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Experiment 1 ________________________________________________________________________ Title: Investigating the Properties of Period 3 Oxides Aim: To examine the oxides of Period 3 elements and describe their structure and bonding. Introduction: Generally, there are oxides of metals and non-metals. Metals burn in oxygen to form basic oxides while non-metals form acidic oxides. Structurally, they are covalent or ionic compounds. You are to do some simple observations and tests, to find out the differences between the types of oxides provided and to account for these differences. Apparatus: Test tubes Measuring cylinders Wooden splinter
Test tube rack Thermometer Glass rod
Materials: Sodium peroxide Silicon (IV) oxide Universal indicator solution
Magnesium oxide Phosphorus pentoxide Litmus paper
Safety measurements: Safety spectacle **Warning: Phosphorus (V) oxide is corrosive and irritates eyes, skin and lungs. Sodium peroxide is also corrosive and a powerful oxidant. Procedure: Part A: Appearance: Examine your oxide samples, and in Table 1, note for the physical states at room temperature: (a) whether it is solid, liquid or gas, (b) its color (if any) Part B: On mixing with water: 1. Set up 4 test tubes, side by side. 3 2. Into each test tube pour about 5 cm of distilled water. 3. In the test tube, place a thermometer. a. Note the temperature. b. Add half a spatula-tip of sodium peroxide and stir carefully with the glass rod. c. Note after one minute, (i) the temperature, (ii) whether the solid has dissolved and (iii) anything else you see. For example, is gas evolved at any time? If so, is the gas acidic? Can you identify it using a simple test? Lab manual version 4.1 Foundation in Science
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d. Add 2 -4 drops of universal indicator solution, compare the color with the chart provided, and note the pH indicated or use a piece of pH paper. 4. Repeat the above steps 3 (a) – (d), using, in turn, magnesium oxide, silicon (IV) oxide and phosphorus (V) oxide. 5. Measure the pH of the water in the fifth test tube by adding 2-4 drops of universal indicator solution for comparison with the above. Results:
Table 1 Na2O2
MgO
SiO2
P4O10
Appearance Initial temperature/ºC Final temperature/ºC Solubility pH of solution
Other observation(s)
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Questions: 1. Use your experimental results and your test books (if necessary) to complete a larger copy of Table 2.
Table 2 Formula of oxide
Na2O2
MgO
Al2O3
SiO2
P4O10
Cl2O
o
Melting-point/ C o
Boiling-point/ C State at s.t.p. Action of water pH of solution
aqueous
Acid/base nature Conductivity liquid Solubility hexane Structure
of in
Bonding
2. Write equations for any reactions which took place when you add the oxides to water. 3. Comment on the change in structure and bonding in the oxides of the elements in the period between sodium and chlorine. 4. How does the acid-base nature of the oxides of the elements in Period 3 change with increasing atomic number? 5. Can you relate this change in structure and bonding that take place along the period?
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Experiment 2 ________________________________________________________________________ Title: The Solubility of Some Salts of Group II Elements Aim: To study the solubility of the sulphates, sulphites and hydroxides of Group II elements. Introduction: 3 In this experiment, you add each of the anion solutions to 1 cm of each cation solution provided, drop by drop, until the first sign of a precipitate appears. For each salt, the solubility is proportional to the number of drops of anion added. Apparatus: Test tubes Graduated pipette Beaker (50ml)
Test tubes racks Pasteur pipette
Materials: 2+ 2+ 2+ 0.1 M solution of the following cations: Mg , Ca , Ba 1.0 M solution of OH 20.5 M solution of SO 4 20.5 M solution of SO 3 Procedure: 1. Set up three rows of three test tubes each. st 2+ nd 2+ rd 2+ 2. For each row, label the 1 test tube Mg , the 2 test tube Ca , and 3 test tube Ba . 3 3 3. Add 1 cm of the appropriate cation solution to each test tube by using a 1 cm graduated pipette. 4. To each test tube in the first row, add OH solution drop by drop and shake until the first sign of precipitate appears. 5. Record the number of drops of OH solution used in Table 1. 6. If a precipitate is produced, classify the precipitate as slight (s) or heavy (h). + 7. If no precipitate is produced after forty drops, then write ‘40 ’ and assign the salt as soluble. 22nd rd 8. Repeat steps 4 to 7 by replacing OH with SO4 and SO3 to the 2 and 3 rows of test tubes respectively.
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Results:
Table 1 Cation Solution Mg
Number of drops of anion solution added to form a precipitate -
OH
SO3
-
SO4
-
+
Ca
+
Ba
+
Questions: 1. For Group II, what are the solubility trends of the salts listed below: (a) Hydroxides (b) Sulphites (c) Sulphates
2. Explain your answer for (1). 3. Use Table 2 to answer the following questions. Table 2: Solubility of Group II compound in water at 298 K Singly-charged anions Doubly-charged anions Solubility Solubility Compound /mol per 100 100 g Compound /mol per 100g 100g of water of water MgCl2 5.6 x 10 MgCO3 1.8 x 10 -1 -4 CaCl2 5.4 x 10 CaCO3 0.13 x 10 -1 -4 SrCl2 3.5 x 10 SrCO3 0.07 x 10 -1 -4 BaCl2 1.5 x 10 BaCO3 0.09 x 10 -1 -4 Mg (NO3)2 4.9 x 10 MgSO4 3600 x 10 -1 -4 Ca (NO3)2 6.2 x 10 CaSO4 11 x 10 -1 -4 Sr (NO3)2 1.6 x 10 SrSO4 0.62 x 10 -1 -4 Ba (NO3)2 0.4 x 10 BaSO4 0.009 x 10 -4 Mg (OH)2 0.020 x 10 MgCrO4 8500 x 10 Ca(OH)2 1.5 x 10 CaCrO4 870 x 10 -4 Sr (OH)2 3.4 x 10 SrCrO4 5.9 x 10 -4 Ba (OH)2 15 x 10 BaCrO4 0.011 x 10 (a) Identify the group trends in solubility for each type of salt listed in Table 2. (b) Does the solubility listed above for carbonates, sulphates and hydroxides match with your findings in this experiment. If no, why? (c) Which anions give more soluble compounds, singly-charged or doubly-charged anions? Lab manual version 4.1 Foundation in Science
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Experiment 3 ________________________________________________________________________ Title: Investigating the Properties of Aluminium and Its Compounds Aim: To investigate the properties of aluminium and its compounds. Introduction: Aluminium is the most abundant metal in the earth’s surface (7.5% by mass). The abundance of Al, coupled with its attractive combination of physical and chemical properties, accounts for the fact that it is one of the principal industrial raw materials used by industrialized societies.
Aluminium has more metallic character compared to boron, which is in the same group in the Periodic Table. It forms trivalent compounds due to the 3 electrons in its valence shell. Generally, aluminium compounds are ionic in nature but many compounds of aluminium show both ionic and covalent character. In this experiment, we will investigate the properties of aluminium and some of its salts. Apparatus: Test tube Beaker Bunsen burner Materials: Aluminium strips Aluminium foil Sand paper Diluted hydrochloric acid Diluted nitric acid Diluted ammonium hydroxide Concentrated sodium hydroxide
Glass dropper Watch glass Glass rod
Filter paper Litmus paper Diluted sodium hydroxide 20% aluminium sulphate Diluted sulphuric acid Distilled water
Safety Precaution Steps: Wear safety goggles. Wear gloves when using concentrated acid and base. Procedure: Part A: Reaction with air 1. Heat a small piece of aluminium foil using a bunsen burner. State the observation. Part B: Reaction with acids 1. Put three small pieces of aluminium (clean with sand paper) into three separate test 3 tubes, each containing 5 cm of diluted hydrochloric acid, diluted nitric acid and diluted sulphuric acid respectively. 2. Heat the solutions when necessary. Which acid reacts faster with aluminium? Lab manual version 4.1 Foundation in Science
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Part C: Reactions with alkali 3 1. Add 5 cm of concentrated sodium hydroxide solution into a test tube containing a piece of aluminium. 2. Identify the gas released. Part D: Aluminium hydroxide and aluminium sulphate 3 1. Fill in about 10 cm of 20% aluminium sulphate solution into a small beaker, and then 3 add 10 cm of diluted ammonium hydroxide solution. 2. Boil the mixture and filter it. Wash the aluminium hydroxide collected on the filter paper with water. 3. Transfer a portion of the aluminium hydroxide prepared in step (2) on to a watch glass. Using a glass dropper, add 6 drops of diluted hydrochloric acid. 4. Put a small amount of aluminium hydroxide from step (2) into a test tube. Add four drops of sodium hydroxide solution, one drop at a time. Shake the test tube after adding each drop and observe carefully for the appearance and disappearance of any precipitate. 5. Test the pH of a small amount of aluminium sulphate solution using litmus paper and record your observations. 3 6. Pour 5 cm of aluminium sulphate solution into a small beaker and add drop wise sodium hydroxide solution slowly with stirring. Observe the reaction when excess sodium hydroxide is added to the mixture. Results: Experiment A. Reaction with air
Observation
B. Reaction with acids C. Reaction with alkali D. Aluminium hydroxide and aluminium sulphate
Question: 1. Write down all the chemical equations involved in this experiment.
2. Why must we use clean aluminium foil for this experiment?
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Experiment 4 ________________________________________________________________________ Title: The Synthesis of Potassium Aluminium Sulfate (Alum) Aim(s): To prepare common aluminium complexes, alum, KAl(SO 4)2.12H2O. Introduction: Aluminium occurs naturally as mineral bauxite (primarily a mixture of Al 2O3.3H2O, Fe2O3 and SiO2), and it is purified in the following process: Step 1: Purification of raw materials Bauxite is firstly mined, crushed and then washed to remove water soluble impurities. The remaining material is then dissolved in NaOH and heated up. Al 2O3 is selectively dissolved due to its properties of amphoteric oxide. The reaction is shown as below.
Al2O3 + 6NaOH + 3 H2O
2Na3Al(OH)6
→
However, some of the crystalline forms of SiO 2 can also be dissolved under the same reaction. The equation is given as below. SiO2 + 4NaOH
Na4SiO4 +2H2O
→
Both of these species are soluble, but Fe 2O3 is a basic oxide and hence it is insoluble in NaOH solution and can be filtered out. Over time the Na 3Al(OH)6 decomposes to Al(OH)3 (an insoluble species), which can also be filtered out. Na3Al(OH)6 + 2H2O
3NaOH + Al(OH)3 .2H2O
→
This is then decomposed by heating to temperatures above 1000 °C to give alumina, Al2O3. Al(OH)3 .2H2O
Al2O3 + 9 H2O
→
Step 2: Reduction of the alumina The resultant alumina (Al 2O3 ) is dissolved in molten cryolite (Na 3AlF6), forming an ionic and electrically conductive solution. This is decomposed by electrolysis later by using a consumable carbon as anode with two concurrent reactions proceeding according to the following equations:
Al2O3 + 3C 2Al + 3CO 2 Al2O3 + 3C 4Al + 3CO2 →
→
The use of consumable carbon anode lowers the required voltage by 1.0 V at the operating temperature of 950-980 °C. Lab manual version 4.1 Foundation in Science
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Figure 1: Electrolysis process on extracting aluminium.
The environmental impact on extracting aluminium from its natural source (bauxite) is quite high. Yet, the need for aluminium continues to grow due to its attractive properties. Recycling aluminium products is one of the alternatives on saving environmental cost due to its highly cost from the extraction process. Aluminium recycled from beverage cans only requires 5 percent of energy if compared to the production of aluminium from ores. In the year 2000, it was estimated that nearly 63 billion aluminium cans were recycled in the United States. The commercial recycling of aluminium is a melting or purification process that keeps the aluminium as aluminium metal. However, it needs to dissolve aluminium in hot KOH in this experiment and use the dissolved aluminium to make crystals of potassium aluminium sulphate dodecahydrate, KAl(SO 4)2.12H2O. This compound belongs to a family of metal sulphates called alums. In this experiment, you will be recycling aluminium scrap in a very unusual way, and you will produce two products which are potentially very useful: hydrogen gas (H 2) and very pure potassium aluminium sulphate (KAl(SO 4)2.12H2O or alum). Hydrogen gas has great potential use as fuel, if some of its dangerous properties can be controlled (mixtures of H 2 and air are highly explosive). Hot aqueous hydroxide solution used in this experiment will quickly remove the oxide layer on the aluminium surface and then dissolve the 3+ 3+ aluminium metal by converting aluminium atoms to Al . There are a number of Al + species formed in an aqueous environment, depending on the abundances of OH and H ions (the pH of the solution). Adding the H 2SO4 to the mixture can lead to the desired KAl(SO4)2.12H2O alum product. Apparatus and Equipments: Beaker, 250ml Butchner funnel Filtration flask Filter paper Ice bath
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Measuring cylinder Pasteur pipette Sandpaper Glass rod
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Materials: Aluminium beverage can Boiling chips Distilled water Ethanol 2 M Potassium hydroxide, KOH 9 M Sulphuric acid, H 2SO4 Safety measurements: Protective glove Safety spectacle Hydrogen gas produced is very explosive. e xplosive. Therefore, you MUST: ENSURE THAT YOU ONLY HEAT THE BOTTOM OF THE BEAKER AND NOT LETTING THE FLAME GET NEAR THE TOP. Concentrated sulphuric acid is very corrosive and reacts vigorously with water. Therefore, you MUST: WEAR GLOVES AND SAFETY SPECTACLES. DISPOSE UNWANTED ACID BY COOLING AND POURING SLOWLY INTO AN EXCESS OF WATER. Ethanol is very flammable. Therefore, you MUST: KEEP THE BOTTLE CLOSED ALWAYS. KEEP THE BOTTLE AWAY FROM FLAMES. WEAR SAFETY SPECTACLES. Potassium hydroxide is very harmful if swallowed and causes severe burns. Therefore, you MUST: WEAR APPROPIATE PROTECTIVE CLOTHING.
Procedure: Part A: Dissolution of the aluminium 2 1. Cut about 2 x 5 cm of aluminium strip from aluminium can provided. Scrap off thoroughly any paint and/or plastic coating from both sides by using a piece of sandpaper. 3 2. Weigh out approximately 1.0 g of the scrap aluminium strip into a 250 cm beaker. Record the mass. 3. Cut the weighted aluminium strip into small pieces and place the pieces in a clean 3 beaker, followed by the addition of 50 cm of 2 M KOH into the beaker. Perform this operation in the fume hood. 4. Heat the mixture very gently on a hot plate if the reaction is proceeding too slowly.
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5. Bubbles should form from the reaction between aluminium and aqueous potassium 3 hydroxide. Add distilled water to maintain the volume at approximately 25 cm (if the liquid level in the beaker drops to less than half of its original volume). The reaction is complete when the gas evolution ceases and without any trace of aluminium pieces. 6. Vacuum filter the solution (if the solution contains any remaining solid). Use a small 3 amount of water (not more than 200 cm ) to rinse the beaker and funnel. 7. Allow the filtrate to cool down to room temperature. -
Part B: Formation of Al(OH)3 and removal of OH 3 1. Transfer 20 cm of 9 M H2SO4 to the filtrate. 3 2. Add 20 cm of 9 M H2SO4 drop wise to the filtrate slowly and with stirring. 3. White precipitate will form upon the addition of sulphuric acid and will dissolve when excess of sulphuric acid is added into the beaker. (Note: There may be a small amount of undissolved white precipitate. Add 2 or 3 boiling chips (if necessary) and heat the solution gently until the solution becomes clear.) Part C: Precipitation of alum crystals 1. Prepare a half-full ice bath and add water until the bowl is three quarters full. 2. Cool the solution in Part B to room temperature and then place the beaker in the ice bath. Crystals of alum should form. Allow it to cool for 15 minutes. 3 3. Vacuum filter the product and wash with 10– 20 cm of ethanol/water solution (1:1). 4. Allow the product to dry for a few minutes, remove the boiling chips and record the weigh. 5. Calculate the percentage yield of alum obtained. Results: Part A: Observation(s)
Table 1: Observation(s) for each part of experiment Observation(s)
(A) Dissolving the aluminium
(B) Formation of Al(OH) 3
(C) Precipitating alum crystals
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Part B: Calculation Table 2: Mass of aluminium Mass of empty beaker (g) Mass of beaker + aluminium strips (g) Mass of aluminium strips used (g) Table3: Mass of alum Mass of filter paper (g) Mass of filter paper + alum (g) Mass of alum (g)
Questions: 1. Identify the gas released during the reaction of aluminium beverage can and potassium hydroxide.
2. What is the white precipitate formed during the addition of concentrated sulphuric acid? Write down the balanced equation that involved. 3. Why the white precipitate disappears when excess of sulphuric acid is added? Write down the balanced equation that involved. 4. Write down the complete balanced equation of aluminium hydroxide, Al(OH) 3, to form alum, KAl(SO4)2.12H2O. 5. What is the theoretical yield of alum, in grams, obtained from the experiment? 6. What is the percentage yield of alum obtained from the experiment?
Percentage yield =
actual yield ( g ) theoretical yield ( g )
×
100 %
7. List out several common usages of aluminium.
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Experiment 5 ________________________________________________________________________ Title: Reaction of Tin and its Common Ions Aim: To shows the reactions of tin with acids and to carry out some of the common reactions 2+ of Sn (aq). Introduction: In this experiment you will find out if the metallic character of tin is evident from its reactions with acids. You treat the elements with two acids: an oxidizing agent (nitric acid) and a non-oxidizing acid (hydrochloric acid). In each case you attempt to identify any gases evolved. The reactions of the divalent ions are included here to demonstrate the relative stability of the +2 state in tin. Apparatus: Test tubes Bunsen burner Asbestos sheet Graduated pipette
Test tube rack Test tube holder/ clamp Beaker wooden splinter
Materials: Diluted hydrochloric acid (2 M) Concentrated hydrochloric acid Concentrated nitric acid 2 M NaOH solution 2.0 M ammonia solution 0.1 M K2CrO4 0.02 M Na2S solution 0.1 M KI solution 2+ Tin (small pieces/granule) 0.1 M solution of Sn ions (in diluted HCl acid) 0.01 M KMnO4 (in diluted ethanoic acid) Safety measurement: Safety spectacles **Warning: Sodium sulphide is toxic and corrosive and evolves highly poisonous hydrogen sulphide gas on contact with acids. Concentrated hydrochloric acid is very corrosive. Concentrated nitric acid is very corrosive and a powerful oxidant.
WEAR PROTECTIVE GLOVES AND SAFETY USE SODIUM SULPHIDE IN THE FUME-CUPBOARD .
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Procedure: 1. Place a small piece of tin in each of three test tubes. 3 2. To one test tube add about 2 cm of diluted hydrochloric acid and heat gently. 3 Can you see or detect a gas? If not, repeat the experiment carefully using about 2 cm of concentrated hydrochloric acid. 3 3. In the remaining test tube add about 2 cm of concentrated nitric acid to the tin and heat gently. 4. Record your results in a larger copy of Table 1. 3 2+ 5. Add approximately 2 cm of the Sn solution to each of seven test tubes. 2+ 6. Add each of the following reagents to Sn : (a) Diluted sodium hydroxide solution, initially drop-by-drop, and then to excess; (b) Ammonia solution, initially drop-by-drop, and then to excess; 3 (c) About 2 cm of diluted hydrochloric acid, heat the mixtures and then cool them under running cold water; 3 (d) About 2 cm of acidified potassium manganate (VII) solution; 3 (e) About 1 cm of potassium chromate (VI) solution; (f) 5 drops of sodium sulphide solution (do this in the fume-cupboard and dispose of the mixture by pouring into the fume-cupboard sink); 3 (g) About 2 cm of aqueous potassium iodide. 7. Record your observations in a larger copy of results Table 2. Result:
Table 1: Reaction of Tin granules with acids: Acid Observations Diluted hydrochloric acid Concentrated hydrochloric acid Concentrated nitric acid 2+
Table 2: Reaction of acidified Sn (aq) with other reagents: Reagent
Observations
a) Sodium hydroxide solution b) Ammonia solution c) Diluted hydrochloric acid d) Acidified potassium manganate (VII) solution e) Potassium chromate (VI) f) Sodium sulphide solution g) Potassium iodide solution Lab manual version 4.1 Foundation in Science
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Questions: 1. Complete the following equations:
Sn(s) + HCl(aq.)
→
2. Are the reactions between the elements and hydrochloric acid typical of metals? Explain your answer. 3. Reactions with nitric acid tend to be complex and equations are not generally required. The questions illustrate some general points. (a) Which gas did you detect when nitric acid reacted with tin? (b) Do other metals behave in similar way with nitric acid? Give one example. (c) Why does nitric acid behave differently from hydrochloric acid? 4. Use your text-book(s) to complete and balance the equations in Table 3. In the comments column you should describe the type of chemical reaction occurring and any other important feature(s). Table 3: Equations
Comments
2+
-
Sn (aq) + OH (aq) Sn (OH)2 (s) + OH (aq) -
The precipitate dissolves in excess NaOH 2 4to form a stannate (II) ion , Sn (OH)6
→ →
+
2+
2MnO4 (aq) + 16H (aq) + 5Sn (aq) 2-
+
2+
Cr2O7 (aq)** + H (aq) + Sn (aq) 2+
2-
Sn (aq) + S (aq)
→
→
→
Various formulae have been proposed for the stannate (II) ion ranging from SnO 22- for the anhydrous form to Sn(OH) 42- and Sn(OH)64- for the hydrated forms. Sn(OH)64- seems the most probable. ** Chromate (VI) (CrO42-) changes to dichromate (VI) (Cr 2O72-) when acidified [2CrO42-(aq) + 2H + (aq) Cr2O72-(aq) + H2O (1)] *
→
5. In the experiment, potassium manganate (VII) solution was acidified with diluted ethanoic acid and hot, as is usual, diluted hydrochloric acid or diluted sulphuric acid. With the aid of your text-book (s), explain why you think this change was made. Give any relevant equations in your answer and state what you would observe if the MnO 4 solution were acidified with HCl (aq) or H 2SO4 (aq). 6. Predict the reaction between aqueous tin (II) ions and a solution of mercury (II) chloride. What do you think you would observe in this reaction?
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Experiment 6 ________________________________________________________________________ Title: Investigation of thermal stability of nitrates Aim(s): To identify the products of thermal decomposition of s-block nitrates. To predict the order of thermal stability of these compounds. Introduction: This experiment attempts to test the effect of heat on the solid nitrates of Groups I and II. You are to heat small samples of the nitrate of each element, using the same size flame. Take note the time taken to detect the product of decomposition. Refer to standard textbook for the common tests for nitrogen dioxide (brown gas), produced from nitrates. Apparatus: Boiling tubes Test tubes Stop-watch Bunsen burner
L-shaped delivery tube with bung (boiling tube) Test tube rack Wooden splinter Boiling tube holder/ clamp
Materials: Solid nitrates (anhydrous) of Groups I and II Lime water (saturated calcium hydroxide solution) 2 M hydrochloric acid (diluted) **Warning: Nitrogen dioxide gas is poisonous. Heat nitrates in a fume cupboard. Nitrates are strong oxidizing agents. DO NOT ALLOW PIECES OF GLOWING SPLINT TO DROP ON TO HOT NITRATES.
Procedure: Effect of Heat on Nitrates: 1. Set up two rows of boiling tubes. First row with 2 boiling tubes and second row with 4 boiling tubes. Add a spatula-measured of the nitrates as stated in Table 1. 2. Start the stop-watch at the moment you begin heating the first nitrate by holding the end of the boling tube just above the blue cone of a roaring Bunsen flame. 3. Test for oxygen at short regular intervals (place the glowing splinter in the same part of the boling tube) and also look for the first sign of a brown gas. (A white background is helpful) 4. In Table 1, record the time for the first appearance of brown fumes or when oxygen is detected. (Whichever method of detection you choose for one member of a group you must also apply to the other members of the same group) Continue heating for Lab manual version 4.1 Foundation in Science
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another minute after gas is detected. 5. Repeat steps 2, 3 and 4 for the other nitrates in turn. 6. To the cold solid residue remaining after each nitrate is heated, add a few drops of diluted hydrochloric acid and warm. Table 1: Effect of Heat on s-Block Nitrates Nitrate
Time to detect Observations O2 /NO2
Effect of adding diluted HCl to cold residue
NaNO3 KNO3 Mg(NO3)2 Ca(NO3)2 Sr(NO3)2 Ba(NO3)2
Questions: 1. Explain why many of these nitrates rapidly turn into colorless liquids on first heating. On further heating, they become white solids again, before they decompose.
2. Describe the trend in thermal stability of the nitrates when going down a group in the periodic table. 3. How does Group I nitrates compare with their Group II counterparts in terms of thermal stability?
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Experiment 7 ________________________________________________________________________ Title: Halogen-Halide Reactions in Aqueous Solution Solu tion Aim: To investigate the order of oxidizing ability of the halogens Cl 2, Br2 and I2 in aqueous solution. Introduction: You mix each of the aqueous solutions with halide ion solutions, C1 (aq), Br (aq), and I (aq) in turn, and see whether a reaction takes place. The addition of hexane to the halogen-halide mixture enables you to recognize the halogen molecules present. The halogen which oxidizes most of the other halide ions will clearly be the strongest oxidizing agent. Apparatus: Test tubes fitted with cork Graduated pipettes
Test tube rack
Materials: Bromine water, Br2 (aq) --------------- Chlorine water, C1 2 (aq) -------------------------------Iodine solution, I 2 in KI (aq) Potassium bromide solution, KBr Potassium chloride solution, KC1 Potassium iodide solution, KI Hexane, C6H14 ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------Safety measurement: Safety spectacle Hazard warning KEEP HEXANE WELL STOPPERED AND AWAY FROM FLAMES Halogen and organic vapors must not be inhaled. THE LABORATORY MUST BE WELL VENTILATED AND REAGENT BOTTLES AND TEST TUBES STOPPERED AS MUCH AS POSSIBLE. Procedure: 1. Reaction (if any) of iodide with chlorine and bromine: 3 (a) To each of two test tubes add about about 1 cm of potassium iodide solution. (b) To one of those tubes, add about the same volume of chlorine water, and to the other add the same volume of bromine water. (c) Cork and shake the tubes and note the colour change (if any). 3 (d) To each tube add about 1 cm of hexane. Cork and shake, allow it to settle. Note the colour of each layer. (e) Decide which reactions have taken place, and complete Table 1. 2. Reaction (if any) of bromide with chlorine and iodine. Repeat the above steps, 1 (a) – (e), using potassium bromide with chlorine water and Lab manual version 4.1 Foundation in Science
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iodine solution. 3. Reaction (if any) of chloride with bromine and iodine Repeat steps 1 (a) – (e) using potassium chloride with bromine water and iodine solution. Results:
Table 1 Chlorine water
Bromine water
Iodine solution
Initial colour
Colour after shaking with KI solution Colour of each layer 1. after shaking with hexane
Upper Lower
Conclusion Colour after shaking with KBr solution Colour of each layer 2. after shaking with hexane
Upper Lower
Conclusion Colour after shaking with KCl solution Colour of each layer 3. after shaking with hexane
Upper Lower
Conclusion Questions: 1. From the results: – – (a) Does I2 (aq KI) oxidize Cl (aq) and Br (aq)? – (b) Does Br2 (aq) oxidize Cl (aq) and I (aq)? – – (c) Does Cl2 (aq) oxidize Br (aq) and I (aq)?
2. Explain your your answer for question (1).
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3. State the purpose of using hexane in this experiment. 4. Write ionic equations for the reactions that have taken place.
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Experiment 8 ________________________________________________________________________ Title: Reaction of Halides in Solution Aim: To find out whether the ions, Cl , Br and I , react in solution with certain reagents and identify the products formed in the reactions. Introduction: In this experiment, you will add various reagents to separate samples of solutions containing the Cl , Br and I ions. In many of the reactions, precipitates are formed. Where you are asked to add another reagent to excess, you should look carefully to see if any of the precipitate dissolves. Apparatus: 15 test tubes with corks Pasteur pipettes Materials: Potassium bromide solution, KBr Potassium iodine solution, KI Diluted nitric acid, HNO 3 Hydrogen peroxide solution, H 2O2
Test tube racks
Potassium chloride solution, KCl Silver nitrate solution, AgNO 3 Ammonia solution, NH 3 Diluted sulphuric acid, H 2SO4
Procedure: 3 Add the following reagents to 1 cm of the chloride, bromide and iodide solutions in turn, and record your observations in Table 1. 3 1. Add approximately 1 cm of silver nitrate solution and shake gently. State the observation. Move the three test tubes to a dark cupboard and leave them there till the end of the lesson and note their appearance again. 2. Add silver nitrate solution as in (1). Leave these test tubes in their racks until the end of the lesson, noting their appearance every 10-15 minutes. 3 3 3. Add approximately 1 cm of silver nitrate solution followed by excess (e.g. 5 cm ) diluted nitric acid. Cork the test–tubes and shake vigorously. 3 3 4. Add approximately 1 cm of silver nitrate solution followed by excess (e.g. 5cm ) ammonia solution. Cork the test tubes and shake. 3 5. Add approximately 1 cm of hydrogen peroxide solution followed by approximately 1 3 cm of diluted sulphuric acid. Cork these test tubes and allow them to stand. Add any further reagent (s) which you think will help you to decide what has happened.
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Results:
Table 1: Test
Chloride
Bromide
Iodide
Action of AgNO 3 (aq) Effect of standing in (a) dark (b) light Action of AgNO 3(aq) followed by diluted HNO 3 Action of AgNO3 (aq) followed by NH 3 (aq) Action of H 2O2 (aq) and diluted H2SO4 (aq)
Question: 1. Write ionic equations for the reactions between each of the three halide solutions and silver nitrate solution.
2. Suggest chemical tests that can be used to distinguish between: (a) Cl (aq) and Br (aq), (b) Br (aq) and I (aq). 3. Write an ionic equation equation for the reaction between aqueous iodine and acidified hydrogen peroxide. 4. Why do you you think there is no reaction occurs between acidified hydrogen peroxide and the other halide ions? 5. Suggest a reason for the darkening effect of light on the silver chloride and silver bromide precipitates.
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UTAR FHSC1134 Inorganic Chemistry Trimester 3
Experiment 9 ________________________________________________________________________ Title: Complex Formation and Precipitation Aim: To investigate complex formation and precipitation reactions. Introduction: Complex formation and precipitation reactions are the basis of qualitative inorganic analysis. The reactions involve the manipulation of chemical equilibria by either adding specific ions or adjusting their concentrations, in order to cause a precipitate to form or to dissolve. Substances that show conductivities proportional to their concentrations in aqueous solution are classified as strong electrolytes. Strong electrolytes will dissociate completely into ions in aqueous solution. Examples of salts are Li, Na, K, all nitrates, many metallic chloride salts, all hydroxides, HCl, HNO 3, and HClO4. In the present study + + the ions Na , K , and NO3 can be regarded as spectator ions, not taking part in the reactions.
Complex formation Addition of ammonia or sodium hydroxide to aqueous solutions of metal ions will often cause precipitation of the metal hydroxide, eg: 2+ (aq) +
Sn
-
2OH (aq)
Sn(OH)2(s)
However, on addition of excess ammonia, or hydroxide ion, some metal hydroxides dissolve by forming complex ions. Zn(OH)2(s) + 4NH3(aq) -
[Zn(NH3)4]
Sn(OH)2(s) + 3OH (aq) + 3H2O(l) 2+
2+
2+
(aq) +
-
2OH (aq) -
[Sn(H2O)3(OH)3 ](aq)
2+
The metal ions Zn , Cu and Pb form complexes in solution with a coordination number of 4. This means that four ligands are joined to the central metal ion to form 2+ 2+ 2+ complex ion such as [Cu(NH 3)4] . Zn and Pb can also form six-coordinate complexes. Precipitation Reaction Almost all salts of the alkali metals are soluble in water and strong electrolytes, but anions such as phosphate, carbonate or oxalate form insoluble salts with most other cations. Some such precipitates can be made to dissolve by changing the pH or by adding suitable ligands, soluble complexes can be formed whose large formation constant overwhelms the small solubility product of the original salt. Silver halides are insoluble in water. They can be distinguished by the differing actions of dilute and concentrated ammonia solutions, thereby furnishing tests for the presence of halide ions. Lab manual version 4.1 Foundation in Science
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UTAR FHSC1134 Inorganic Chemistry Trimester 3
Apparatus: Test tubes Red litmus paper
Droppers Pipette
Materials: 1 M hydrochloric acid 4 M ammonia solution 2 M sodium hydroxide Zinc nitrate Copper (II) sulphate
Potassium chloride Manganese (II) chloride Magnesium chloride Calcium chloride Trisodium phosphate
Caution: Cleanliness of test tubes is essential. Procedures: Part A: Complex formation 1. Label two test tubes and add 4 M ammonia solution into respective test tubes of 0.5 3 cm of dilute zinc nitrate and copper (II) sulphate solutions drop wise until each is just alkaline alkaline (test with red red litmus paper). paper). 2. Add more ammonia solution, and observe if there is any precipitate dissolves. 3. Repeat step 1 and 2 by using 2 M sodium hydroxide in place of ammonia solution. Part B: Phosphate precipitation reaction 3 1. Label five test tubes and add 1 cm of each solution (potassium chloride, manganese (II) chloride, magnesium chloride, calcium chloride and copper (II) sulphate) into respective test tubes. 3 2. Add 1 cm of trisodium phosphate solution to each of the test tubes and shake. Observe for any precipitation and record in the table. 3. Add a few drops of 1 M HCl to any test tube with precipitate formed and shake. Note: The precipitates are not necessarily phosphates. Some precipitates are due to hydrolysis of the anion in solution. Results: Part A: Complex formation
Observations Limited NH3
Excess NH3
Zn(NO3)2 CuSO4
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UTAR FHSC1134 Inorganic Chemistry Trimester 3
Observations Limited NaOH
Excess NaOH
Zn(NO3)2 CuSO4
Part B: Phosphate precipitation reaction
Observations KCl MnCl2 MgCl2 CaCl2 CuSO4
Questions: 1. Explain briefly each of the reactions involved.
2. Write down appropriate equation(s) to describe your observations.
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UTAR FHSC1134 Inorganic Chemistry Trimester 3
Experiment 10 ________________________________________________________________________ Title: Identification of Unknown Metal Ions Aim: To identify the presence of unknown metal ions in series of solutions. Introduction: Common metallic cations can be separated from one another and identified by using qualitative analysis. During analysis, inferences can be made on the colour, solubility, the effect of heat on the salt, the type of gas given out, reaction with other reagents and confirmatory test. When the unknown cation has been identified, equations should be added to support the conclusions.
Colours of common cation solutions: Colourless Blue + + +, + + Ag , Pb , Ca Ba , Cu 2+ 2+ 2+ Zn , Mg , Cd
Yellow + Fe , Cr
+
Pink + Co , Mn (very pale)
+
Green + Ni , Fe (pale)
+
The cations supplied belong to four main groups: Group 1: Cations whose chlorides are relatively insoluble Group 2: Cations whose sulfates are relatively insoluble Group 3: Cations which form soluble amine complexes in excess ammonia (at a pH of approximately 10) Group 4: Cations which form insoluble metal hydroxides in a solution of excess ammonia at pH10 Apparatus: Test tubes Boiling tubes Water bath
Dropper Centrifuge Centrifuge tubes
Materials: 6 M ammonia solution 6 M hydrochloric acid 6 M sulphuric acid 1 M hydrogen peroxide Universal indicator paper Boiling chips
Silver nitrate, AgNO 3 Barium nitrate, Ba(NO 3)2 Iron (III) nitrate, Fe(NO 3)3 Chromium (III) nitrate, Cr(NO 3)3 Copper (II) nitrate, Cu(NO 3)2 Ethanol
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UTAR FHSC1134 Inorganic Chemistry Trimester 3
Safety Precautions: • Safety glasses must be worn at all times. • Most of the metal ions used are poisonous. Do not throw residues containing metal ions or sulfides down the sink. Containers are provided in the fume cupboards for such residues. • When heating any acid always heat cautiously and do not allow any vigorous reaction to occur. • Do not take the test tubes away from fume hood until the reaction has ceased completely. All test tubes used for tests should be cleaned thoroughly. • Procedures: 1. In a set of 5 clean test tubes, add each of them with 10 drops of one unknown solutions. Label the test tubes A - E. 2. Add 4 drops of 6 M HCl to each test tube. Mix the solutions thoroughly. Record your observations about precipitation (if any) and colors. 3. Follow the flow chart illustrated in the next page for further investigations. investigation s. Notes for Tests: Transferring the solution to boiling tubes is important to prevent loss of solution due • to over rapid boiling off of ethanol. Removal of ethanol is complete when vigorous bubbling ceases. • The 6 M NH 3 should be added drop wise and the pH carefully monitored by using the universal indicator paper provided. The simplest way is to dip a clean stirring rod into the solution and touch a drop to a small section of universal indicator paper which is resting on a watch glass.
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UTAR FHSC1134 Inorganic Chemistry Trimester 3
Unknown metal ions + 2+ 3+ 3+ 2+ (Ag , Ba , Fe , Cr , Cu ) Add 4 drops of 6 M HCl and mix thoroughly YES
NO
Precipitate Insoluble Chloride Group: Ag
Solution Add 1cm of ethanol, 2 drops of 6 M H2SO4 and stand for 5 minutes. 3
+
2+
3+,
Group: Ba , Fe YES
Precipitate Insoluble sulphate Group: Ba2+
3+
2+
Cr , Cu NO
Solution - Transfer to boiling tube, add 3 boiling boiling chips. Boil Boil to expel ethanol (water bath). - Return the solution to a small small test tube and add 6 M NH3, dropwise, until has pH 8-10 (test ( test with universal indicator paper) Subgroup: Fe3+, Cr3+, Cu2+ NO
YES
Precipitate Insoluble hydroxide Subgroup: Fe
3+,
Cr
- Centrifuge and discard supernatant. - Transfer as much solid as possible to a larger test tube. - Add 6 drops – 1 cm 3 of 1 M H2O2. Stir thoroughly and place in a boiling water bath for 5-10 minutes
dissolves to Some or all precipitate dissolves to give a yellow supernatant solution. Cr present as H2CrO4 Lab manual version 4.1 Foundation in Science
3+
Solution Soluble amine Subgroup: Cu
2+
Add excess of 6 M NH3 (fume hood) to the original solution.
Precipitate remains, remains, no colour change. Fe present
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UTAR FHSC1134 Inorganic Chemistry Trimester 3
Results: Qualitative Tests for the Individual Ion Solutions – Observations Ion
Chloride test (HCl)
Ethanol test
NH3 test
H2O2 test
Possible ion
A
B
C
D
E
Questions: 1. Write down all the balanced equations involved.
2. Describe briefly the reactions involved.
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