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Download Test Objectives: Unit 1 – Measurement
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Test Objectives: Measurement Know the steps of the Scientific Method: observation, hypothesis, procedure experiment, conclusion Know the difference between theory & law Recall the rules for rounding numbers Be able to measure length, mass & volume using SI units Be able to perform one-step conversions within the metric system o examples: convert meters to centimeters or liters to cm3 Know how to derive other units from the fundamental SI units o Example: volume from length, width & height Figure out the calibration of a measuring devise Know how to determine the number of significant figures (sig figs) in a measurement Be able to determine the correct number of sig figs in a calculation involving measurements Know how to measure the mass & volume of various objects as well as calculate density for each Be able to rearrange the density equation to solve for M or V, given values for 2 of the 3 variables Be able to perform percentage of error calculations Know the volume-mass relationship for water. (One liter of water has a mass of 1 kg; one mL or cm3 of water has a mass of 1 g) Understand the relationship between sig figs and the calibration of the measuring device Understand the difference between accuracy & precision Be able to convert from conventional to scientific notation and the reverse Be able to perform calculations using scientific notation Know the definitions of temperature & absolute zero Be able to convert from °C to K and from K to °C Know the characteristics of a good graph and be able to graph simple data Test Objectives: Matter & Energy Matter: Be able to define Matter Be able to explain the three states of matter in terms of organization, volume & shape Describe the movement of particles in the solid, liquid & gaseous states Be able to define & distinguish between chemical properties & physical properties Distinguish between chemical change & physical change o Know why changes of state & dissolving are examples of physical change o Know that chemical changes involve a change of identity Be able to explain & apply the law of conservation of matter Given the mass of reactants or products be able to determine the unknown mass Be able to define what forms of matter are known as pure substances Be able to distinguish between elements, compounds, & mixtures in terms of their ability to be broken down or separated by physical or chemical means Be able to name & describe the typical separation techniques for pure substances & mixtures o Mixtures can be separated into their components by a physical process o Separation techniques may rely on differences in density, solubility, magnetism, size (filtration), appearance, boiling point (distillation), or adhesion to paper (chromatography) o Given a sample of several substances you must be able to explain how these substances can be separated Identify a chemical formula as representing either an element or a compound Distinguish between homogeneous & heterogeneous material Energy: Know the definition of energy Know the SI unit for energy Know the definitions of potential & kinetic energy Be able to give several examples of each type of energy o Know that PE resides in a chemical bond Describe the relationship between potential energy & stability Be able to explain the law of conservation of energy Know the names of all phase changes: melting, fusion, freezing, solidification, vaporization, condensation, sublimation & deposition Describe phase changes in terms of whether they are endothermic or exothermic energy processes Distinguish between heat content & the temperature of a substances o Know the direction of heat flow State & apply the law of conservation of energy Use particle diagrams to illustrate phase changes Calculate energy absorbed or released in a calorimetry experiment using the formula Q = mc∆T Rearrange the equation to solve for m or ∆T Determine final or initial temperatures using ∆T = Tf - Ti Heating & Cooling Curves Test Objectives: The Mole Know the definition of the mole Know Avogadro’s number and what it signifies Determine the atomic mass of an element using the periodic table Using subscripts, determine the number of atoms of each element in a chemical formula Recognize binary compounds Determine the formula mass (gram formula mass, molecular mass, molar mass) of a compound Determine the formula mass of a hydrated salt Determine the percent composition of the elements in a compound, given the formula of the compound o determine the percent composition of elements in a compound from measured elemental mass data Determine the percent water in a hydrate, given the formula of the hydrate Determine the number of atoms of each element in a formula when the formula is preceded by a coefficient Recognize that subscripts & coefficients in chemical formulas can refer to atom ratios or mole ratios, depending on the context Given the formula of a compound, determine the number of moles of each element (or water) present in one mole of the compound Given the formula of a substance, perform a variety of 1-step mole conversions: o moles to grams o grams to moles o moles to number of particles o particles to number of moles Use a mole map to perform 2 step mole conversions o grams to number of particles o number of particles to grams Define the terms: empirical formula and molecular formula o distinguish between the two types of formulas Given the empirical formula and the formula mass of a covalent compound, determine its molecular formula Test Objectives: The Gas Laws List the properties of gases List the 5 assumptions of the Kinetic-Molecular Theory of Gases Be able to convert between the different units of pressure measurement: Torr, atm, kPa, & mmHg Be able to express Boyle’s Law, Charles’ Law and Gay-Lussac’s Law verbally, mathematically & graphically Solve problems using all the individual laws as well as the combined gas law Know when solving gas law problems that all temperatures must be expressed in Kelvin Define STP (standard temperature and pressure) in SI units as well as in atm & °C Know how to convert temperature between the Celsius & Kelvin temperature scales Know the definition of temperature Describe the relationship between temperature & molecular velocity Distinguish between real & ideal gases o Know how temperature & pressure can be changed to make real gases behave more like ideal gases List conditions under which the gas laws break down State Avogadro’s Hypothesis Define molar volume of a gas at STP Calculate the density of a gas from molar volume & molar mass Determine the formula mass of a gas from the experimental density Know Dalton’s Law of Partial Pressures o be able to solve partial pressure problems Be able to describe the difference between effusion & diffusion o understand the dependence of effusion & diffusion of gases on mass & temperature Test Objectives: Atomic Structure I Define the term atom Distinguish between protons, neutrons & electrons o know that protons & neutrons are collectively called nucleons Define atomic number & atomic mass o Know that C-12 is the standard used to determine the atomic mass of all other atoms in amu’s o Know that the mass of C-12 in amu’s is exactly 12 Use a periodic table to determine the correct number of protons, neutrons & electrons in a particular atom Be able to define an isotope o Distinguish between isotopes of an element 12 Interpret notation for isotopes of an element (ex: C-14 or 6C) Determine the average atomic mass of an element, given isotopic abundances & masses Define the terms ion, cation & anion Calculate the number of protons, neutrons & electrons in ions Atomic Theory: List the basic ideas of Dalton’s atomic theory Describe Thomson’s model of the atom Describe Rutherford’s model of the atom & interpret his famous experiment o Be able to discuss Rutherford’s conclusion regarding the structure of the atom Describe the Bohr model of the atom In the modern or quantum theory of the atom, know what the term orbital means & how it differs from an orbit Nuclear Chemistry: Define radioactivity List the characteristics (mass, charge & penetration power) & symbols of the major nuclear emanations: alpha particle, beta particle, positron, gamma radiation, proton, neutron & electron Be able to write equations for the generation of alpha particles, beta particles & positron particles Be able to describe towards which electrode (+/-) particles will move when a radioactive beam is passed between them Be able to determine the decay mode of a specific isotope using your reference tables Test Objectives: Atomic Structure II – The Electron Use the Periodic Table to determine the correct number of protons & electrons in a particular atom Know the basic features of the Bohr model of the atom Know what is meant by the valence level of electrons Using the reference tables, determine the correct number of valence electrons for the representative elements Distinguish between valence electrons & kernel electrons (inner shell electrons) Recognize the ground state configuration of an element Distinguish between ground state & excited state configurations of an atom Explain the cause of spectral lines in terms of electrons & energy levels. Spectral lines are produced when electrons jump down from a high energy level to a low energy level Understand that electrons absorb heat, light, or electric energy when they move to an excited state (endothermic process) and release light energy when they return to the ground state configuration (exothermic process) Recognize that each line in the bright-light spectrum of an element can be used to calculate the energy of a particular electron “jump” or transition Understand that the bright line spectrum of an element can be used to determine if a given element is present in a sample, by matching the spectral lines in the emission spectrum Know how to draw Lewis Dot structures for atoms and their ions Describe the modern model of the atom (orbital model) Define the term principal energy level Know the maximum number of electrons (2n2) in a given principal energy level Know the number of sublevels for a given principle energy level Know how many orbitals in a given sublevel Define orbital (a region of space in the modern model that holds two electrons); know the difference between orbit and orbital Test Objectives: The Periodic Table List the elements that are liquids & gases at STP List the 7 diatomic elements List the properties of metals, non-metals & metalloids Identify an element as a metal, non-metal or metalloid based upon its properties Memorize: “Metals are Losers, Are you sure? Yes, I’m Positive” and be able to explain what it means Predict the size & charge of ions relative to the parent atom Define the term allotrope and list some common examples (for Carbon & Oxygen) Know how the modern periodic table was developed Identify the common groups on the PT: alkali metals, alkaline earth metals, transition metals, inner transition metals (lanthanides & actinides), halogens & noble gases Define the term “metallic character” Identify the most active metal Explain how the reactivity of non-metals is defined Identify the most active non-metal Define the terms electronegativity & ionization energy Explain how the atomic radius, ionic radius, electronegativity, first ionization energy & metallic or non-metallic properties change as you go down a group on the PT Explain how the atomic radius, ionic radius, electronegativity, first ionization energy & metallic or non-metallic properties change as you go across a period on the PT Correlate changes in atomic radii with changes in ionization energy & changes in electronegativity Recognize that elements in the same group have the same number of valence electrons & therefore similar chemical properties Correlate changes in the number of valence electrons with typical bonding behavior Predict the properties of the A-group (Main groups – 1,2, 13-18) elements from the positions of the elements in the PT Test Objectives: Bonding, IMFs, & VSEPR Theory o Know the definition of a chemical bond o Recognize that the driving force of chemical bond formation is the formation of an octet (stable valence electron configuration just like a noble gas) Ionic Bonding o Know that the attraction of opposite charges is the force of attraction in an ionic bond o Be able to describe ionic bond formation in terms of an electron transfer process o Metals transferring electrons to non-metals o “Metals are losers. Are you sure? Yes, I’m positive!” o Be able to explain why energy is absorbed when a bond is broken & energy is released when a bond is formed o Ionic reactions are exothermic o Bond breaking is endothermic o Know that metals tend to form cations (+ ions) & non-metals tend to form anions (- ions) & together they form ionic compounds o Know that ionic compounds form crystal lattice structures and be able to explain in general terms what these are o Be able to calculate which of several compounds is more ionic than the others based on electronegativity differences o Know that bonds having an electronegativity difference greater than 1.7 are considered to be ionic o the higher the electronegativity difference the greater the ionic character o less than 1.7 the compound is not considered to be ionic o Be able to discuss the physical properties of ionic compounds o Be able to explain why ionic compounds will not conduct electricity in the solid (crystalline) phase but will conduct electricity in the molten state or in solution Metallic Bonding o be able to explain how metallic bonds are formed in terms of valence electrons & temporary cations o freely flowing valence electrons moving from one overlapping valence shell to the next o be able to explain what is meant by the term “sea of mobile electrons” o be able to discuss the physical properties of metals o explain the properties of metals in terms of delocalized electrons o know why metals are malleable & ductile while ionic compounds are not o ionic compounds from crystals that will shatter if struck hard Covalent Bonding o know that when a bond is broken, energy is absorbed; when a bond is made, energy is released o define the term covalent bond and list the properties of covalent substances o know how to draw Lewis Dot structures for covalent compounds o distinguish between non-polar & polar covalent bonds o be able to determine the bond type of a chemical substance by knowing its chemical properties and/or its electronegativity data o Electronegativity difference of 0-0.4 represents a non-polar covalent bond o Electronegativity difference of 0.5-1.6 represents a polar covalent bond o Electronegativity difference 1.7 and greater represents an ionic bond o The higher the electronegativity difference the greater the ionic character of the bond o The lower the electronegativity difference the greater the covalent character of the bond predict the bond type of a chemical substance from its chemical formula know how many pairs of electrons are shared in single & multiple covalent bond o Single bond: one pair shared o Double bond: two pairs shared o Triple bond: three pairs shared Intermolecular Forces & Vapor Pressure The phase of a substance at room temperature depends on the strength of the attractions between its particles. List 3 kinds of intermolecular attractions; desribe their origins & relative strengths. Define vapor pressure. Interpret graphs of vapor pressure & temperature (Table H). Know the differences between evaporation & boiling of a substance. Understand the relationships between IMFs, vapor pressure, and boiling point VSEPR Theory predict 3-D Shapes of simple molecules from the Lewis Dot structure predict the polarity of a molecule by using its molecular geometry, derived from the Lewis Dot structure