Honors Chemistry Unit 5 Chemical bonding Chemical formulas Chemical naming 1 Chemical Bonding Electrical attraction between nuclei of one atom and valance (outer shell) electrons of a different atom. I. Ionic Bonding _________________ of electrons from the ___________(cation) to the ____________ (anion) Electrical attraction between large numbers of cations and anions. “clusters” Cation = positively particle Typically are metals Loves to give electrons away Low Ionization Energy Low Electron Affinity Low Electronegativity Most metallic element = Francium Anion = negatively charged particle Typically are non metals Loves to accept or take on electrons Higher Ionization Energy Higher Electron Affinity Higher Electronegativity Most nonmetallic element = Fluorine Ionic compounds are ________________ Ionic bonds _________________________in water - Fall apart into cations and anions -Will conduct electricity EN (electronegativity) difference is 1.8 – 4 Maximum value is 4 (Fluorine is a 4) 2 II. Covalent Bonds Formed when 2 _______________ atoms ______________electrons A. ____________ Covalent __________________ sharing of electrons H Cl Electrons attracted MORE to higher EN atom, so density is greater around atom with higher EN value. EN of H = 2.1 EN of Cl = 3.0 EN difference = .9 EN difference range = >_______– ________ for polar covalent bonds Polar Covalent compounds dissolve in H2O don’t fall apart into ions…. No conductivity! B. _________________ Covalent Bonds ______________ sharing of electrons Br Br Electrons are shared equally between two atoms. EN difference for nonpolar covalent bonds is _____-_______. Usually nonpolar covalent bonds are between diatomic molecules – two of the same atoms. Nonpolar covalent compounds do not dissolve in water no conductivity. Can be a gas, liquid, or solid. 3 III. Metallic Bonds Bond formed between 2 _____________atoms. Larger outer electron shells – which overlap Electrons are free to move within electron clouds of all metal ions = ___________________________ Electrons are ______________________ - they don’t belong to any one atom anymore. 4 Types of Bonds Ionic Examples Na and Cl Covalent C and Cl Metallic Na and Na Types of elements (metal? nonmetal?) Electronegativity Difference between elements How are the electrons involved? Compound formed from example above Name for a single unit of this compound Bond Strength State at room temperature Polarity 5 6 Polar versus Non Polar Ionic versus Covalent Substance Formula Physical Appearance Polar or Non Polar (Dissolve?) Conducts Electricity? Ionic or Covalent 1. Baking Soda 2. Sugar 3. Salt 4. Splenda 5. Milk of Magnesia 6. Flour 7 Substance Formula Physical Appearance Polar or Non Polar (Dissolve?) Conducts Electricity? Ionic or Covalent 7. Baking Powder 8. Epsom Salts 9. Cream of Tartar 10. Alum 11. Rolaids 12. Chicken Bouillon 8 Name_________________ Chemical Bonds Lab Part 1. Conductivity Introduction: A compound is defined as a chemical combination of two or more elements. A chemical bond is the "glue" holding together atoms of different elements. Two types of bonds are Ionic and covalent. Ionic bonds generally occur between a metallic and nonmetallic atom. The bond results from the transfer of one or more electrons from the metallic atom to the nonmetallic atom resulting in a charge difference. The positively charged metal ion is then attracted to the negatively charged nonmetallic ion. Covalent bonding involves the sharing of electrons. In the following activity, you will be exploring one additional property displayed by the molecules that contain these bonds. In this investigation, you will be observing three groups of substances known as strong electrolytes, weak electrolytes, and nonelectrolytes When placed in an aqueous solution (water) ionically bonded substances dissociate into their ions and demonstrate the ability to conduct electricity. These are considered __________________electrolytes. Some covalently bonded substances also have the ability to conduct electricity at low levels. These are considered ____________________ electrolytes. Finally, there are many substances that, when placed in water do not dissociate into ions. As a result, these substances fall to conduct electricity. These are considered ____________________ electrolytes. Materials: Solutions Equipment 24-well microplate Conductivity meter Deionized Water-dH2O (to rinse electrodes) Beaker Ethyl Alcohol (CH3CH2OH) Hydrochloric acid (HCl) Sodium Hydroxide (NaOH) Hexane (C6H14) Copper (II) Chloride (CuCl2) Bleach (NaClO) Tap H2O dH2O Ammonia (NH3) Sodium Chloride (NaCl) Glucose (C6H12O6) Acetic Acid (CH3COOH) Calcium Chloride (CaCl2) 9 Experiment: 1) In data table 1, record the substances’ names and formulas that will be tested. Calculate the highest electronegativity difference between any 2 elements in the formula and predict the type of bond contained in the substance (Ionic, NP Covalent, P Covalent). 2) In the diagram of the well plate below, put the name of the compound in the well number that you intend to put that compound in. This will act as a key since the solutions appear identical. 1 2 3 4 5 6 A B C D Procedure 1) Obtain a small sample of each substance and add it to the appropriate well. Add just enough to cover the bottom of the well. 2) Place both metal probes of the conductivity meter into the well. Press and hold the low button. If the meter lights up less than 10, record the number in the data table. If the meter lights up 10, then press and hold the high button. You must add 10 to the meter reading when on high when you record it in your data table. 3) Rinse the metal probes of the conductivity meter with the wash bottle of dH2O while holding it over a beaker. Wipe dry. 4) Repeat steps 2 & 3 for each compound. 10 Data Table 1: Formula of Substance Tap H2O Largest Electronegativity Difference Predicted Type of Bond Conductivity Meter Reading dH2O NH3 NaCl C6H12O6 CH3COOH CaCl2 CH3CH2OH HCl NaOH CuCl2 NaClO C6H14 Conclusions: 1) Identify those compounds that showed an unexpected result (e.g. a covalent compound that had a high electronegativity value) and discuss possible reasons why that result was obtained. 11 Part 2. Properties of Chemical Bonds Introduction: The physical properties of a substance, such as melting point, solubility, and conductivity, can be used to predict the type of bond that binds the atoms of the compound. In this experiment, you will test various compounds to determine these properties. Your compiled data will enable you to classify the substances as either ionic or covalent compounds. Materials: Equipment Candle Ring stand Conductivity tester Thin-stemmed pipets, 2 Iron ring Tin can lid Matches Solutions Benzoic acid (C6H5COOH) Calcium chloride (CaCl2) Potassium iodide (KI) Sodium chloride (NaCl) Sucrose (C12H22O11) Citric acid (C6H12O7) Deionized Water (dH2O) Ethyl Alcohol (CH3CH2OH) Experiment: Part A. Melting Point 1. Place a can lid on an iron ring attached to a ring stand. Position the ring so that it is just above the tip of a candle flame, as shown in Figure A (next page). Light the candle for a moment to check that you have the correct height. 2. Place a few crystals of sucrose, sodium chloride, benzoic acid, calcium chloride, citric acid, and potassium iodide in separate locations on the lid, as shown in Figure B (next page). Do not allow the samples of crystals to touch. Draw the position of each compound in the diagram below. Ring Stand Diagram 1. 12 3. Write a brief description of each of the six substances in Data Table 2. 4. For this experiment, it is not necessary to have exact values for the melting point. The lid will continue to get hotter as it is heated, so the order of melting will give relative melting points. Light the candle and observe. Note the substance that melts first by writing a Benzoic acid “1” in the data table. Record the order of melting for the other substances. 5. After 3 min., record an “n” in your data table for each substance that did not melt. Extinguish the candle flame. Allow the tin can lid to cool while you complete the remainder of the experiment. Part B. Solubility & Conductivity 1. Put a few crystals of each of the white solids in the top row of your microplate. Repeat with the second row. Add 10 drops of water to each well in the top row. Record the solubility of each substance in data table 2. 2. Add 10 drops of ethanol to each well in the second row of the microplate. Record the solubility of each substance in your data table. 3. Test the conductivity of each water solution in the top row by dipping both electrodes into each well of the microplate. Be sure to rinse the electrodes and dry them with a paper towel after each test. If the bulb of the conductivity apparatus lights up, the solution conducts electricity. Record your results in Data Table 2. 4. Clean the microplate by rinsing it well with water in the sink. Make sure all the wells are clean and then dry each well with a paper towel. Clean the substances off of the can lid in the sink. Be very careful not to cut yourself. Wash your hands thoroughly before you leave the lab and after all work is finished. 13 Data Table 2. Melting Compound Description Point Solubility Solubility Conductivity in water in ethanol meter reading Calcium Chloride Citric Acid Benzoic Acid Potassium Iodide Sodium Chloride Sucrose Conclusions: 1) Group the white substances into two groups according to their properties. Group1 Group2 2) List the properties of each group. Group1 Group2 14 3) Use your prior knowledge and your experimental data to determine which of the groups consists of ionic compounds and which consists of covalent compounds. 4) Write a short paragraph to summarize the properties of ionic compounds and another short paragraph to summarize the properties of covalent compounds. Include all properties tested in this experiment. 15 16 Ionic Covalent 17 18 Periodic Table with Electronegativities 1A 2A 3B 4B 5B 6B 7B 8B 1B 2B 3A 4A 5A 6A 1 H 2.1 7A 8A 2 He 3 4 Li Be 1.0 1.5 5 6 7 8 9 10 B C N O F Ne 2.0 2.5 3.0 3.5 4.0 11 12 Na Mg 0.9 1.2 13 14 15 16 17 18 Al Si P S Cl Ar 1.5 1.8 2.1 2.5 3.0 19 20 21 K Ca Sc 0.8 1.0 1.3 22 Ti 1.5 23 V 1.6 24 Cr 1.6 25 Mn 1.5 26 Fe 1.8 27 Co 1.9 28 Ni 1.9 29 Cu 1.9 30 Zn 1.6 31 32 33 34 35 36 Ga Ge As Se Br Kr 1.6 1.8 2.0 2.4 2.8 3.0 37 38 39 Rb Sr Y 0.8 1.0 1.2 40 Zr 1.4 41 Nb 1.6 42 Mo 1.8 43 Tc 1.9 44 Ru 2.2 45 Rh 2.2 46 Pd 2.2 47 Ag 1.9 48 Cd 1.7 49 50 51 52 53 54 In Sn Sb Te I Xe 1.7 1.8 1.9 2.1 2.5 2.6 55 56 57 Cs Ba La 0.7 0.9 1.1 72 Hf 1.3 73 Ta 1.5 74 W 1.7 75 Re 1.9 76 Os 2.2 77 Ir 2.2 78 Pt 2.2 79 Au 2.4 80 Hg 1.9 81 82 83 84 85 86 Tl Pb Bi Po At Rn 1.8 1.9 1.9 2.0 2.2 2.4 87 88 89 104 105 106 107 108 109 110 111 112 Fr Ra Ac Rf Ha Sg Ns Hs Mt Uun Uuu Uub 0.7 0.9 1.1 58 59 60 61 62 63 64 65 66 67 Ce Pr Nd Pm Sm Eu Gd Tb Dy Ho 1.1 1.1 1.1 1.2 1.2 1.1 1.2 1.2 1.2 1.2 68 Er 1.2 69 Tm 1.2 70 Yb 1.2 71 Lu 1.3 90 91 92 93 94 95 96 97 98 99 100 101 102 103 Th Pa U Np Pu Am Cm Bk Cf Es Fm Md No Lr 1.3 1.5 1.7 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.5 Keep in mind that electronegativities are approximate measures of the relative tendencies of these elements to attract electrons to themselves in a chemical bond. The greater an atom's electronegativity, the greater its ability to attract electrons to itself. 19 20 Calculating Bond Type (using Electronegativity Values) Electronegativity Difference Bond Type Ionic Character 0.0 – 0.3 Non-polar covalent 0 – 5% 0.3 – 1.7 Polar covalent 5 – 50% Over 1.7 Ionic Higher than 50% 1. Find electronegativity values for each element. 2. Subtract the lesser value from the larger value (so the value is positive). 3. Find the difference value on the above chart; convert it to a bond type. 21 Using Modified Rule of Thumb To Predict Bond Type Active Metal (S-block) + Non metal Ionic Bond Transition Metal (D and F blocks) + Non metal Ionic or Covalent Non metal + Non metal Covalent Elements Predict using Rule of Thumb Au and I Au = I= Ca = F= P= Br = Ag = Cl = Ti = O= Ca and F P and Br Ag and Cl Ti and O C6H12O6 C–H C–O Predict based on Electronegativity values (see page 17) Au = I= Ca = F= P= Br = Ag = Cl = Ti = O= O–H KOH H2O MgSO4 CaCO3 22 Intermolecular bond occurs between 2 different molecules Hydrogen Bonding The intermolecular force in which a hydrogen atom that is bonded to a highly electronegative atom is attracted to an unshared pair of electrons of an electronegative atom in a nearby molecule. One molecule is polar and has hydrogen in a H-F, H-O or H-N bond Other molecule has unshared pairs of electrons, usually on F, O, or N Hydrogen forms a weak bond with the unshared pair of the other molecule H – O: H H–O H 23 Van der Waals bonds London dispersion forces result from the intermolecular attractions resulting from the constant motion of electrons and the creation of instantaneous dipoles. They can be very weak intermolecular forces between noble gas atoms and nonpolar molecules Electrons of Noble Gas get shifted to one side causing it to attract a slightly positive atom that is nearby. Dispersion forces are present between any two molecules (even polar molecules) 24 Bonding Review Sheet Name the type of bond that will occur between the elements/compounds below based on the periodic table. 1. Zn + Zn 2. Ca + Cl 3. I + I 4. Co + Ne 5. Mg + O 6. H2O + H2O Below list all of the characteristics of the following words: Ionic Bond Van der Waals Bonds Metallic Bond Polar Colvalent Hydrogen Bond Nonpolar Covalent 25 Write the electronegativity difference for the compounds below and decide what type of bond is occurring Compound Electronegativity difference Type of bond CaCl2 Br2 CH4 C6H12O6 Using the elements below, draw a nonpolar electron cloud and a polar electron cloud and describe why they are different. Label the type of bond (polar or nonpolar covalent) H Cl Br Type of bond ____________ Element Nitogen Nuclear Symbol Br _____________ Mass Number # of Protons # of Neutrons # of Electrons 50 38 15 48 22 26 Octet Rule Chemical compounds tend to form so that each atom, by gaining, losing, or sharing electrons, has an octet of electrons in its highest occupied energy level. Metals from I, II, and III will not have an octet. Family I (________________________) will have 1 bond (2 electrons) only Family II (___________________________) will have 2 bonds (4 electrons) only Family III (________________________) will have 3 bonds (6 electrons) only All other elements will have 4 bonds (8 electrons)! 27 Making Ionic Compounds!! (with a metal and a non-metal) Make compounds from the following cations and anions Br-, Si4+, Ca2+, (NO3)-, P3-, Ga3+, (NH4)+, (CO3) 2- Cations = (Put them along the side of the table) Anions = (Put them across the top of the table) ----------- ------------ ------------- -------------- 28 Naming Ionic Compounds 1. Name metal (cation) first, use name as it appears on the periodic table. 2. If it is a transition metal, it might need a roman numeral. (The roman numeral equals the charge) The transition metals that don’t need a roman numeral are: 3. Name nonmetal (anion) second. Use an ide ending on the element name if it is an element off of the periodic table. Ex. NaCl = Sodium Chloride Exceptions: Oxygen becomes oxide Sulfur becomes sulfide Hydrogen becomes hydride Phosphorus becomes phosphide 4. If the anion is a polyatomic, the name remains the same: Ex. NaNO3 is Sodium Nitrate Fe(NO3)3 is Iron (III) Nitrate 29 Cation Anion Mg 2+ F- Fr+ S2- Ga3+ P3- Zn2+ PO43- Ionic Formula Name Scandium Bromide Lead (IV) Carbide Iron (III) Oxide Silver Sulfate Sr(OH)2 Sn(C2H3O2)4 30 Naming Binary Covalent Compounds (with 2 non-metals) Write the less electronegative element first o Electronegative Trend From top to bottom – decrease From left to right – increase General order of nonmetals o C, P, N, H, S, I, Br, Cl, O, F A. Similar to naming ionic compounds the first nonmetal has the name as given on the periodic table the second nonmetal has the –ide ending B. Different than naming ionic compounds There are numerical prefixes that are used depending on how many of each nonmetal are present in the compound. 31 Number Prefix 1 mono- 2 di- 3 tri- 4 tetra- 5 penta- 6 hexa- 7 hepta- 8 octa- 9 nona- 10 deca- The only time the prefixes are not used is when there is only one of the first nonmetal- the term mono is not used in this case. o NO2 = nitrogen dioxide o NO = nitrogen monoxide o N2O4 = dinitrogen tetroxide Drop the “a” from tetra before adding oxide 32 Molecular First non-metal Second non-metal 2 Carbons 6 Fluorines 1 Phosphorous 5 Oxygens 1 Silicon 4 Chlorines 3 Nitrogens 7 Bromines Formula Name S2I4 F10Cl6 O2Br5 CN3 Trisilicon nonafluoride Carbon monoxide 33 34 Naming Various Compounds Elements Ionic or Covalent Ions Chemical Formula Name of Compound 4 Phosphorus + 10 Oxygens CS2 Calcium + Chlorine Iron (III) + Bromine Na2O Potassium + Sulfur Si3N4 Triantimony pentasulfide FeS Strontium Chloride CuO Nitrogen Dioxide N2O 35 Tin (IV) + Fluorine Cl2O7 Phosphorus Triodide CCl4 Beryllium + Fluorine Silicon monocarbide PCl3 Al2O3 1 Carbon + 1 Oxygen 36 Making More Anions 1 oxygen higher than “ate” level “ate” level 1 oxygen lower than “ate” level 2 oxygens lower than “ate” level ending ate Per Ate Ite Hypo ite Common ions have "ate" ending o BrO3-, Bromate If you lose 1 oxygen atom from "ate" ion, the form is "ite" o Ex: Bromate is BrO3o Br02- = Bromite o Charge of ion does not change as form changes! If you lose 2 oxygens atoms from "ate" ion, the form is "hypo ite" o Ex: BrO3- is Bromate o BrO- is hypobromite If you gain 1 oxygen atom from the "ate" ion, the form is "per ate" o Ex: BrO3- is Bromate o BrO4- is perbromate 37 How to recognize a compound/formula as being an acid or base: Acid: has H, hydrogen, at the beginning. Base: contains OH, hydroxide. Naming Acids Binary Acids Contain H and one other element To name: hydro + second element(change ending to –ic) + acid HCl = Hydro chlorine ic + acid Hydrochloric acid HF = Hydro fluorine ic + acid Hydrofluoric acid H 2S = HI = *If you are given the name and must write the formula, make sure you check charges and do the criss-cross! Ternary Acids (Oxyacids) 38 Contain H, O and one more element (a polyatomic ion with O in it; SO4) To Name: For –ate and per -ate polyatomic ions, name the non H, non O element (this is the 2nd element in the formula) and change the –ate ending to –ic. 1. HNO3 = nitric acid (was nitrate) 2. H2SO4 = sulfuric acid (was sulfate) 3. HC2H3O2 = acetic acid (was acetate) (acetate is also CH3COO) 4. H2SO5 = persulfuric acid (was persulfate) 5. H3PO4 = phosphoric acid (was phosphate) 6. HClO3 = 7. HNO4 = 8. HIO4= -ite and hypo -ite polyatomic ions become –ous. 1. HNO2 = nitrous acid (was nitrite) 2. HNO = hyponitrous acid (was hyponitrite) 3. H2SO3 = 4. H2SO2 = 5. HClO = 6. HIO= 39 Naming Bases: Name the metal first + hydroxide NaOH = sodium hydroxide Ca(OH)2 = calcium hydroxide Fe(OH)3 = iron (III) hydroxide *If you are given the name and must write the formula, make sure you check charges and do the criss-cross! 40 Name ____________________________________ Ionic Covalent Acid Formula Chemical Name Base 1. H2SO2 2. Br2Cl4 3. Sn3(PO4)2 4. Ba(IO3)2 5. H2O 6. HF 7. Silver hydroxide 8. Zinc perchlorate 9. Potassium sulfite 10. hypochlorous acid 11. Trioxygen pentabromide 12. Hydrosulfuric acid 41 42 Formula Acid(binary or ternary)/ Base/Ionic/ or Covalent Name 1) NaOH __________ _____________________ 2) H2SO4 __________ _____________________ 3) SbBr3 __________ _____________________ 4) Li2O __________ _____________________ 5) H2CO3 __________ _____________________ 6) Si2Br6 __________ _____________________ 7) HClO4 __________ _____________________ 8) Co2(CO3)3 __________ _____________________ 9) HCl __________ _____________________ 10) SCl4 __________ _____________________ 11) NH4CN __________ _____________________ 12) NaOH __________ _____________________ 13) B2Si __________ _____________________ 14) Cu(HCO3)2 __________ _____________________ 15) H3PO4 __________ _____________________ 16) H3BO3 __________ _____________________ 17) N2O3 __________ _____________________ 18) IO5 __________ _____________________ 19) HF __________ _____________________ 20) Na2(SO3)3 __________ _____________________ 21) CF4 __________ _____________________ 43 22) HClO2 __________ _____________________ 23) NiPO3 __________ _____________________ 24) P2O5 __________ _____________________ 25) NiSe __________ _____________________ 26) HNO2 __________ _____________________ 27) Cu(CH3COO)2 __________ _____________________ 28) H2SO3 __________ _____________________ 29) P4S5 __________ _____________________ 30) HNO3 __________ _____________________ 31) V3(PO5)5 __________ _____________________ 32) Al2S3 __________ _____________________ 33) HBr __________ _____________________ 34) HCN __________ _____________________ 35) H3PO3 __________ _____________________ 36) Sn(OH)2 __________ _____________________ 37) FeP __________ _____________________ 38) HClO3 __________ _____________________ 39) NaMnO4 __________ _____________________ 40) MnF3 __________ _____________________ 41) Be(NO2)2 __________ _____________________ 42) CO2 __________ _____________________ 43) AgBr __________ _____________________ 44) Zn3(PO2)2 __________ _____________________ 45) Mn(CO3)2 __________ _____________________ 46) Pb3N4 __________ _____________________ 44 Name ____________________________________ Fill in the Blanks! Ionic Covalent Acid Formula Chemical Name Base 1. LiOH 2. Cl4P6 3. Mo(BrO2)3 4. SnO2 5. HClO4 6. HF 7. Copper(II) hydroxide 8. Zinc persulfate 9. Barium carbonate 10. Hypocarbonous acid 11. Trinitrogen pentiodide 12. Hydrochloric Acid 45 Name ________________________________________________ Review for Naming Compounds Number Ionic or Name Formula Covalent 1 Strontium Phosphate 2 3 CS2 acid H2CO3 4 Calcium Nitrate 5 Iron (III) Sulfide 6 Fe3P2 7 Germanium tetriodide 8 LiOH 9 Mg(BrO3)2 10 Silicon Monocarbide 11 Barium Cyanide 12 Aluminum Chromate 13 acid HF 14 15 NH4Cl acid Phosphorous Acid 46