Two experimentally determined facts have achieved the status of scientific laws: The Law of Conservation of Mass: Mass is neither created or destroyed in a chemical reaction. The total mass of all of the reacting substances is the same as the total mass of all of the products. The Law of Constant Composition: The elements present in a compound are present in fixed and exact proportion by mass, irregardless of the compound’s source or method of preparation.

The percent composition of a compound represents the mass percent that each element present contributes to the total mass. The percent composition of a compound is the same irregardless of the size of the sample analyzed. For a compound containing only carbon (C), hydrogen (H), and oxygen (O), the percent composition would be calculated: Mass % C = (mass of carbon in sample) / mass of sample * 100% Mass % H = (mass of hydrogen in sample) / mass of sample * 100% Mass % O = (mass of oxygen in sample) / mass of sample * 100% It should be obvious that: Mass C + Mass H + Mass O = mass sample Mass % C + Mass % H + Mass % O = 100%

His theory contained five major ideas: John Dalton was an English scientist who lived from 1766–1844. Dalton developed a theory known as the atomic theory to explain the chemical behavior of matter. His theory contained five major ideas: All matter is composed of infinitesimally small particles called atoms The atoms of any one element are identical Atoms of different elements have different masses Compounds are combinations of atoms of different elements and possess properties different from their component elements In chemical reactions, atoms are exchanged between starting compounds to form new compounds. Atoms are neither created nor destroyed.

Daltons ideas about chemical reactions correspond to the following illustration: The shapes (atoms) have simply been rearranged.

Because atoms are so small their masses cannot be directly determined by ordinary means. Dalton recognized this and proposed a relative mass scale. The mass of a hydrogen atom was assigned a relative mass of 1.0. He assumed that binary chemical compounds consisted of a 1:1 ratio of the two atoms involved. By decomposing a compound into its elements and weighing them he could then assign a relative mass to other elements.

Hydrogen chloride can be determined to be 97.24% Cl and 2.76% H. In 100 grams of HCl there are 97.24 g of Cl and 2.76 g of H. We don’t know how many H and Cl atoms there are, but we assume that there are equal numbers of each, N. (Mass of N H-atoms) / (Mass of N Cl-atoms) = 2.76 / 97.24 (Mass of 1 H-atom) / (Mass of 1 Cl-atom) = 2.76 / 97.24 (Mass of 1 H-atom) / (Mass of 1 Cl-atom) = 1 / 35.23 Therefore if the mass of 1 H atom is 1 mass unit, the mass of 1 Cl atom must be 35.23 mass units.

This process can be repeated with compounds containing an element of unknown atomic mass and an already known element, and eventually the relative masses of all of the elements can be determined. The obvious problem for Dalton was that most chemical compounds do not contain equal numbers of atoms of their constituent elements (ie. H2O). Daltons original table of relative weights gave a value of about 8 for oxygen rather than the correct value of 16.

The relative masses of atoms are called the atomic masses of the elements, and are often referred to as atomic weights. The current periodic table defines the relative atomic masses to that of a form of carbon atoms whose mass is defined to be exactly 12 atomic mass units or amu (the SI symbol is u).

Atoms consist of three types of particles, protons, neutrons, and electrons. Protons and neutrons make up most of the mass of the atom and are located in a small volume at the center of the atom called the nucleus.

Each proton in the nucleus is positively charged. The negatively charged electrons are spread out around the nucleus and take up most of the volume of the atom. In a neutral atom there are equal numbers of protons and electrons. The number of protons in the nucleus of an atom is called its atomic number. An atom of an element may gain or loose electrons to become electrically charged, but never gains or looses protons in the nucleus. In determining the mass of an atom, the masses of the electrons around the nucleus are usually ignored because they are so small compared to the masses of the protons and neutrons.

All atoms of a given element have the same number of protons in their nuclei, but may have different numbers of neutrons. Atoms of an element containing different numbers of neutrons are called isotopes of each other. Many of these isotopes are radioactive and are used in medicine and in scientific research.

The symbol for an isotope is usually written as the symbol for the element with its atomic number (number of protons) as a subscript at the lower left and the sum of the numbers of its protons and neutrons as a superscript at the upper left. 146C, 136C, 11H, 21H, 31H, etc. An alternate notation is to follow the name of the element with the atomic mass number of the isotope: Carbon-12, carbon 13, etc.

Two scientists, Dmitri Mendeleev in Russia, and Lothar Meyer in Germany independently studied the properties of the elements as a function of increasing mass. They determined that the elemental properties did not change smoothly and continuously with atomic mass, but instead repeated periodically. This variation is now known as the Periodic Law. The Periodic Law is embodied in the periodic table.

The elements are arranged in the periodic table so that those with similar chemical properties are arranged in the same vertical column, called a group or a family. Each horizontal row is called a period.

Elements in group VII are called the noble gases Elements in group VII are called the noble gases. They are very unreactive and do not form chemical compounds as most of the other elements do.

The elements in group I are called the alkali metals. Metals are shiny, malleable, can be melted and cast into shapes, and are excellent conductors of heat and electricity. Metals tend to lose electrons to form cations when the react chemically.

Alkali metals react violently with water to form basic solutions.

The elements in group II are called the alkaline earth metals.

The elements in group VII are called the halogens and are nonmetals. Nonmetals cannot be cast into shapes and do not conduct electricity. Nonmetals tend to gain electrons to form anions when they chemically react.

The halogens, chlorine, bromine, and iodine:

The elements between groups II and III are called the transition elements. Many of these elements form cations of more than a single electrical charge: Fe+2 and Fe+3, Cu+1 and Cu+2, etc.

Many heavier elements are not shown in the abbreviated periodic table above. Among these are the inner transition elements: 57-70 are the lanthanides, and 89-102 are the actinides.

Most elements are metals and are located to the left in the periodic table. Nonmetals are located to the upper right in the periodic table. Metalloids or semimetals are found between the metals and nonmetals in the periodic table and have have properties between the two.

White light, as from the sun or an incandescent bulb, can be separated into its component colors, or visible spectrum, by means of a prism.

Atomic Spectra When light is created from excited, or energized, atoms in a flame, a series of sharply defined, separated lines of different colors appears in the visible spectrum, rather than a continuous rainbow of colors. K Na Rb

When passed through an instrument called a spectrometer, the lines of color can be recorded on a photographic plate as an atomic emission spectrum. H He

A second kind of spectrum can be recorded and measured by passing white light through the atoms of a specific element. What would have been brightly colored lines on a black background become the corresponding missing colors, or dark lines, on a brightly colored rainbow. This type of spectrum is called an absorption spectrum and can be measured using an instrument called an atomic absorption spectrometer.

Electromagnetic Radiation and Energy Radiation describes the transfer of energy from one point in space to another. Heat and visible light are only small parts of the full spectrum of electromagnetic radiation, which has its origin in the oscillation, or vibration, of charged particles. Electromagnetic radiation is usually described by its frequency, or by how many times per second a vibration is completed.

Atomic Energy States The basis of the line structure of atomic emission spectra was discovered by Niels Bohr, a Danish scientist. Albert Einstein had discovered that a beam of light consisted of many small packages of energy called photons. Bohr surmised that the electrons in atoms could exist in certain discrete energy states. Moving between these energy states would only be possible by the absorption or emission of a photon of light containing the same energy as the difference between the two states. The lowest energy state in an atom is called its ground state. An atom in its ground state cannot emit a photon of light but can absorb a photon of light of the correct energy to reach one of many different excited states. Once in an excited state, an atom can emit a photon of light to return to the ground state.

The first model of the atom resembled the solar system with the positive nucleus attracting an orbiting electron. This model, the Bohr model, although it accounted for the spectrum of hydrogen, was proved to be incorrect. A new theory called quantum mechanics is now believed to correctly account for the electronic structure of the atom.

Quantum mechanics is the modern theory that describes the properties of atoms, molecules, and subatomic particles. Quantum mechanics provides a set of rules that describe the way in which electrons are organized within an atom. We will examine the periodicity of the chemical properties of the elements by describing the electronic arrangement of the hydrogen atom and then by moving one atom at a time through the periodic table.

Electrons are organized within an atom into shells, subshells, and orbitals. The relationship between these levels of organization depends upon the energy state of the atom, which in turn depends upon a quantity called the principle quantum number. Shell: Identified by a principal quantum number (1, 2, 3 . . . n) that specifies the energy level, or energy state, of the shell. The higher the quantum number, the greater the energy and the farther the shell electrons are from the nucleus. Subshells: Locations within a shell, identified by the lowercase letters s, p, d, and f. Orbital: The region of space within a subshell that has the highest probability of containing an electron.

The region of space in which an electron is most likely to be found is called an atomic orbital which is best viewed as a cloud surrounding the nucleus. The size and shape of an orbital depend upon the atom’ energy state: the greater the energy, the larger and more complex the orbitals.

Each type of orbital, s, p, d, f, …, retains its shape as the principle quantum number increases, but increases in volume. The sizes and shapes of the atomic orbitals are responsible for the properties of molecules constructed from the atoms (bond length, bond angles, etc.)

Combining these two tables the orbitals for the first 3 principle quantum numbers are: 2s 2p1 2p2 2p3 3s 3p1 3p2 3p3 3d1 3d2 3d3 3d4 3d5

An orbital is a “state” or location in which electrons can exist in an atom. Only two electrons can occupy any one orbital on the same atom. In order for this to happen the two electrons must have opposite “spins”. When two electrons have opposite spins, they are said to be spin-paired. The concept of electron spin results from the fact that they behave like a spinning top which can rotate either in a clockwise or anticlockwise direction. Since each orbital can hold only two electrons, it is now possible to calculate how many electrons can be held by each subshell:

The rules for constructing a picture of the arrangement of the electrons about an atom are called the Aufbau rules. Using these rules we describe the atomic structure of hydrogen and then systematically describe the atomic structure of each successive atom by adding one proton and one electron to picture for the previous atom.

Once a particular orbital is filled, the next electron must be placed in an empty orbital of next highest energy. No intermediate energy levels are allowed. This property means that the energies of the electrons in an atom are quantized.

This configurations could also be written: The electronic configurations of the first four elements illustrate the Aufbau process: This configurations could also be written: H 1s1 He 1s2 Li 1s22s1 Be 1s22s2

As p orbitals are filled, Hund’s rule must be applied, as illustrated for carbon and oxygen: These configurations can be written: C 1s22s22p2 O 1s22s22p4 Note that the three p orbitals may be written in this notation using a single letter p with a superscript from 1 to 6.

The electronic configuration of the larger elements can become very unwieldy to write. We can think of the electronic configuration of an element as that of the preceding inert gas plus any additional electrons left over. Li: 1s22s1 becomes [He]2s1; Mg: 1s22s22p63s2 becomes [Ne]3s2.

Notice that the outer electronic configuration (in blue) is the same for each column of elements, except for the principle quantum number. This is the reason that the elements in each of the columns shown have similar chemical properties.

The electronic configuration of a carbon atom which contains 6 electrons can be written: 1s2 2s2 2px1 2py1 According to Hund’s rule, each of the three p orbitals, px, py, and pz must contain one electron (each with the same spin) before any of the p orbitals can be filled.

When an alkali metal atom (sodium) reacts with a halogen atom (Cl) an electron is transferred from the sodium atom to the chlorine atom. The sodium atom becomes a positively charged cation, and the chlorine atom a negatively charged anion.

Examining the electronic configurations of Na+ and Cl-, it can be seen that each is identical to that of an inert gas: Na+ to Ne and Cl- to Ar. The simple chemistry of the metals and nonmetals is dominated by this idea which is called the Octet Rule. Each inert gas contains the electronic configuration: ns2np6, where n is the principle quantum number. The chemistry of the elements depends only upon the electrons in the outermost shell called the valence shell. These electrons are called the valence electrons.

These representations are called Lewis symbols. Individual atoms are often represented by their chemical symbol, surrounded by dots representing the valence electrons for that atom. These representations are called Lewis symbols. With the exception of helium, the number of valence electrons for an element is the same as its group number. The reaction between an alkali metal and a halogen can also be written using Lewis symbols. Note that whenever an electron is lost by one atom, it is always gained by a second atom.

Dalton’s Atomic Theory Chapter 2 Summary Dalton’s Atomic Theory • All matter consists of particles called atoms, which are indestructible. • The atoms of any one element are chemically identical. • Atoms of different elements are distinguished from one another because they have different masses. • Compounds consist of combinations of atoms of different elements. In chemical reactions, atoms trade partners to form new compounds. • The theory explained (1) the conservation of mass in chemical reactions and (2) the constant composition of matter.

Chapter 2 Summary Atomic Masses • The relative mass of an element is called its atomic mass. • Atomic masses are calculated in relation to the mass of the most common form of the element carbon, exactly 12 atomic mass units (amu).

Chapter 2 Summary The Structure of Atoms • Atoms contain three kinds of particles: protons, electrons, and neutrons. • The protons and neutrons are located together in the nucleus • In an electrically neutral atom, the number of protons is balanced by exactly the same number of electrons. • An atom bearing a net electrical charge is called an ion. A cation is a positively charged ion, and an anion is a negatively charged ion.

Chapter 2 Summary Isotopes • Naturally occurring elements consist of isotopes. • Isotopes of a given element have the same atomic number but have different numbers of neutrons. • An isotope’s mass number is the sum of the numbers of protons and neutrons in its nucleus.

Chapter 2 Summary The Periodic Table • The properties of the elements repeat periodically if the elements are arranged in order of increasing atomic number. • In the periodic table, elements of similar chemical properties are aligned in vertical columns called groups. • Horizontal arrangements, called periods, end on the right with a noble gas. • Each of the second and third periods contains eight elements. But the fourth period includes a new group of ten transition elements. • Elements are designated as either main-group or transition elements. • The metals occupy most of the left-hand side of the periodic table, and the nonmetals occupy the extreme right-hand side of the table. • Elements called metalloids, or semimetals, have properties between those of metals and nonmetals and lie between the two larger classes.

Electron Organization Within the Atom Chapter 2 Summary Electron Organization Within the Atom • Electrons in atoms are confined to a series of shells around the nucleus. • The farther away the electrons are from the nucleus, the greater their energy. • Electron energy states are characterized by an integer called the principal quantum number. • Electrons are contained in shells that consist of subshells, and electrons in these subshells reside in orbitals. • Only two electrons are allowed in any orbital, and, to do that, they must have opposite spins—they must be spin-paired. • The atom’s orbitals define the probability of finding an electron in a given region of space around the nucleus. • With an increase in the number of shells, the number of subshells and the complexity of their shapes increase.

Atomic Structure, Periodicity, and Chemical Reactivity Chapter 2 Summary Atomic Structure, Periodicity, and Chemical Reactivity • The symbolic notation that indicates the distribution of electrons in an atom is called its electron configuration. • An alternative method of representation, Lewis symbols, emphasizes the number of electrons in an atom’s valence shell. • The valence electrons dictate the chemical reactivity of each element. • The octet rule summarizes the tendency of atoms to attain noble-gas outer-shell electron configurations through chemical reactions.