Chapter 2 Atoms and Elements Chapter 2 Atoms
- Slides: 138
Chapter 2 Atoms and Elements
Chapter 2 Atoms and Elements 2. 1 2. 2 2. 3 2. 4 2. 5 2. 6 2. 7 2. 8 2. 9 Imaging and Moving Individual Molecules Early Ideas about the building blocks of Matter Modern Atomic theory and the Laws that led to it The Discovery of the Electron The Structure of the Atom Subatomic Particles: Protons, Neutrons and Electrons in Atoms Finding Patterns: The Periodic Law and the Periodic Table Atomic Mass: The Average Mass of an Element’s Atoms Molar Mass: Counting Atoms by Weighing Them 2
Section 2. 1 Imaging and Moving Individual Atoms Atomos - indivisible • Pencil Lead is made of graphite – Made of carbon • If we divide the lead into smaller and smaller pieces eventually we end up with the tiniest piece that is still considered carbon • An atom of carbon http: //www. istockphoto. com/stock-photo-3251968 -pencil-tip. php http: //www. ej 2 hosting. com/gilmarcomuniones. es/atomic-structure-ofgraphite 3
Section 2. 1 Imaging and Moving Individual Atoms Atomos - indivisible • An atom of carbon is the smallest unit that we can divide graphite into and still call it carbon. • Is an atom of carbon truly indivisible? 4
Section 2. 1 Imaging and Moving Individual Atoms Scanning Tunneling Microscope - STM • Moves a current over a surface • Measures the “tunneling current” – The current that flows between the electrode and the surface even though the two are not touching • As the tip of the electrode moves over the surface it moves up or down to maintain a constant current. – Like feeling something gently in the dark to determine its shape • The STM forms an “image” of atoms 5
Section 2. 2 Early Ideas about the Building Blocks of Matter Greeks ~ 5 th century BC • Leucippus and Democritus – Matter is composed of small indivisible particles they named atomos – Democritus wrote “nothing exists except atoms and empty space, everything else is opinion. ” • Plato and Aristotle disagreed – Substances were composed of the various proportions of fire, air, earth and water. • Who’s point of view prevailed? Why? 6
Section 2. 2 Early Ideas about the Building Blocks of Matter Scientific Revolution ~ 16 th century • Modern Science began to emerge – – – Greater emphasis of observation Copernicus (Sun Centered Universe) Robert Boyle (We will meet him in Chapter 5) Isaac Newton (Physics) Finally the scientists we will meet in this section culminating in a man named John Dalton • 2000 years later these observations offered evidence that confirmed the initial atomic ideas of Leucippus and Democritus 7
Section 2. 3 Modern Atomic Theory and the Laws that Led to It Three Laws • Modern Atomic Theory – All matter is composed of atoms • Grew out of observations and laws • The Three Most Influential – – – The Law of Conservation of Mass The Law of Definite Proportions The Law of Multiple Proportions 8
Section 2. 3 Modern Atomic Theory and the Laws that Led to It The Law of Conservation of Mass • In a chemical reaction, matter is neither created nor destroyed – This is a Law because it describes what happens not why (theory or model) • The particles of matter rearrange during a chemical reaction • The amount of matter is conserved because the particles themselves are not changed • This was Lavoisier (Chapter 1) 9
Section 2. 3 Modern Atomic Theory and the Laws that Led to It Conceptual Connection • When a log burns up in a fire the mass of the ash is much less than the mass of the log. What happened the extra mass? 10
Section 2. 3 Modern Atomic Theory and the Laws that Led to It Solution • When a log burns up in a fire the mass of the ash is much less than the mass of the log. What happened the extra mass? • The extra mass is released into the air as carbon dioxide (CO 2) and water (H 2 O) 11
Section 2. 3 Modern Atomic Theory and the Laws that Led to It The Law of Definite Proportions • Joseph Proust • Studied the composition of compounds vs mixtures and noticed that: • Elements in a compound always present in fixed (definite) proportions • Elements in a mixture can be present in any proportions 12
Section 2. 3 Modern Atomic Theory and the Laws that Led to It The Law of Definite Proportions • For example he found that copper carbonate Cu(II)CO 3 is always 5. 3 parts copper to 4 parts oxygen to 1 part carbon. • Why doesn’t this match the formula? http: //www. timna. co. il/92847/Basic-Copper-Carbonate 13
Section 2. 3 Modern Atomic Theory and the Laws that Led to It The Law of Definite Proportions • All samples of a given compound, regardless of their source or how they were prepared, have the same proportion of their constituent elements. • Basically what he is saying is that water is always H 2 O never H 3 O or HO 2. • This seems obvious to us – but back in the early days of chemistry they were just figuring this stuff out. 14
Section 2. 3 Modern Atomic Theory and the Laws that Led to It The Law of Multiple Proportions • Proust’s discovery of the law of definite proportions got another scientist (John Dalton) to start thinking about atoms as the particles that might compose elements. • Dalton reasoned that if matter was composed of atoms then when those atoms combined into compounds they would combine as whole units • If A reacts with B to from more than one kind of compound then you will get combinations like this • AB, AB 2, AB 3, A 2 B, A 3 B etc • But remember they still don’t know formulas – all they can measure is masses of elements in compounds 15
Section 2. 3 Modern Atomic Theory and the Laws that Led to It The Law of Multiple Proportions • Lets say we have 1 g of carbon that we react with oxygen • We end up with two different compounds – One contains 2. 67 g of oxygen – One contains 1. 33 g of oxygen • Does not seem that helpful until you take the ratio of the oxygen 2. 67/1. 33 = 2 – One compound has twice as much oxygen as the other – Of course we know that the two compounds are CO 2 and CO. 16
Section 2. 3 Modern Atomic Theory and the Laws that Led to It The Law of Multiple Proportions • When two elements (call them A and B) form two different compounds, the masses of element B that combine with 1 g of element A can be expressed as a ratio of whole numbers. 17
Section 2. 3 Modern Atomic Theory and the Laws that Led to It Example • The following data were collected for several compounds of nitrogen and oxygen. How do these data illustrate the law of multiple proportions. Mass of Nitrogen That Combines with 1 g of Oxygen Compound A 1. 750 g Compound B 0. 8750 g Compound C 0. 4375 g 18
Section 2. 3 Modern Atomic Theory and the Laws that Led to It Example • For the law of multiple proportions to hold, the ratios of the masses of nitrogen combining with 1 gram of oxygen in each pair of compounds should be small whole numbers. Mass of Nitrogen That Combines with 1 g of Oxygen Compound A 1. 750 g Compound B 0. 8750 g Compound C 0. 4375 g A/B = 1. 750/0. 8750 = 2/1 B/C = 0. 8750/0. 4375 = 2/1 A/C = 1. 750/0. 4375 = 4/1 19
Section 2. 3 Modern Atomic Theory and the Laws that Led to It Definite vs Multiple Proportions • The Law of definite proportion states that in two or more samples of the same compound the ratio of one element to the other is always the same. Carbon dioxide always CO 2 and carbon monoxide always CO • The Law of multiple proportion states that carbon and oxygen can combine in more than one way (CO and CO 2). 20
Section 2. 3 Modern Atomic Theory and the Laws that Led to It John Dalton and the Atomic Theory • We have been talking about Laws – Descriptions of “What Happens” • John Dalton brought together the best thinking and ideas of lots of other scientists and published a theory (or model) – Attempt to explain “Why” 21
Section 2. 3 Modern Atomic Theory and the Laws that Led to It Dalton’s Atomic Theory 1. 2. 3. 4. Each element is made up of tiny indestructible particles called atoms. All atoms of a given element have the same mass and other properties that distinguish them from atoms of other elements Atoms combine in simple whole number ratios to form compounds. Atoms of one element cannot change into atoms of another element. In a chemical reaction, atoms only change the way that they are bound together with other atoms. 22
Section 2. 3 Modern Atomic Theory and the Laws that Led to It Concept Check • Other than the obvious fact that it is more detailed, what is the fundamental difference between the Modern Atomic theory of John Dalton and the one put forth by Democritus 2000 years before 23
Section 2. 3 Modern Atomic Theory and the Laws that Led to It Solution • Democritus’ theory was basically just speculation. It was not based on any observations or laws. • Daltons theory was based on observations of the natural world. 24
Section 2. 4 The Discovery of the Electron Scientists can’t leave well enough alone • • So now we have the Atomic Theory All matter is composed of atoms Atoms are indivisible So, of course, scientists immediately went about trying to figure out what atoms were made of 25
Section 2. 4 The Discovery of the Electron Cathode Rays • Electricity is the hot new tool in science • JJ Thomson • Ran a current of electricity between two electrodes at either end of a partially evacuated tube (cathode tube) • Noticed a beam of particles travelling from the cathode (negative electrode) to the anode (positive electrode) • He named them “cathode rays” 26
Section 2. 4 The Discovery of the Electron Cathode Rays Fig 2. 3 27
Section 2. 4 The Discovery of the Electron Cathode Rays • Stream of charged particles emitted from a electrically charged metal plate – Travel in a straight line – Independent of material used for cathode – Repelled by negative pole of applied electrical field 28
Section 2. 4 The Discovery of the Electron Cathode Rays • Thomson calculated the charge-to-mass ratio of the cathode ray particles by measuring the deflection of the beam in response to electric and magnetic fields e = the charge in coulombs m = mass in grams 29
Section 2. 4 The Discovery of the Electron The Electron • The value of the charge/mass ratio suggests that the cathode ray particles were very, very small • Thomson had discovered the electron • Negatively charged, low mass particle within all atoms. • So it turns out the atom is not indivisible after all 30
Section 2. 4 The Discovery of the Electron The Electron • Atom is not indivisible • This opened up the field of “subatomic structure” • Also asked new questions – What are the characteristics of this new “subatomic” particle? – What is the structure of the atom itself? • Lets look at how they tried to figure these out 31
Section 2. 4 The Discovery of the Electron Millikan’s Oil Droplet Experiment and the Charge of Electrons • How did he figure out the charge of an electron with oil drops? • Pretty clever actually • Used electricity • Also used the new tool – Radioactivity 32
Section 2. 4 The Discovery of the Electron Millikan’s Oil Droplet Experiment and the Charge of Electrons • Fine mist of oil droplets • Fall thru tiny pinhole • “Charge them up” with electrons using Ionizing Radiation* • Look at drops through a microscope * Radioactivity 33
Section 2. 4 The Discovery of the Electron Millikan’s Oil Droplet Experiment and the Charge of Electrons • Suspend the fall of the droplets by adjusting the voltage across two plates. • The value of the voltage and the mass of the oil drop can then be used to calculate the charge on the oil drop. 34
Section 2. 4 The Discovery of the Electron Millikan’s Oil Droplet Experiment and the Charge of Electrons • This experiment showed that the charge on an oil drop is always a whole number multiple of 1. 60217646 × 10 – 19 coulombs • This is the charge on a single electron 35
Section 2. 4 The Discovery of the Electron Millikan’s Oil Droplet Experiment and the Charge of Electrons • Determined the magnitude of the charge on a single electron. • Why does this matter? • 2 reasons – 1. Now that we are dividing atoms up into subatomic particles it is helpful and informative to know the characteristics of these particles. – 2. We can use the charge of the electron to determine its mass. 36
Section 2. 4 The Discovery of the Electron Millikan’s Oil Droplet Experiment and the Charge of Electrons • Using the charge of an electron to determine the mass. • Well we already have the charge/mass ratio. – Thomson figured this out with the Cathode rays • So if we figure out the charge then we can calculate the mass of a subatomic particle. 37
Section 2. 4 The Discovery of the Electron Millikan’s Oil Droplet Experiment and the Charge of Electrons • Since he knew the ratio of charge to mass he was able use the charge of an electron to determine its mass. • Mass of the electron is 9. 10 x 10 – 28 g 38
Section 2. 5 The Structure of the Atom Models of the Structure of the Atom • JJ Thomson reasoned that if atoms contain negative particles then they must also contain positive charge of some type that balances out negative charge because most atoms are neutral. • The question he wanted to answer was how are these positive and negative charges arranged. What is the internal structure of the atom? 39
Section 2. 5 The Structure of the Atom JJ Thomson (Plum Pudding Model) • Reasoned that the atom might be thought of as a uniform “pudding” of positive charge with enough negative electrons scattered within to counterbalance that positive charge. 40
Section 2. 5 The Structure of the Atom Ernest Rutherford (1911) • • Graduate student of J. J. Thompson Father of nuclear physics Wanted to test the plum pudding model of atomic structure New “big thing” in science is radioactivity 41
Section 2. 5 The Structure of the Atom Radioactivity • • • Henri Becquerel Piece of uranium produced an image on a photographic plate Attributed this phenomenon to spontaneous emission of radiation by uranium – Named it radioactivity – Studies in the early 20 th century demonstrated three types of radioactivity • Gamma (g) rays – high energy light • Beta (b) particles – high speed electron • Alpha (a) particles – basically a He nucleus (2+) charge 42
Section 2. 5 The Structure of the Atom Gold Foil Experiment • Ernest Rutherford – Shoot large, positive particles (a particles) • Product of radioactive decay – At a thin gold foil – Observe how particles are deflected 43
Section 2. 5 The Structure of the Atom Fig 2. 6 Source = Piece of uranium Fig. 4 -5, p. 84 44
Section 2. 5 The Structure of the Atom Gold Foil Experiment • • If Plum pudding model correct most a particles would fly right through barely deflected Not what they saw − − • Most particles went right through A few bounced off at weird angles – like they were hitting something “Almost as if you had fired a 15 inch shell at a piece of tissue paper and it came back and hit you” 45
Section 2. 5 The Structure of the Atom Gold Foil Experiment • • • How to explain these results To explain the fact that the a particles were deflected Rutherford reasoned that most of the mass of the atom must be concentrated in a relatively small area In contrast with the plum pudding model which depicts matter as fairly uniform he suggested that instead matter consists of large regions of empty space dotted with small regions of dense matter 46
Section 2. 5 The Structure of the Atom Fig. 4 -6, p. 84 47
Section 2. 5 The Structure of the Atom Nuclear Theory of the Atom 1. Most of the atom’s mass and all of its positive charge are contained in a small core called the nucleus. 2. Most of the volume of the atom is empty space, throughout which tiny, negatively charged particles are dispersed. 3. There as many negatively charged particles outside the nucleus as there are positively charged particles (named protons) within the nucleus, so the atom is electrically neutral. 48
Section 2. 5 The Structure of the Atom Discovery of the Neutron • • OK so we have a model of the atom. But we still have some problems Hydrogen atom has 1 proton and Helium atom has 2 yet Helium weighs 4 times as much as Hydrogen Rutherford and his student (Chadwick) went to work on this one 49
Section 2. 5 The Structure of the Atom Discovery of the Neutron • • • Turns out most nuclei also contain a neutral particle called the neutron. A neutron is similar in mass to a proton but has no charge. Hydrogen has no neutrons and Helium has 2 Hydrogen – 1 proton 0 neutrons Helium – 2 protons 2 neutrons 50
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Subatomic Particles • The atom contains: • Protons – found in the nucleus; positive charge equal in magnitude to the electron’s negative charge. • Neutrons – found in the nucleus; no charge; virtually same mass as a proton. • Electrons – found outside the nucleus; negatively charged. 51
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Nuclear Atom Viewed in Cross Section • The nucleus is: • Extremely Small compared with the overall size of the atom. − Pea at the center of Qwest field • Extremely dense; accounts for almost all of the atom’s mass. 52
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms • The atom contains: What do you need to know from this table Relative charges +1, 0, – 1 Relative masses protons and neutrons appx 1 amu and electrons appx 1/2000 amu 54
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Elements: Defined by Their Number of Protons • If all atoms are composed of the same subatomic particles then how can atoms can be different from each other. • What makes a carbon atom as distinct from a sodium atom or a copper atom • The number of particles • More specifically, the number of protons. 55
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Elements: Defined by Their Number of Protons • The number of protons in an atom is called the atomic number – Carbon has 6 protons – atomic number = 6 – Sodium has 11 protons – atomic number = 11 – Copper has 29 protons – atomic number = 29 • Identity of an element arises from number of protons. 56
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Elements: Defined by Their Number of Protons • So far 116 elements have been discovered or synthesized 57
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Elements: Defined by Their Number of Protons • Each element has – Unique atomic number – Unique chemical symbol • Some of these are based on the English names – H for Hydrogen He for Helium • Others are based on the Latin names – Na for sodium (from the Latin natrium) – atomic number 11 – Sn for tin (from the Latin stannum) – atomic number 50 58
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Isotopes: When the Number of Neutrons Varies • Turns out all atoms are not exactly the same • Isotopes are atoms with the same number of protons but different numbers of neutrons 59
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Isotopes: When the Number of Neutrons Varies • • 2 isotopes of sodium. Both have 11 protons One has 12 neutrons Other has 13 Show almost identical chemical properties In nature most elements contain mixtures of isotopes. Where do isotopes come from? How are they formed? 60
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Isotopic Notation • • To specify isotopes we use symbolic notation X = the symbol of the element Z = the atomic number (# of protons) A = the mass number (# of protons and neutrons) 61
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Isotopes – An Example • • • C = the symbol for carbon 6 = the atomic number (6 protons) 14 = the mass number (6 protons and 8 neutrons) • C = the symbol for carbon • 6 = the atomic number (6 protons) • 12 = the mass number (6 protons and 6 neutrons) 62
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Concept Check Write the symbolic notation for these two isotopes of sodium. 63
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Solution Write the symbolic notation for these two isotopes of sodium. 64
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Learning Check A certain isotope X contains 54 electrons and 78 neutrons. • What is the mass number of this isotope? 65
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Solution A certain isotope X contains 54 electrons and 78 neutrons. • What is the mass number of this isotope? 132 66
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Ions: Losing and Gaining Electrons • In a neutral atoms the number of protons is equal to the number of electrons – Negative charge = positive charge 67
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Concept Check • How many protons and electrons in a neutral atom of • Lithium (Li) • Bromine (Br) 68
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Solution • How many protons and electrons in a neutral atom of • Lithium (Li) 3 protons and 3 electrons • Bromine (Br) 35 protons and 35 electrons 69
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Ions: Losing and Gaining Electrons • During chemical changes atoms can gain or lose electrons to become ions (charged atom) • Metals tend to lose electrons to become positively charged cations – Li Li+ + 1 e – • Nonmetals tend to gain electrons to become negatively charged anions – Br + 1 e – Br – 70
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Concept Check • How many protons and electrons in the lithium and bromine ions • Lithium cation (Li+) • Bromine anion (Br –) 71
Section 2. 6 Subatomic Particles: Protons, Neutrons and Electrons in Atoms Solution • How many protons and electrons in the lithium and bromine ions • Lithium cation (Li+) 3 protons and 2 electrons • Bromine anion (Br –) 35 protons and 36 electrons 72
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table The Periodic Table 73
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Mendeleev • Elements were discovered and purified one at a time • Late 1800 s scientists started to group chemicals together that all behaved the same way • 1872, Dmitri Mendeleev arranged the 60 know elements into groups with similar properties and arranged them in order of increasing atomic mass 74
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table from Mendeleev’s 1869 paper http: //www. aip. org/history/curie/periodic. htm 75
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Superimpose on Modern Periodic Table http: //www. msnucleus. org/membership/html/jh/physical/periodictable/lesson 5/periodic 5 b. html 76
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Predictive Power of Mendeleev’s Table • There are bunch of gaps in Mendeleev’s first version of the periodic table • This is because lots of elements had not been discovered or characterized yet. • His table was revolutionary and ingenious because it actually predicted the properties of elements that had not been discovered yet! 77
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table The Periodic Law • When the elements are arranged in order of increasing mass, certain sets of properties recur periodically Fig. 2. 10 78
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Periodic Law and Quantum Mechanical Theory • The Periodic Law was something that was observed – Properties of elements repeat in a periodic way – It is a law because it describes what happens but does not attempt to explain why • About 50 years later the Theory of quantum mechanics was presented that explains why the periodic behavior exists. (Ch 7 and 8) 79
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Representative Elements 1 A – 8 A Transition Elements 1 B – 8 B Second numbering system 1 – 18 We will use the 1 – 8 A and B You should learn the names and symbols of the elements in Periods 1 – 4. 80
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Groups and Periods On the periodic table, • elements are arranged according to similar properties • groups contain elements with similar properties in vertical columns • periods are horizontal rows of elements 81
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Groups and Periods 82
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Classification of Groups 83
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Groups with Specific Names • Alkali Metals (1 A) – Very reactive metals, explode in water, very soft • Alkaline Earth Metals (2 A) – Less reactive than alkali metals, less soft, found in higher concentrations in rocks and soil • Halogens (7 A) – Reactive nonmetals, most are gases at room temperature • Noble Gases (8 A) – Non reactive gases 84
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Metals, Nonmetals, and Metalloids • The heavy zigzag line separates metals and nonmetals. • Metals are located to the left. • Nonmetals are located to the right. * • Metalloids are located along the heavy zigzag line between the metals and nonmetals. − Aluminum and Polonium are exceptions • * notice there is one lonely nonmetal on the left side of the table 85
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Metals, Nonmetals, and Metalloids 86
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Properties of Metals, Nonmetals, and Metalloids Metals (most elements) • Are shiny and ductile (can be pulled into wires) and malleable (can be hammered into sheets) • Are good conductors of heat and electricity • Most are solid at room temperature. Which isn’t? Nonmetals • Are dull, brittle, and poor conductors • Are good insulators • Solids, liquids or gases and room temperature Metalloids • Are better conductors than nonmetals, but not as good as metals • Are used as semiconductors and insulators 87
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Learning Check List all of the elements that match the description A. Metals in Group 4 A Sn, Pb, C, Si, Ge B. Nonmetals in Group 5 A As, Sb, Bi, N, P C. Metalloids in Group 4 A C, Si, Ge, Sn, Pb 88
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Solution List all of the elements that match the description A. Metals in Group 4 A Sn, Pb B. Nonmetals in Group 5 A N, P C. Metalloids in Group 4 A Si, Ge 89
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table 7 Elements Exist as Diatomic Molecules in their Elemental Forms 90
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Allotropes • • Different forms of a given element. Example: Solid carbon occurs in three forms. • Diamond • Graphite • Buckminsterfullerene 91
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Ions and The Periodic Table • Metals tend to lose electrons in chemical reaction – Li Li+ + 1 e – Lithium cation • Nonmetals tend to gain electrons in chemical reactions – Br + 1 e – Br – Bromine anion • In both of these examples only one electron is gained or lost but this is not always the case, sometimes 2 or even 3 92
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table How to Predict the Charges of Ions • Groups 1, 2 and 3 lose 1, 2 and 3 – Metals lose electrons • Groups 5 – 7 gain 8 minus (group number) – Nonmetals gain electrons 93
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Learning Check Predict the charges of ions formed by the following: A. Sr B. Se C. Cs 94
Section 2. 7 Finding Patterns: The Periodic Law and the Periodic Table Solution Predict the charges of ions formed by the following: A. Sr 2+ Sr is in group 2 – loses 2 electrons B. Se 2 – Se is in group 6 – gains 2 electrons C. Cs + Cs is in group 1 – loses 1 electron 95
Section 2. 8 Atomic Mass: The Average Mass of an Elements Atomic Mass • Dalton thought that all atoms of the same element had exactly the same mass – – • • Not strictly true Isotopes have slightly different masses We can calculate an average mass of the atoms of an element This is called the Atomic Mass – Average mass of the isotopes of an element weighted according to their abundance. 96
Section 2. 8 Atomic Mass: The Average Mass of an Elements Atomic Mass for Carbon • • When we look at the periodic table, the atomic mass for carbon is not 12. It is 12. 01. That is because carbon naturally exists as a mixture of isotopes. The mass of carbon is an average of the masses of the different isotopes. 12 C, 13 C and 14 C – – All have 6 protons – that is what makes them carbon Have 6, 7 and 8 neutrons – that is what makes them isotopes 97
Section 2. 8 Atomic Mass: The Average Mass of an Elements Atomic Mass for Carbon • 98. 89% of 12 C and 1. 11% of 13 C – (14 C is negligible) • 98. 89% of 12 amu + 1. 11% of 13. 0034 amu = • (0. 9889)(12 amu) + (0. 0111)(13. 0034 amu) = • 12. 01 amu 98
Section 2. 8 Atomic Mass: The Average Mass of an Elements Atoms Learning Check An element consists of 62. 60% of an isotope with mass 186. 956 amu and 37. 40% of an isotope with mass 184. 953 amu. • Calculate the average atomic mass and identify the element. 99
Section 2. 8 Atomic Mass: The Average Mass of an Elements Atoms Solution An element consists of 62. 60% of an isotope with mass 186. 956 amu and 37. 40% of an isotope with mass 184. 953 amu. • Calculate the average atomic mass and identify the element. • (0. 6260)(186. 956 amu) + (0. 3740)(184. 953 amu) = 186. 2 amu Rhenium (Re) 100
Section 2. 8 Atomic Mass: The Average Mass of an Elements Atomic Mass Unit • • • It doesn’t make sense to refer to the mass of an atom in grams – atoms are really small So chemists defined the Atomic Mass Unit Originally corresponded the mass of 1 H – • • Makes sense – smallest atom Then for a while is was 1/16 the atomic weight of a single atom of oxygen Both of these roughly corresponded to a nucleon (particle that makes up the nucleus) – Either a proton of neutron 101
Section 2. 8 Atomic Mass: The Average Mass of an Elements Atomic Mass Unit • • Current definition of an atomic mass unit One atom of 12 C is assigned the mass of exactly 12 atomic mass units So 1 amu = 1/12 the mass of an atom of 12 C Masses of all other atoms are assigned relative to this standard. 102
Section 2. 8 Atomic Mass: The Average Mass of an Elements Atoms Average Atomic Mass for Carbon • • Even though natural carbon does not contain a single atom with mass 12. 01, for stoichiometric purposes, we can consider carbon to be composed of only one type of atom with an average mass of 12. 01. This enables us to count atoms of natural carbon by weighing a sample of carbon. 103
Section 2. 8 Atomic Mass: The Average Mass of an Elements Atoms Mass Spectrometry • • • So 1 amu = 1/12 the mass of an atom of 12 C Masses of all other atoms are assigned relative to this standard. Most accurate method to determine atomic mass is mass spectrometry. 104
Section 2. 8 Atomic Mass: The Average Mass of an Elements Atoms Mass Spectrometry 1) 2) 3) 4) Vaporize sample Ionize sample – create positive ions Electric field accelerates particles Ions are deflected in magnetic field 105
Section 2. 8 Atomic Mass: The Average Mass of an Elements Atoms Mass Spectrometry • How does deflection of ions help us determine atomic mass? – Large ions deflected the least and small ions deflected the most – Amount of defection is an indication of relative size – To get a measure of absolute size the samples are always compared to a standard that is mixed into the sample http: //www. rug. nl/research/isotope-research/projects/radiocarbonams? lang=en 106
Section 2. 8 Atomic Mass: The Average Mass of an Elements Atoms Mass Spectrometry • • When 12 C and 13 C are analyzed 13 C is deflected slightly less (more massive) The degree of deflection of ions if translated into a ratio of masses 107
Section 2. 8 Atomic Mass: The Average Mass of an Elements Atoms Mass Spectrometry How does deflection of ions help us determine the abundance of two isotopes? 1. Fig 2. 17 The position of each peak indicates the atomic mass The intensity of the peak indicates the relative abundance of the two isotopes 2. • Each peak is a percentage of the total intensity 108
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Counting by Weighing • • When we count by weighing we use the average mass of an individual object in a sample The average mass of the object allows us to behave as though they were all identical. 109
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them • Example: What is the mass of 1000 jelly beans? 1. Not all jelly beans have the same mass. 2. Suppose we weigh 10 jelly beans and find: Bean 1 2 3 4 5 6 7 8 9 10 Mass 5. 1 g 5. 2 g 5. 0 g 4. 8 g 4. 9 g 5. 0 g 5. 1 g 4. 9 g 5. 0 g 3. Now we can find the average mass of a bean. 4. Finally we can multiply to find the mass of 1000 beans! 110
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Exercise A pile of marbles weigh 394. 80 g. 10 marbles weigh 37. 60 g. How many marbles are in the pile? 111
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Solution A pile of marbles weigh 394. 80 g. 10 marbles weigh 37. 60 g. How many marbles are in the pile? 394. 80 g/ 3. 76 g/marble = 105 marbles 112
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Masses of Atoms • • • Elements occur in nature as mixtures of isotopes. Carbon = 98. 89% 12 C 1. 11% 13 C < 0. 01% 14 C A single atom of carbon does not have uniform mass When we count atoms by weighing we use an average mass What unit is used for the masses of atoms? 113
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Average Mass of an Atom • So, in order to count things by weighing them we need an average mass of an individual unit • For the atom we already have that • The Atomic Mass – Weighted average of the mass of the isotopes of the atom • The Atomic Mass is expressed in amu – atomic mass units – Atomic mass of carbon is 12. 01 amu – Atomic mass of helium is 4. 003 amu – Atomic mass of sodium is 22. 99 amu 114
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them The Mole: A Chemist’s Dozen • Samples of matter contain enormous numbers of atoms • So just like we needed a special unit for the mass of an atom (amu), we need a unit for a collection of atoms 115
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them The Mole: A Chemist’s Dozen • Can’t use a dozen or a hundred • The unit we use is the Mole • The number of carbon atoms in exactly 12 grams of 12 C • This number was determined to be 6. 022 x 1023 C atoms (Again from mass spectrometry) • Avogadro’s number – After the first scientist who estimated it 116
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them The Mole: A Chemist’s Dozen • This definition has two parts • The mole is both a number of particles and a mass • A mole is the number of carbon atoms in exactly 12 grams of 12 C – 6. 022 x 1023 12 C atoms – 12 g of 12 C 117
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them The Mole: A Chemist’s Dozen • So A mole is both a Number of particles and a Mass • • Mole is a Number of particles A mole is a unit just like a dozen 1 dozen = 12 of something 1 mole = 6. 022 x 1023 particles • • • Mole is also a Mass A dozen eggs has a mass ~ a pound or so Mass of a mole in grams = to atomic weight in amu * * See the Proof called “The Mole” on the website 118
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them The Mole: A Chemist’s Dozen • This means that a mole of any element has a mass in grams that is equal to its atomic weight in amu. • Carbon 12. 01 amu/atom 12. 01 g/mole 6. 022 x 1023 C atoms • Helium 4. 003 amu/atom 4. 003 g/mole 6. 022 x 1023 C atoms • Sodium 22. 99 amu/atom 22. 99 g/mole 6. 022 x 1023 C atoms 119
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Problem Solving • So out of all these numbers and equations there are only two things you need to remember in order to solve problems • 6. 022 x 1023 particles/mole Avogadro’s number • Grams/mole = amu/atom From periodic table 120
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them One-Mole Quantities 121
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Converting between number of Moles and Number of Atoms • How many atoms in 2. 50 moles of carbon? • How many moles in 5. 25 x 1025 atoms of Helium? 122
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Learning Check • How many atoms in 7. 50 moles of argon? • How many moles in 7. 35 x 1026 atoms of sodium? 123
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Solution • How many atoms in 7. 50 moles of Argon? • How many moles in 7. 35 x 1026 atoms of sodium? 124
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Converting between Mass and Amount (Number of Moles) • What is the mass (in grams) of 0. 535 moles of copper? • How many moles are in 1. 22 g of potassium? 125
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Learning Check • What is the mass (in grams) of 2. 88 moles of iron? • How many moles are in 25 g of calcium? 126
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Solution • What is the mass (in grams) of 2. 88 moles of iron? • How many moles are in 25 g of calcium? 127
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Converting between Mass and Number of Atoms • How many gold atoms are in in a solid gold ring that weighs 25. 0 g • What is the mass of a sample of 2. 5 x 1027 silicon atoms 128
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Learning Check • Determine both the number of moles and the number of atoms in 25. 0 g of calcium. 129
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Solution • Determine both the number of moles and the number of atoms in 25. 0 g of calcium. 130
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Learning Check • Determine the number of atoms in 5. 50 mg of lead 131
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Solution • Determine the number of atoms in 5. 50 mg of lead 132
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Learning Check • Determine the number of moles and the mass of 1. 00 x 1022 atoms of silicon. 133
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Solution • Determine the number of moles and the mass of 1. 00 x 1022 atoms of silicon. 134
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Conceptual Connection • Why is Avogadro’s number defined as 6. 022 x 1023? Why is it such a strange number? Why not a nice round number like 1. 00 x 1023? 135
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Solution • The definition of Avogadro’s number is tied to the definition of the amu. • Avogadro's number is the number of atoms is 12 g of carbon-12 • An amu is the mass of 1/12 of an atom of carbon-12 • Linking these two definitions makes for the relationship that the mass in g of 1 mol of any element is equal to its atomic mass in amu. • Allows us to weigh out numbers of particles • Count by weighing. 136
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Conceptual Connection • Without doing any calculations determine which sample contains the most atoms • A. 1 g of calcium 40. 08 amu • B. 1 g of nitrogen 14. 01 amu • C. 1 g of gold 196. 97 amu 137
Section 2. 9 Molar Mass: Counting Atoms by Weighing Them Solution • Without doing any calculations determine which sample contains the most atoms • A. 1 g of calcium 40. 08 amu so 40. 08 g in a mole • B. 1 g of nitrogen 14. 01 amu so 14. 01 g in a mole • C. 1 g of gold 196. 97 amu so 196. 97 g in a mole • So the nitrogen sample is ~ 1/14 of a mole and the calcium is ~ 1/40 th and the gold ~ 1/200 th. • The nitrogen has the most atoms. 138
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