ࡱ> _ lbjbj 4nbbk"66666JJJJ\JBhBBBBB1 1 1 AAAAAAA$oD!G@A6w!L1 w!w!@A66BBA%%%w!6B6BA%w!A%% >r@B`D #>AA0B>G# G4r@G6r@1 0a "%  1 1 1 @A@A$ 1 1 1 Bw!w!w!w!G1 1 1 1 1 1 1 1 1  : Types of Chemical Reactions Chemist: _________________________Per: ______ Background: There are many kinds of chemical reactions and several ways to classify them. One useful method classifies reactions into four major types. These are: (1) direct combination, or synthesis; (2) decomposition, or analysis; (3) single replacement; and (4) exchange of ions, or double replacement. Not all reactions can be put into one of these categories. Many, however, can. In a synthesis reaction, two or more substance (elements or compounds) combine to form a more complex substance. Equations for synthesis reactions have the general form A+B( AB. A decomposition reaction is the opposite of a synthesis reaction. In decomposition, a compound breaks down into two or more simpler substances (elements or compounds). Equations for decomposition reactions have the form AB( A+B. In a single replacement reaction, one substance in a compound is replaced by another, more active, substance (an element). Equations for single replacement reactions have two general forms. In reactions in which one metal replaces another metal, the general equation is X+YB(XB + Y. In those in which one nonmetal replaces another nonmetal, the general form is X+AY(AX+Y In a double replacement reaction, the metal ions of two different ionic compounds can be though of as replacing one another. Equations for this type of reaction have the general form AB+CD(AD+CB. Most replacement reactions, both single and double, take place in aqueous solutions containing free ions. In a double replacement reaction, one of the products is a precipitate, and insoluble gas, or water. All of the types of reactions discussed here may be represented by balanced molecular equations. Reactions involving ion exchanges may be represented by ionic equations also. In this investigation you will be concerned only with molecular formulas and equations. In a balance equation, the number of atoms of any given element must be the same on both sides of the equation. Multiplying the coefficient and the subscript of an element must yield the same result on both sides of the balanced equation. Purpose: Students will observe seven different chemical reactions, identify the reactants and products of those reactions by both name and formula, and classify the reactions as one of the five basic types of chemical reactions. Students will also practice balancing chemical equations. Materials: Bunsen Burner Wood Splints Micro Spatula Zinc, mossy Crucible Tongs 400ml Beaker (to hold hot test tubes) Striker Evaporating Dish 7 Medium Test Tubes Safety Goggles Test Tube Holder 1M Copper (II) Sulfate, CuSO4 Copper Wire, 10cm Test Tube Rack 0.1M Sodium Phosphate, Na3PO4 Copper (II) Carbonate, CuCO3(s) Magnesium Ribbon, 5cm 1M Sodium Sulfite, Na2SO3 6M Hydrochloric Acid, HCl Procedure: (check off the boxes as you do them!!) 1. Synthesis Reaction Obtain a clean piece of copper wire. Note the appearance. Using crucible tongs, hold the wire in the hottest part of a burner flame for 1minute.  Examine the wire and record any change in its appearance. 2. Synthesis Reaction Place an evaporating dish near the base of the burner.  Examine a piece of magnesium ribbon. Using crucible tongs, hold the sample in the burner flame until the magnesium starts to burn. DO NOT LOOK DIRECTLY AT THE FLAME. HOLD THE BURNING MAGNESIUM AWAY FROM YOU AND DIRECTLY OVER THE EVAPORATING DISH. When the ribbon stops burning, put the remains in the evaporating dish. Examine this product carefully. 3. Decomposition Reaction Place 1 micro spatula of copper (II) carbonate (CuCO3) in a clean, dry test tube. Dont let it clump in the bottom! Note the appearance of the sample. HOLD TESTUBE AT AN ANGLE AWAY FROM EVERYONE. Using a test tube holder, heat the CuCO3 strongly for about 1 minute. Insert a burning wood splint into the gas at the top of the test tube. Do NOT drop the splint into the solid CuCO3. .  Note any change in the appearance of the residue as well as the results of putting the burning wood splint into the gas. 4. Single Displacement (Replacement) Reaction Add about 3 mL (squirts) of 6M hydrochloric acid (HCl) to a test tube. CAUTION, Handle acids with care. They can cause painful burns. Do not inhale any HCl fumes. While holding the test tube with a test tube holder, carefully drop a small piece of zinc metal (Zn) into the acid. Record your observations. Invert a second test tube over the mouth of the test tube in which the reaction is taking place. Remove the inverted tube after about 30 seconds without flipping it over and quickly insert a burning wood splint into the mouth of the inverted test tube. Hold on tight to the test tube.  Note the appearance of the substance in the reaction test tube as well as the results of putting the burning wood splint into the inverted test tube containing the gas. 5. Single Displacement (Replacement) Reaction Place a small amount of zinc metal in a test tube. Add just enough of the 1M copper (II) sulfate CuSO4 to cover the metal . Wait about five minutes. LOOK at the solution and the zinc before and after the reaction. 6. Double Displacement (Replacement) Reaction Add about 1 mL (squirt) of 0.1M zinc acetate (Zn (C2H3O2)2) to a clean, dry test tube. Next, add about 1 mL (squirt) of 0.1M sodium phosphate (Na3PO4) solution to the test tube. Observe what happens and note any changes in the mixture. 7. Double Displacement (Replacement) Reaction Add about 5mL (squirts) of 1M sodium sulfite (Na2SO3) solution to a clean, dry test tube. To this solution, add about 1mL (squirt) of 6M HCl. Wait about five minutes.  Note the odor given off by wafting some of the gas toward your nose. DO NOT SMELL THE GAS DIRECTLY. Types of Chemical Reactions Purpose____________________________________________________________________________________________________________________________________________________________________________ Pre-lab Equations Balance the equations, 2) Name the reactants & products, 3) Determine the type of reaction Part A 1. _____ Cu(s) + _____ O2(g) ! _____ CuO (s) ________________________ 2. _____ Mg (s) + _____ O2(g) ! _____ MgO (s) ________________________ Part B 3. _____ CuCO3 (s) ! _____ CuO (s) + _____ CO2(g) ________________________ Part C 4. _____ Zn (s) + _____ HCl(aq) ! ______ ZnCl2(aq) + _____H2(g) ________________________ 5. _____ Zn(s) + ______ CuSO4 (aq) ! _____ZnSO4 (aq) + _____ Cu (s) ________________________ Part D 6. _____Zn(C2H3O2)2 (aq) + _____Na3PO4 (aq) ! _____ NaC2H3O2 (aq) + ______Zn3(PO4)2(s) _________________ 7. _____ Na2SO3 (aq) + _____ HCl (aq) ! _____ NaCl (aq) + _____ H2O (l) + _____ SO2 (g) __________________ Observations and Data: SampleBefore reactionAfter reactionA. Synthesis1. Cu2. MgB. Decomposition3. CuCO3C. Single Replacement4. Zn + HCl5. Zn + CuSO4D. Double Replacement6. Zn(C2 H3 O2 )2 + Na 3PO47. Na2 SO4 + HCl Analysis Questions 1. If you measured the mass of magnesium before and after the reaction in part A how would the two masses relate? Why? 2. How do you know that there is one zinc atom in a molecule of zinc acetate and three zinc atoms in a molecule of zinc phosphate? 3. What happen in reaction #7 in part D? How could you classify this as more than one type of reaction! 4. 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Pn_/1q i|+bS$\LXF}KHy7 d                fT        2        &        hz        VP        V        ݨ        VF        +$J$Y70;k3CRoQ1RaBg`jrjS;n^HGPkO\$ImmZhF]J2$+]u9;k"m"@| !k"`@` `"`$`L@`(`*`d`@`@Unknown G*Ax Times New Roman5Symbol3. *Cx Arial7@Cambria;WingdingsCNComic Sans MS5. .[`)TahomaABook Antiqua?= *Cx Courier NewA$BCambria Math"qh1rbgXrbgIg#H>#H>24Z"Z"3qHP ?$2! xx Types of Chemical Reactions Tiffany Sejut Windows User4         Oh+'0L , L X d p|Types of Chemical ReactionsTiffany Sejut Normal.dotmWindows User5Microsoft Office Word@NZ@65*@fK@#HG,KVT$m  %  !1.@Cambria---@Cambria------ 42 D00 Types of Chemical Reactions       /2 DF0  --- O2 D-0 Chemist: _________________________Per: ______  ---  2 D0   @Cambria---  2 W00    2 j0 0 Background:     2 j0   @Cambria--- 2 }``0 There are many kinds of chemical reactions and several ways to classify them. One useful method                    V2 020 classifies reactions into four major types. These          R2 w/0 are: (1) direct combination, or synthesis; (2)            2 0i0 decomposition, or analysis; (3) single replacement; and (4) exchange of ions, or double replacement. Not                        z2 0J0 all reactions can be put into one of these categories. Many, however, can.                2 0     2 00  0 52 `0 In a synthesis reaction, two       2 0   m2 A0 or more substance (elements or compounds) combine to form a more               @Wingdings------ 2 0N0 complex substance. Equations for synthesis reactions have the general form A+B               ---  2 U0 ---  2 e0   2 h0 AB.   2 0     2 00  0 2 `_0 A decomposition reaction is the opposite of a synthesis reaction. In decomposition, a compound                  2 0 0 breaks dow   2 M0 n into two or more simpler substances (elements or compounds). Equations for                 --- G2 0(0 decomposition reactions have the form AB         ---  2 S0 ---  2 c0   2 f0 A+B.   2 0     2 %00  0 2 %`[0 In a single replacement reaction, one substance in a compound is replaced by another, more                    G2 80(0 active, substance (an element). Equation        h2 8D>0 s for single replacement reactions have two general forms. In              --- 2 K0Q0 reactions in which one metal replaces another metal, the general equation is X+YB               ---  2 K`0 --- )2 Kp0 XB + Y. In those in       --- t2 ^0F0 which one nonmetal replaces another nonmetal, the general form is X+AY             ---  2 ^&0 --- 2 ^60 AX+Y   2 ^[0     2 p00  0 "2 p`0 In a double rep    2 pQ0 lacement reaction, the metal ions of two different ionic compounds can be though                  --- 2 0^0 of as replacing one another. Equations for this type of reaction have the general form AB+CD                   ---  2 0 --- 2 0 AD+CB.   y2 0I0 Most replacement reactions, both single and double, take place in aqueous                2 +0   ;2 . 0 solutions containing free ions.          2 0d0 In a double replacement reaction, one of the products is a precipitate, and insoluble gas, or water.                     2 0     2 00  0 2 `a0 All of the types of reactions discussed here may be represented by balanced molecular equations.                         /2 00 Reactions involving ion       2 P0 exchanges may be represented by ionic equations also. In this investigation you                    2 0c0 will be concerned only with molecular formulas and equations. In a balance equation, the number of                         2 0M0 atoms of any given element must be the same on both sides of the equation. Mu                    22 L0 ltiplying the coefficient        2 0d0 and the subscript of an element must yield the same result on both sides of the balanced equation.                           2 0     2 00   --- 2 ,00 Purpose:    2 ,q0  --- 2 ,ua0 Students will observe seven different chemical reactions, identify the reactants and products of                     ,2 ?00 those reactions by bot     2 ?Q0 h name and formula, and classify the reactions as one of the five basic types of                 2 Q0M0 chemical reactions. Students will also practice balancing chemical equations.                 2 Q:0     2 d00   --- 2 w0 0 Materials:     2 w~0  --- 2 w0 Bunsen   2 w0 Burner    2 w0  '  2 w 0  0 2 wP 0 Wood Splints     2 w0    2 w0  0 2 w 0 Micro Spatula      2 w>0   2 w@ 0   2 wn 0 Zinc, mossy   ---  2 w0   ---  2 0 Crucible Tongs      2 0  *  2  0  0  2 P0  0 C2 %0 400ml Beaker (to hold hot test tubes)        2 0    2 0   2 0 Striker  2 0    #2 0 Evaporating Dish       2 0    2  0  0 (2 P0 7 Medium Test Tubes        2 0  -  2 0  0  2 @0  0  2 p0  0 2 0 Safety   2 `0 Goggles   2 0   @Cambria--------- #2 0 Test Tube Holder      2 0    2  0  0 52 P0 1M Copper (II) Sulfate, CuSO     ---  2 0 4---  2 0  '  2 @0  0  2 p0  0 2  0 Copper Wire,   2 `0 10cm    2 0     2 0 Test Tube Rack     2 0  '  2  0  0  2 P0  0  2 0   --- 12 0 0.1M Sodium Phosphate, Na       ---  2 O0 3--- 2 U0 PO ---  2 h0 4---  2 n0  --- 42 0 Copper (II) Carbonate, CuCO    --- 2 B0 3(s)---  2 U0  ---  2 p0   --- 2 0 Ma  (2 0 gnesium Ribbon, 5cm        2 80    2 P0  0 +2 0 1M Sodium Sulfite, Na     ---  2 0 2--- 2 0 SO ---  2 .0 3---  2 40  --- 12 @0 6M Hydrochloric Acid, HCl           2 0     2 0  0  2 0   --- 2 30 0 Procedure:     2 30   D2 3&0 (check off the boxes as you do them!!)           2 30   ---  2 E00    2 X00 1.  2 X@ 0 Synthesis    2 X0 Reaction    2 X0    2 X0  @Cambria---- @ !Y0- @Times New Roman---@"Arial- - - --- 2 k`0 a.- - -   2 kk0  --- a2 kx90 Obtain a clean piece of copper wire. Note the appearance.             2 k0    0'--- 2 ~`0 b.- - -   2 ~l0  --- P2 ~x.0 Using crucible tongs, hold the wire in the hot             2 ~0 tes =2 ~!0 t part of a burner flame for 1min         2 ~0 ute   2 ~0 .  2 ~0    0'--- 2 `0 c.- - -   2 k0  ---  2 x0   42 |0 Examine the wire and record          2 C0   "2 F0 any change in i      2 0 ts appearance.    2 0    0'  2 00     2 00     2 00     2 00   -- $K`Kr\r\`K`- -- - $K`Kr\r\`- - '-- $KqK\\qKq- -- - $KqK\\q- - '-- $KK\\K- -- - $KK\\- - '"Systemvཕ vv@P - -   00//..՜.+,0 hp  LCCHS>Z" Types of Chemical Reactions Title  !"#$%&'()*+,-./012345679:;<=>?ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_`abcefghijklmnopqrstuvwxyz{|}~Root Entry FPUData 81Table@GWordDocument4nSummaryInformation(dMDocumentSummaryInformation8CompObjr  F Microsoft Word 97-2003 Document MSWordDocWord.Document.89q