40 20 40 20 20 20 Hydrogen-1 1 1 1 0 1
Isotopes All atoms of the same element have the same number of protons, but the number of neutrons may vary. Isotopes are atoms of the same element which have different numbers of neutrons.
Complete the following table for the 3 commonly occurring isotopes of oxygen. Isotope Nuclear Symbol Number of Protons Number of Electrons Number of Neutrons Mass Number 8 8 8 16 8 8 9 17 8 8 10 18 Mass (amu) Oxygen 16 15.99415 Oxygen 17 16.999131 Oxygen - 18 17.999160 What structural characteristics do all oxygen atoms have in common? All oxygen atoms have the same number of protons and electrons. What differences exist between the isotopes of oxygen? The mass number, number of neutrons and mass of each isotope are different. The isotopes of an element do not differ significantly in their chemical behavior. Why do you think this is so? The chemical behavior is determined by the number of electrons and they all contain the same number of electrons.
Calculating Average Atomic Mass The average atomic for an element is given on the periodic table, but how was it determined? In order to calculate the average atomic mass for an element, you must know the percent abundance and atomic mass for each of the isotopes of that element.
Example Problem The average atomic mass of oxygen is given as 15.999 amu on the periodic table. Let s see how that was calculated. Isotope Atomic Mass Percent Abundance Oxygen 16 15.99415 amu 99.762% Oxygen 17 16.999131 amu 0.038% Oxygen 18 17.999160 amu 0.200% 15.99415 amu = 15.95608 amu 16.999131 amu x = 0.0064597 amu 17.99160 amu = 0.03598 amu 15.95608 amu + 0.0064597 amu + 0.03598 amu = 15.999 amu
A certain element exists as three natural isotopes as shown in the table below. Isotope Mass (amu) Percent Abundance Mass Number 1 19.99244 90.51 20 2 20.99395 0.27 21 3 21.99138 9.22 22 Calculate the average atomic mass of this element to the nearest thousandth. 19.99244 amu = 18.09515744 amu 20.99395 amu = 0.056683665 amu 21.99138 amu = 2.027605236 amu 18.09515744 amu + 0.056683665 amu + 2.027605236 amu = 20.179 amu Identify the element. Neon
Carbon has three naturally occurring isotopes: Carbon-12 (12.000 amu), Carbon-13 (13.003 amu), and Carbon-14 (14.003 amu). Based upon the average atomic mass of carbon (12.011 amu), which isotope of carbon do you think is the most abundant in nature? Explain your answer. Carbon-12 is the most abundant in nature. This answer is based on the fact that the average atomic mass of carbon is 12.011 amu which is closest to the mass of carbon- 12.
An element has two naturally occurring isotopes. The mass of the first isotope is 64.9278 amu and the mass of the second isotope is 62.9296 amu. The average atomic mass of the element is 63.546 amu. Calculate the percent abundance of each isotope to two decimal places. Let x = the percent as a decimal of the first isotope and y = the percent as a decimal of the second isotope (64.9278)x + (62.9296)y = 63.546 We also know that: x + y = 1, therefore y = 1-x (64.9278)x + (62.9296)(1-x) = 63.546 64.9278x + 62.9296 62.9296x = 63.546 1.9982x = 0.6164 x = 0.3085; 1-x = 0.6915 The percent abundances are 30.85% and 69.15%.
Discovery of Radioactivity Radioactivity was accidently discovered in 1896 by the French chemist Henri Becquerel. Becquerel was studying the properties of fluorescent materials, substances that glow in the dark having been exposed to light. On one occasion, Becquerel placed the minerals he was studying along with some unexposed photographic film in a laboratory drawer. When he retrieved the film on a later date, he found that it was foggy.
Discovery of Radioactivity Upon further investigation, Marie Curie and her husband Pierre, were able to determine that the fogginess was caused by rays emitted by the uranium in the mineral samples. Marie Curie named the process by which materials give off such rays radioactivity; the rays and particles emitted by a radioactive source are called radiation.
Ionizing vs. Nonionizing Radiation Ionizing radiation radiation with enough energy to produce ions by knocking electrons off some atoms of a bombarded substance. Alpha, beta, gamma, and X-rays are examples of ionizing radiation. Ionizing radiation can cause changes to living cells. Nonionizing radiation not capable of ionizing matter. Radio waves and visible light are forms of nonionizing radiation.
Radioisotopes Radioisotopes are isotopes that are radioactive because they have unstable nuclei.
Nuclear Stability The stability of the nucleus depends upon its ratio of neutrons to protons. Too many or too few neutrons lead to an unstable nucleus. When the number of protons in stable nuclei is plotted against the number of neutrons, a beltlike graph is obtained. This stable nuclei cluster over a range of neutron-proton ratios is referred to as the band of stability. Stable isotopes fall within the band of stability and have neutron to proton ratios of nearly 1:1 at the lower range and nearly 1.5:1 at the upper range. Such isotopes tend to be stable. Radioactive isotopes fall outside of the band of stability.
Band of Stability Would you expect Helium-4 to be a stable isotope? Why or why not? Yes, the neutron to proton ratio is 1:1. (falls within the band of stability) Would you expect Carbon- 14 to be a stable isotope? Why or why not? No, the neutron to proton ratio is 1.3:1 (falls above the band of stability)
What happens if a nucleus is unstable? Unstable nuclei undergo spontaneous changes that change their number of protons and neutrons. In this process, they give off large amounts of energy and increase their stability. Reminder: The identity of an element changes when the number of protons changes.
Types of Radioactive Decay During radioactive decay, unstable atoms lose energy by emitting one of several types of radiation. The three main types of radiation are alpha, beta, and gamma.
Properties of the Three Most Common Types of Radiation Radiation Alpha Beta Gamma Composition Symbol Mass alpha particles (helium nucleus) 4 He 2 4 amu beta particles (electron) 0 e -1 0-1 or nearly 0 amu (0.0055 amu) form of electromagnetic radiation 0 0 0 amu Electric Charge Penetrating Power 2+ 1-0 stopped by paper, wood, cloth, etc. stopped by aluminum or other metals stopped by lead
Alpha Emission (Decay) An alpha particle ( ) is composed of two protons and two neutrons bound together. Alpha emission is restricted almost entirely to very heavy nuclei. In these nuclei, both the number of neutrons and the number of protons need to be reduced in order to increase the stability of the nucleus. All nuclei with atomic numbers greater than 83 are radioactive. A majority of these undergo alpha emission.
Alpha Emission (Decay) In a balanced nuclear equation, the total of the mass numbers and atomic numbers on each side of the equation must be equal. Describe the change in the atomic number. The atomic number decreases by 2. Describe the change in mass number. The mass number decreases by 4. Remember: Two protons and two neutrons are lost by the nucleus.
Beta Emission (Decay) Beta emission ( ) is the emission of electrons from the nucleus when a neutron is converted to a proton and an electron. Beta emission occurs when the nucleus of an element has too many neutrons. This is true of elements that fall above the band of stability.
Beta Emission (Decay) Describe the change in the mass number. The mass number stays the same. Describe the change in atomic number. The atomic number increases by 1. What happens to the neutron to proton ratio? The neutron to proton ratio decreases.
Gamma Emission (Decay) Gamma rays ( ) are high-energy electromagnetic waves emitted from a nucleus as it changes from an excited state to a ground state. Gamma rays are produced when nuclear particles undergo transitions in energy levels. Gamma emission usually follows other types of decay that leave the nucleus in an excited state.
Gamma Emission (Decay)
Positron Emission (Decay) Positron emission ( ) occurs when a proton is converted into a neutron. A positron is a particle that has the same mass as an electron, but has a positive charge and is emitted from the nucleus during some kinds of radioactive decay. Positron emission occurs when elements have too many protons to be stable. This is true of elements that fall below the band of stability.
Positron Emission (Decay) Describe the change in the mass number. The mass number stays the same. Describe the change in atomic number. The atomic number decreases by 1. What happens to the neutron to proton ratio? The neutron to proton ratio increases.
Electron Capture Electron capture ( ) occurs when an inner orbital electron is captured by the nucleus of its own atom. The inner orbital electron combines with a proton and a neutron is formed. Electron capture also occurs in atoms with too many protons.
Electron Capture Describe the change in the mass number. The mass number stays the same. Describe the change in atomic number. The atomic number decreases by 1. What happens to the neutron to proton ratio? The neutron to proton ratio increases.
Complete the following nuclear equations and identify the type of radioactive decay. 1. + 2. 3. + 4. + beta decay electron capture alpha decay positron emission
Write nuclear Decay equations for each of the following. 1. alpha decay of polonium-210 2. beta decay of copper-66 3. oxygen-15 undergoes positron emission 4. argon-37 undergoes electron capture
Write nuclear Decay equations for each of the following. 5. potassium-38 undergoes positron emission 6. silver-106 undergoes electron capture 7. beta decay of zirconium-91 8. alpha decay of thorium-230
Radioactive Decay Series A radioactive decay series is a series of nuclear reactions that begins with an unstable nucleus and results in the formation of a stable nucleus.
Radioactive Decay Series
Decay Series Write the series of reactions that represent the decay series for uranium-238.
Transmutation Transmutation conversion of an atom of one element to an atom of another element. Transmutation may occur through radioactive decay. Induced Transmutation may also occur when high energy particles (protons, neutrons, or alpha particles) bombard the nucleus. Transuranium elements elements in the periodic table with atomic numbers above 92. These elements have been synthesized in nuclear reactors and nuclear accelerators; which accelerate the bombarding particles to very high speeds.
Transmutation 1. The nuclear equation for the induced transmutation of aluminum-27 into phosphorus-30 by alpha particle bombardment is written below. Which particle is emitted from the aluminum atom? neutron
2. Write the balanced nuclear equation for the induced transmutation of aluminum-27 into sodium-24 by neutron bombardment. An alpha particle is released in the reaction. 3. Write the balanced nuclear equation for the alpha bombardment of plutonium-239. One of the reaction products is a neutron.
Nuclear Fusion In nuclear fusion, light nuclei combine to form a heavier, more stable nucleus. Nuclear fusion occurs in the sun where hydrogen nuclei fuse to make helium nuclei.
Nuclear Fusion as a Power Source Nuclear fusion produces more energy per gram of fuel than nuclear fission. Potential fuels (hydrogen-2, hydrogen-3) are inexpensive and readily available. Fusion products are usually not radioactive. Unfortunately fusion requires high temperatures to initiate the reaction and once started no known structural materials can contain the reaction.
Nuclear Fission In nuclear fission, fissionable isotopes split when bombarded with neutrons. 1 235 140 n + U Ba + 93 Kr + 3 n 0 92 56 36 0 1 The isotopes release neutrons that cause a chain reaction.
Nuclear Fission as a Power Source Uranium-235 is typically used as the source of fuel in controlled fission reactions that produce large amounts of energy. A major problem associated with nuclear fission is the issue of how to contain, store and dispose of the nuclear waste produced.