CATEGORIZE ELEMENTS AS METALS, NONMETALS, METALLOIDS AND NOBLE GASES. RECOGNIZE PERIODIC TRENDS OF ELEMENTS, INLCUDING THE NUMBER OF VALENCE ELECTRONS, ATOMIC SIZE AND REACTIVITY. CATEGORIZE ELEMENTS AS METALS, NONMETALS, METALLOIDS AND NOBLE GASES. DIFFERENTIATE BETWEEN FAMILIES AND PERIODS. USE ATOMIC NUMBER AND MASS NUMBER AND MASS NUMBER TO IDENTIFY ISOTOPES. COS 1.0, 1.1, 1.2, 1.3

WHAT YOU’LL LEARN State the charge, mass, & location of each part of an atom according to the modern model of the atom. Relate the organization of the periodic table to the arrangement of electrons within an atom. Identify isotopes of common elements. Determine how many protons, neutrons, & electrons an atom has, given its symbol, atomic number, & mass number. Locate alkali metals, alkaline earth metals, & transition metals in the periodic table. Locate semiconductors, halogens, & noble gases in the periodic table.

ATOMIC STRUCTURE

WHAT ARE ATOMS? smallest part of an element that still has element’s properties. building blocks of molecules

WHAT’S IN AN ATOM?

NUCLEUS center of each atom small & dense has positive electric charge

PROTONS subatomic particle that has positive charge found in nucleus

NEUTRONS subatomic particle that has no charge no overall charge equal number of protons and electrons whose charges exactly cancel

ELECTRONS subatomic particles with negative charges. located in a cloud (orbit) moving around outside nucleus

QUARKS particles of matter that make up protons and neutrons

MODELS OF THE ATOM

DEMOCRITUS Greek philosopher developed theory around 400 B.C. proposed that atoms make up all substances Atom — “unable to be divided”

JOHN DALTON Developed atomic theory in 1808 first atomic theory with a scientific basis model was simple sphere thought the atom could not be split Atoms of same element exactly alike

NIELS BOHR theory developed in 1913 suggested that electrons in an atom move in set paths around the nucleus much like planets orbit sun It is impossible to determine an electrons: exact location speed direction Best scientists can do is: calculate chance of finding an electron in a certain place within an atom

J.J. Thomson (1897) Discovered negatively charged particles atom was divisible! Particles discovered are electrons Atom consists of positively charged material with negative charges spread evenly throughout

Rutherford (1908) Gold Foil Experiment Positive particles shot at gold foil occasionally bounced back! Proposed dense, positively charged center called the nucleus

ENERGY LEVELS path of a given electron's orbit around a nucleus, marked by a constant distance from the nucleus Closer to nucleus, lower energy level of electrons Further from nucleus, more energy electrons have Number of filled energy levels an atom has depends on number of electrons

ORBITAL region in an atom where there is a high probability of finding electrons

VALENCE ELECTRONS found in outermost shell of an atom determines atom’s chemical properties participate in chemical bonding Every atom has between one and eight

THE PERIODIC TABLE

ORGANIZATION OF THE PERIODIC TABLE Groups similar elements together organization makes it easier to predict properties of an element based on where it is in periodic table Elements are listed in order of number of protons

PERIODIC LAW states that when elements are arranged this way, similarities in their properties will occur in a regular pattern helps determine electron arrangement

PERIODS Horizontal rows number of protons & electrons increases as you move from left to right

FAMILY/GROUP vertical column of elements Atoms of elements in same group have same number of valence electrons elements have similar properties

IONS an atom or group of atoms that has lost or gained one electron and has a negative or positive charge

HOW THE STRUCTURES OF ATOMS DIFFER

ATOMIC NUMBER (Z) number of protons in the nucleus

MASS NUMBER (A) number of protons plus the number of neutrons in nucleus

ATOMIC RADIUS is size of atom GROUPS radius increases as one proceeds down any group of periodic table WHY? adding layers of electrons PERIODS radius decreases as one proceeds across any row of periodic table increasing number of protons in nucleus as you go across the period pulls electrons in more tightly.

ISOTOPE has same number of protons as other atoms of same element do but has a different number of neutrons. Some are more common than others. If you know the atomic number and mass number of an atom, you can calculate the number of neutrons it has.

Example Chlorine 35 has a mass number of 35. Has an atomic number of 17. Mass number (A): 35 Atomic number (Z): –17 Number of neutrons: 18

ATOMIC MASS UNIT (amu) Mass of an atom or molecule that is exactly 1/12th the mass of a carbon atom with mass number 12

AVERAGE ATOMIC MASS weighted average of masses of all naturally-occurring isotopes of an element

AVERAGE ATOMIC MASS EXAMPLE About 8 out of 10 chlorine atoms are chlorine-35. Two out of 10 are chlorine-37. Avg. Atomic Mass 35.4 u

FAMILIES OF ELEMENTS

HOW ARE ELEMENTS CLASSIFIED? By similar physical & chemical properties.

ALKALI METALS group 1 shiny malleable ductile React violently w/ water Very reactive b/c it has only one valence electron Has +1 charge Not found in nature as elements Found only in compounds Ex: salt (NaCl) Lithium used to treat bipolar disorder

ALKALI EARTH METALS Group 2 two valence electrons +2 charge shiny malleable ductile Form compounds in stone & human body Calcium (Ca): Shells of sea animals, coral reefs (limestone), skeletal structure humans … Magnesium (Mg) Air plane construction Activates enzymes that speed up processes in humans brilliant white color in fireworks Medicines milk of magnesia Epsom salt

TRANSITION METALS groups 3-12 most familiar found in elemental state Iron most abundant metal used in steel Aluminum making containers, automotive parts, cookware… MERCURY only metal at room temperature used in thermostats, thermometers, batteries …

NONMETALS Some elements found in groups 13-16 & all elements in groups 17-18 except hydrogen usually gases or brittle solids at room temperature poor conductor of heat & electricity may be solids, liquids, or gases at room temperature.

HALOGENS Group 17 very reactive in elemental state Chlorine greenish yellow gas Kills bacteria Elemental chlorine is very poisonous obtained from seawater Fluorine Poisonous yellow gas used in toothpaste Bromine Dark red liquid only nonmetal liquid at room temperature Iodine shiny, purple-gray solid Used as disinfectant

NOBLE GASES group 18 Exist only as single atoms instead of molecules Unreactive b/c orbitals are full of electrons Neon Signs Helium Less dense than air Gives lift to blimps & balloons Argon/Krypton Used in light bulbs

SEMICONDUCTORS elements that can conduct electricity under certain conditions Aka metalloids: Composed of only six elements Boron, silicon, germanium, arsenic, antimony & tellurium Boron Extremely hard Added to steel to increase hardness & strength at high temperatures. Antimony Used as fire retardants Silicon Makes up 28% of earths crust Sand most common compound Used in electronics