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This review packet was assembled from NY State’s Core Curriculum, which outlines thematerial to be tested on the Regents exam. This is by no means a thorough review of theentire course. It is designed to be used with review sheets, past Regents exams and yourReference tables to help you prepare for the coming test. Emphasis is placed on key ideasthat are stressed by the Core Curriculum. Additional space has been left for you to addyour own notes. You cannot passively prepare for the Chemistry Regents. There are no shortcuts. You
have to study, ask questions, analyze problems and come to review sessions to be
Students taking the exam should come with a 4-function or scientific calculator (not agraphing calculator), pen, and pencil. Reference Tables will be provided. Students arerequired to stay in the examination room for a minimum of 2 hours from the time the testis distributed.
This analysis is based on the last 10 exams (June 2004 – January 2008). It is possible thenew exams will have minor modifications.
The Chemisty Regents Exam is broken down into three sections: Part A: 35 mulitple choice questions from all units covered over the course of the schoolyear.
Part B: 30 questions, 15 multiple choice and 15 short answers.
Part B focuses on the Reference Tables, graphing, and laboratory experiments.
Part C: 20 short answer questions, most broken down into smaller parts. This is often aneclectic, unpredictable mix of questions from various units, and may demand studentswrite short paragraphs, use equations and reference tables, or draw graphs and diagramsin order to correctly answer the questions.
Each question is worth 1 point, for a total of 85 points. The grading scale changes witheach test, with a raw score of 48-51 translating to a passing grade of 65.
The actual scoring scale varies with each exam, and there is no way to know what curvewill be used before the exam begins.
There are 12 specific chemistry topics covered on the test, as well as a 13th topic ongeneral lab skills: Topic One: The Atom
1. The modern model of the atom has evolved over a long period of time through the
work of many scientists.
Atoms of an element are the same.
Compounds are formed from combinations of atoms.
Bombarded gold foil with alpha particles. Showed atoms were mostly empty space with small, dense positively Small, dense, positively charged nucleus surrounded by electrons in circular orbits.
Wave-Mechanical Model (Modern Atomic Theory) Small, dense, nucleus positively charged nucleus surrounded by electrons moving in "electron cloud".
"Orbitals" are areas where an electron with a certain amount of energy is most likelyto be found.
2. Each atom is made of a positively charged nucleus with one or more orbiting,
negatively charged electrons.
3. Protons and neutrons are found in the nucleus.
4. Protons have a positive charge, neutrons no charge, and electrons a negative
5. The number of protons in an atom equals the number of electrons.
The positive charges of the protons are cancelled by the negative charges of the electrons,so overall an atom has a neutral charge.
6. The mass of a proton is 1 amu. The mass of a neutron is 1 amu. The mass of an
electron is almost 0 amu.
The amu is defined as 1/12 the mass of a Carbon atom.
The atomic mass of an atom is equal to the total number of protons 7. Each electron in an atom has its own distinct amount of energy.
When all electrons are at their lowest possible energy, it is called the "ground state." Electrons fill in energy levels and orbitals starting with the one that requires the leastenergy (1s) and progressively move to those levels and orbitals that require increasingamounts of energy.
8. When the electron gains a specific amount of energy, it moves to a higher orbital
and is in the "excited state".
9. When an electron returns from a higher energy state to a lower energy state, it
emits a specific amount of energy usually in the form of light. This can be used to
identify an element (bright line spectrum).
The instrument used to see the bright line spectrum is called a spectroscope.
10. The outermost electrons are called valence electrons. These affect the chemical
properties of the element.
Atoms with a filled valence level are stable.
Most elements can have up to 8 electrons in their valence level. The exceptions are H andHe, which can have only 2 valence electrons.
Atoms form bonds in order to fill their valence levels.
You can use orbital notation or Lewis structures to show the configuration of the valenceelectrons.
11. Atoms of the same element all contain the same number of protons.
Changing the number of protons changes the atom into a different element.
The atomic number is the number of protons in an atom of an element.
12. Isotopes are atoms with equal numbers of protons but different numbers of
Isotopes of an element have the same atomic number (protons only), but different atomicmasses (protons + neutrons).
13. The average atomic mass of an element is the weighted average of its naturally
14. When an atom gains an electron, it becomes a negative ion and its radius
15. When an atom loses an electron, it becomes a positive ion and its radius
16. Electron-dot diagrams (Lewis structures) represent the valence electron
arrangement in elements, compounds and ions.
Electrons in Lewis structures are arranged by their orbitals.
The first two electrons are placed together in the "s" orbital.
The remaining electrons are spread among the 3 "p" orbitals.
The "s" orbital must be filled first. Then each "p" orbital must have one electron beforeanother "p" orbital gains a second.
17. Electronegativity indicates how strongly an atom of an element attracts electrons
in a chemical bond. These values are based on an arbitrary scale.
Fluorine has the highest electronegativity of all elements (4.00).
Topic Two: Nuclear Chemistry
1. The stability of an isotope depends on the ratio of protons to neutrons in the
Most nuclei are stable, but some are unstable. These nuclei will spontaneously decay,emitting radiation.
Stable isotopes have a 1:1 ratio of protons and neutrons. Most radioactive isotopes havetwice as many neutrons as protons.
All elements with an atomic number higher than 83 are radioactive.
2. Each isotope has a specific mode and rate of decay. (see Table N)
The rate of decay is called half life.
Half-life is a constant that can never be changed.
Half life is the measure of the time it takes exactly one half of an amount of isotope todecay.
The amount of substance will never decay to zero.
3. A change in the nucleus of an atom changes it to a new type of atom (i.e. a new
element). This is called transmutation.
Transmutation can occur naturally or artificially.
Artificial transmutation requires the bombardment of a nucleus by high energy particles.
4. Spontaneous decay can involve the release of different particles from the nucleus.
The types of particles, as well as their masses and charges, can be found on Table O.
5. Nuclear reactions include natural and artificial decay, nuclear fission and nuclear
Nuclear fission occurs when the nucleus of an atom is split. This can be causedartificially by "shooting" the nucleus with a neutron.
Nuclear fusion combines two light nuclei to form heavier nuclei. Nuclear fusion is theprocess that powers the sun.
Nuclear fusion requires very high temperatures, and is not yet ready for practical use. Themain advantage it offers is that the products are not radioactive wastes (as with fission).
6. Nuclear reactions can be represented by equations that include symbols which
represent atomic nuclei (with mass number and atomic number), subatomic
particles (with mass and charge) and emitted particles.
7. Energy from nuclear reactions comes from the very small fraction of mass that is
lost – the reaction converts matter into energy.
Einstein’s E=mc2 describes the relationship between energy and matter.
8. The energy released from nuclear reactions is much greater than that released
from chemical reactions.
9. The risks associated with using radioactive isotopes include biological exposure
(which may cause radiation poisoning and cancer), long-term storage and disposal,
and nuclear accidents.
10. Radioactive isotopes may be used in medicine (tracing chemical and biological
processes), radioactive dating, industrial measurement, nuclear power, and
detection and treatment of disease.
Topic Three: Bonding
1. Chemical compounds are formed when atoms are bonded together.
Breaking a chemical bond is an endothermic process.
Forming a chemical bond is an exothermic process.
Compounds have less potential energy than the individual atoms they are formed from.
2. Two major categories of compounds are ionic and molecular (covalent)
3. Compounds can be differentiated by their chemical and physical properties.
Ionic substances have high melting and boiling points, form crystals, dissolve in water(dissociation), and conduct electricity in solution and as a liquid.
Covalent or molecular substances have lower melting and boiling points, do not conductelectricity.
Polar substances are dissolved only by another polar substance. Non-polar substances aredissolved only by other non-polar substances.
4. Atoms gain a stable electron configuration by bonding with other atoms.
Atoms are stable when they have a full valence level.
Most atoms need 8 electrons to fill their valence level.
H and He only need 2 electrons to fill their valence level.
The noble gases (group 18) have filled valence levels. They do not normally bond withother atoms.
5. Chemical bonds are formed when valence electrons are:
Transferred from one atom to another – ionic.
Mobile in a free moving "sea" of electrons – metallic.
6. In multiple (double or triple) covalent bonds more than 1 pair of electrons are
shared between two atoms.
oxygen and it’s family (grp 16) form double bonds with each other (O2) nitrogen and it’s family (grp 15) form triple bonds with each other (NH3) carbon can form double and triple bonds with itself, grp 16 and grp 15 elements (ex:CO2) 7. Polarity of a molecule can be determined by its shape and the distribution of the
Polar molecules must have polar bonds.
Nonpolar molecules are symmetrical and/or have no polar bonds.
8. The electronegativity difference between two bonded atoms can determine the
type of bond and its polarity.
9. Bonding guidelines:
Metals react with nonmetals to form ionic compounds.
Nonmetals bond with nonmetals to form covalent compounds (molecules).
Ionic compounds with polyatomic ions have both ionic and covalent bonds.
10. Intermolecular forces allow different particles to be attracted to each other to
form solids and liquids.
Hydrogen bonds are an example of a strong IMF between atoms.
Hydrogen bonds exist between atoms of hydrogen and oxygen, fluorine, or nitrogen.
Substances with hydrogen bonds tend to have much higher melting and boiling pointsthan those without hydrogen bonds.
11. Physical properties of a substance can be explained in terms of chemical bonds
and intermolecular forces. These include conductivity, malleability, solubility,
ductility, hardness, melting point and boiling point.
Topic Four: Matter, Phases and Gas Laws
1. Matter is classified as a pure substance or a mixture of substances.
A substance has fixed composition and uniform properties throughout the sample.
Element and compounds are substances.
2. A mixture is composed of two or more different substances that may be physically
A mixture may be homogeneous (uniform – a solution), or heterogeneous (uneven).
Substances in a mixture retain their original properties.
Substances in a mixture may be separated by their size, polarity, density, boiling andfreezing points, and solubility (among others).
Filtration and distillation are examples of processes used to separate mixtures.
2. An element is a substance composed of atoms with the same atomic number. They
cannot be broken down by chemical change.
3. A compound is two or more elements bonded together. It can only be broken
down by chemical changes.
Substances that form a compound gain new properties.
The ratio of substances in a compound is constant (e.g. water has a fixed ratio 2:1 ratio ofhydrogen to oxygen).
4. A physical change is one that results in the rearrangement of existing particles in
a substance (ex: freezing, boiling). A chemical change results in the formation of
different substances with different properties.
Chemical and physical changes may be endothermic or exothermic.
5. The three phases of matter are solid, liquid and gas. Each has its own properties.
Solids have a constant volume and shape. Particles are held in a rigid, crystallinestructure.
Liquids have a constant volume but a changing shape. Particles are mobile but still heldtogether by strong attraction.
Gases have no set volume or shape. They will completely fill any closed contained.
Particles have largely broken free of the forces holding them together.
6. A heating curve (or cooling curve) traces the changes in temperature of a
substance as it changes from solid to liquid to gas (or gas to liquid to solid).
When the substance undergoes a phase change, there is no change in temperature. Theline "flattens" until the phase change is complete.
When a phase change is occurring, the potential energy of the substance changes whilekinetic energy remains the same.
As temperature increases, kinetic energy increases.
7. Heat of fusion (Hf) is the energy needed to convert one gram of a substance from
solid to liquid.
8. Heat of vaporization (Hv) is the energy needed to convert one gram of a substance
from liquid to gas.
9. Specific heat (C) is the energy required to raise one gram of a substance 1 degree
(Celcius or Kelvin).
The specific heat of liquid water is 1 cal/g*J or 4.2 J/g*K.
10. The combined gas law states the relationship between pressure, temperature and
volume in a sample of gas.
Increasing pressure causes a decrease in volume (inverse relationship).
Increasing temperature causes an increase in volume (direct relationship).
Increasing temperature causes an increase in pressure.(direct relationship).
11. An ideal gas model is used to explain the behavior of gases. A real gas is most
like an ideal gas when it is at high temperature and low pressure.
The real gases that most resemble ideal gases are H2 and He 12. The Kinetic Molecular Theory (KMT) for an ideal gas states that all gas
have no forces of attraction between them.
have a negligible volume compared to the distances between them.
have collisions that result in the transfer of energy from one particle to another, with nonet loss of energy from the collision.
13. Equal volumes of gases at the same temp and pressure have an equal number of
Topic Five: Energy
1. Energy can exist in different forms – chemical, electrical, electromagnetic,
thermal, mechanical, nuclear.
Stored energy is referred to as potential energy.
2. The Law of Conservation of Energy states that energy can not be lost or
destroyed, only changed from one form to another.
3. Heat is a transfer of energy (often but not always thermal energy) from a body of
higher temperature to a body of lower temperature.
4. Temperature is a measure of the average kinetic energy of the particles in a
sample. Temperature is NOT a form of energy and should not be confused with
5. The concepts of kinetic and potential energy can be used to explain physical
processes such as fusion (melting), solidification (freezing), vaporization (boiling,
evaporation), condensation, sublimation, and deposition.
6. Processes that are exothermic give off heat energy. This typically causes the
surrounding environment to become warmer.
7. Processes that are endothermic absorb energy. This typically causes the
surrounding environment to become colder.
Topic Six: The Periodic Table
1. The placement of an element on the Periodic Table gives an indication of the
chemical and physical properties of that element.
2. Elements are arranged in order of increasing atomic number.
3. The number of protons in an atom (atomic number) identifies the element.
The number of protons in an atom only changes through nuclear reactions.
4. The atomic mass is the sum of protons and neutrons in the nucleus.
The mass number given on the periodic table is a weighted average of the differentisotopes of that element.
Electrons do not significantly add to the atomic mass.
5. Isotopes of an element are identified by the sum of protons and neutrons.
Isotopes of the same element have the same number of protons and a different number ofneutrons.
Examples of isotopic notation are: 146C, 14 C, carbon-14, C-14 6. Elements can be classified by their properties and their location on the Periodic
Table as metals, non-metals, metalloids, and noble gases.
7. Elements may be differentiated by their physical properties.
Ex: Density, conductivity, malleability, hardness, ductility, solubility 8. Elements may be differentiated by their chemical properties.
Chemical properties describe how an element behaves in a chemical reaction.
9. Elements are arranged into periods and groups.
10. Elements of the same period have the same number of occupied energy levels.
11. Elements of the same group have the same valence configuration and similar
Group 1 elements other than H are alkali metals. Group 2 elements are alkali earth metals.
Alkali metals, alkali earth metals, and halogens all are highly reactive and do not exist asfree elements in nature (they are all found in compounds).
Group 18 elements are noble or inert gases. These elements have filled valence levelsand are do not normally react with other substances.
12. The succession of elements within a group demonstrates characteristic trends in
properties. As you progress down a group:
13. The succession of elements within a period demonstrates characteristic trends in
properties. As you progress across a group from left to right:
14. Some elements may exist in two or more forms in the same phase. These forms
differ in their molecular or crystal structure, hence their different properties.
Ex: Carbon exists as both graphite and diamond (a network solid).
Topic Seven: Moles and Stoichiometry
1. A compound is a substance composed of two or more different elements that are
chemically combined in a fixed proportion. A chemical compound can only be
broken down by chemical means.
2. Chemical compounds can be represented by a specific formula and assigned a
name based on the IUPAC system.
3. Types of chemical formulas include empirical, molecular, and structural.
Empirical formulas show elements in their simplest whole number ratios. This may ormay not be the same as the molecular formula.
Molecular formulas show the actual number of atoms per element in a single molecule.
Structural formulas show the number of each type of atom as well as their physicalarrangement.
4. All chemical reactions show a conservation of mass, energy and charge.
5. A balanced chemical equation represents conservation of atoms.
6. The coefficients in a balanced chemical equation can be used to determine mole
ratios in the reaction.
7. The formula mass of a substance is the sum of the atomic masses of its atoms. The
molar mass (gram formula mass) equals the mass of one mole of that substance.
8. The percent composition by mass of each element in a compound can be
9. Types of chemical reactions include synthesis, decomposition
single replacement, and double replacement.
Topic Eight: Solutions
1. A solution is a homogeneous mixture of a solute dissolved in a solvent.
Solubility depends on temperature, pressure, and the nature of the solute and solvent.
"Like dissolves like" – polar substances dissolve polar substances, and non-polarsubstances dissolve non-polar substances. Polar and non-polar do not mix.
2. Ionic substances dissolve in polar solvents. The positive ion is attracted to the
negative end of the polar molecule, as the negative ion is attracted to its positive end.
3. Concentration of a solution can be expressed as molarity (M), percent by volume,
percent by mass, or parts per million (ppm).
4. Adding a solute to a solvent causes the boiling point of the solvent to increase and
the freezing point to decrease.
5. A saturated solution exists in equilibrium – the rate of crystallization equals the
rate of dissolving.
Topic Nine: Kinetics and Equilibrium
1. Collision theory states that a reaction is most likely to occur if reactant particles
collide with the proper energy and orientation.
2. The rate of a chemical reaction depends on temperature, concentration, nature of
the reactants, surface area and the presence of a catalyst.
3. Energy absorbed or released by a chemical reaction can be represented by a
potential energy diagram.
4. The amount of energy released or absorbed during a chemical reaction is the heat
Heat of reaction equals the PE of the products – PE of reactants.
Positive heat of reaction implies an endothermic reaction.
Negative heat of reaction implies an exothermic reaction.
5. A catalyst provides an alternative pathway for a chemical reaction. The catalyzed
reaction requires a lower activation energy than the uncatalyzed reaction.
Adding a catalyst increases the rate of the forward and reverse reactions equally, so thereis no shift in equilibrium.
6. Entropy is a measure of the randomness or disorder in a system. A system with
greater disorder has greater entropy.
7. Systems in nature tend to undergo changes towards lower energy and higher
8. Exothermic reactions that result in increased entropy are spontaneous.
10. At equilibrium the rate of the forward reaction equals the rate of the reverse
11. The measurable quantities of reactants and products remain constant at
12. LeChatelier’s principle can be used to predict the effect of stress on a system in
Stresses include a change in pressure, volume, concentration, and temperature.
Topic Ten: Acids, Bases and Salts
1. Behavior of many acids and bases can be explained by the Arrhenius theory.
Arrhenius acids and bases are electrolytes.
2. An electrolyte is a substance which, when dissolved in water, forms a solution
capable of conducting electricity. The ability to conduct electricity depends on the
concentration of ions.
3. Arrhenius acids yield H+(aq) ions as the only positive ion in solution.
H+(aq) ions may also be written as H3O+(aq) ions (hydronium ions).
4. Arrhenius bases yield OH-(aq) ions as the only negative ion in solution.
Organic compounds with OH- are not bases.
5. In neutralization reactions an Arrhenius acid and an Arrhenius base react to
form salt and water.
The net ionic equation for all neutralization reactions is the same: H+(aq) + OH- (aq) H2O (l) 6. Titration is a lab process in which a volume of a solution of known concentration
is used to determine the concentration of another solution. Titration is a practical
application of a neutralization reaction.
7. There are other acid-base theories besides the Arrhenius theory. The Bronsted-
Lowry theory states an acid is a H+ donor and a base a H+ acceptor.
8. The acidity or alkalinity of a solution can be measured by pH.
A low pH (0-6) indicates a higher concentration of H+ ions than OH- ions.
A high pH (8-14) indicates a lower concentration of H+ ions than OH- ions.
A neutral pH (7) indicates an equal concentration of H+ ions than OH- ions.
9. On the pH scale, each decrease of one pH unit represents a tenfold increase in H+
Topic Eleven: Oxidation-Reduction (Redox)
1. An oxidation-reduction (redox) reaction involves the transfer of electrons (e-).
2. Reduction is the gain of electrons and decrease of oxidation number.
A half reaction can be written to represent reduction.
3. Oxidation is the loss of electrons and increase of oxidation number.
A half reaction can be written to represent oxidation.
4. In redox the number of electrons lost is equal to the number of electrons gained.
5. Oxidation numbers/states can be assigned to atoms and ions. Changes in
oxidation numbers indicate that a redox reaction has occurred.
Double replacement reactions are not redox reactions.
A reaction in which an element is alone on one side of a reaction, and part of a compoundon the other side is always a redox reaction.
6. An electrochemical cell can be either voltaic or electrolytic.
7. In an electrochemical cell oxidation occurs at the anode and reduction at the
You can use Table J to determine the anode and the cathode. The anode is higher in avoltaic cell, and lower in an electrolytic cell.
8. A voltaic cell spontaneously converts chemical energy to electrical energy.
9. An electrolytic cell requires energy to produce a chemical change. This is called
Topic Twelve: Organic Chemistry
1. Organic compounds consist of carbon atoms which bond to each other in chains,
rings and networks to form a variety of structures.
2. Organic compounds can be named with the IUPAC system.
3. Hydrocarbons are compounds that contain only carbon and hydrogen.
Saturated hydrocarbons contain only single carbon-carbon bonds.
Unsaturated hydrocarbons contain at least one multiple carbon-carbon bond (double ortriple bond).
4. Organic acids, alcohols, esters, aldehydes, ketones, ethers, halides, amines,
amides, and amino acids are categories of organic molecules that differ in their
5. Functional groups give organic molecules distinct physical and chemical
6. Isomers of organic compounds have the same molecular formula but different
structures and properties.
7. In a multiple covalent bond, more than one pair of electrons are shared between
two atoms. Unsaturated organic compounds contain at least one double or triple
8. Types of organic reactions include: addition, substitution, polymerization,
esterification, fermentation, saponification, and combustion.
Topic Thirteen: Lab skills
1. Any standard chemistry lab procedure is fair game for the Regents. Specific skills
that may be tested include:
Using the scientific method for a controlled experiment.
Making accurate and precise measurements.
Significant figures are used when doing math with measurements, and reflect theprecision of your measurements.
Significant figures include all digits that you are certain of, plus one that is anestimate.
All non-zero digits are significant.
All leading zeros (zeros before the 1st non-zero digit) are not significant, whether ornot there is a decimal.
All zeros between non-zero numbers are significant.
Trailing zeros (zeros after the last non-zero number) are significant if and only if thereis a decimal point.
Constants (such as the freezing point of water at STP) and certain numbers (thenumber of people in the room) are considered to have an infinite number of sig figs.
For multiplication and division, the answer should have the same number of digits asthe measurement with the fewest sig figs.
For addition and subtraction, the answer must have the same number of decimalplaces as the measurement with the fewest number of decimal places. The total numberof digits does not matter.
When problems have a mix of multiplication/division and addition/subtraction, usethe multiplication/division rules.
Identification and use of lab equipment.
October / November 2008 Rhapsody in Black and White. The main gallery at DIVA will feature 31 photographs by Charles Teenie Harris, selected from Archives of the Carnegie Museum of Art in Pittsburgh, PA. Harris' photographs reflect African- American urban life in the mid-20th Century, from the Depression to the Civil Rights Movement. This touring exhibit, Charles "Teenie" Harri