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This chapter introduces fundamental concepts of chemistry, including the composition, structure, and properties of matter. It covers different branches of chemistry and important measurements. The chapter also introduces the metric system and the International System of Units (SI).
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UNIT 1 SOME BASIC CONCEPTS OF CHEMISTRY Chemistry: Chemistry is the branch of science that deals with the composition, structure and properties of matter. Chemistry is called the science of atoms and molecule Branches of Chemistry Or...
UNIT 1 SOME BASIC CONCEPTS OF CHEMISTRY Chemistry: Chemistry is the branch of science that deals with the composition, structure and properties of matter. Chemistry is called the science of atoms and molecule Branches of Chemistry Organic Chemistry -This branch deals with study of carbon compounds especially hydrocarbons and their derivatives. Inorganic Chemistry-This branch deals with the study of compounds of all other elements except carbon. It largely concerns itself with the study of minerals found in the Earth's crust. Physical Chemistry-The explanation of fundamental principles governing various chemical phenomena is the main concern of this branch. It is basically concerned with laws and theories of the different branches of chemistry. Industrial Chemistry-The chemistry involved in industrial processes is studied under this branch. Analytical Chemistry-This branch deals with the qualitative and quantitative analysis of various substances. Biochemistry-This branch deals with the chemical changes going on in the bodies of living organisms; plants and animals. Nuclear Chemistry-Nuclear reactions, such as nuclear fission, nuclear fusion, transmutation processes etc. are studied under this branch. PROPERTIES OF MATTER AND THEIR MEASUREMENT--Every substance has unique or characteristic properties. These properties can be classified into two categories – physical properties and chemical properties. Physical properties are those properties which can be measured or observed without changing the identity or the composition of the substance. E.g. colour, odour, melting point, boiling point, density etc. The measurement or observation of chemical properties requires a chemical change to occur. e.g. Burning of Mg-ribbon in air Chemical properties are characteristic reactions of different substances; these include acidity or basicity, combustibility etc.Many properties of matter such as length, area, volume, etc., are quantitative in nature. Metric System was based on the decimal system. The International System of Units (SI) The International System of Units (in French Le Systeme International d’Unites– abbreviated as SI) was established by the 11th General Conference on Weights and Measures (CGPM from ConferenceGenerale des Poids at Measures). The SI system has seven base units 1 Prefixes in SI system Multiple Prefix Symbol 10-12 pico p 10-9 nano n 10-6 micro µ 10-3 milli m 10-2 centi c 10-1 deci d 10 deca da 102 hecto h 103 kilo k 106 mega M 109 giga G 1012 tera T Mass and Weight-- Mass of a substance is the amount of matter present in it while weight is the force exerted by gravity on an object. The mass of a substance is constant whereas its weight may vary from one place to another due to change in gravity. The mass of a substance can be determined very accurately by using an analytical balance Volume-- Volume has the units of (length)3. So volume has units of m3 or cm3 or dm3.A common unit, litre (L) is not an SI unit, is used for measurement of volume of liquids. 1 L = 1000 mL, 1000 cm3 = 1 dm3 Density: Density of a substance is its amount of mass per unit volume.SI unit of density = SI unit of mass/SI unit of volume = kg/m3 or kg m–3This unit is quite large and a chemist often expresses density in g cm–3. Temperature--There are three common scales to measure temperature — °C (degree celsius), °F (degree Fahrenheit) and K (kelvin). Here, K is the SI unit. K = °C + 273.15 Note—Temperature below 0 °C (i.e. negative values) are possible in Celsius scale but in Kelvin scale, negative temperature is not possible. 2 Scientific Notation In which any number can be represented in the form N × 10 n (Where n is an exponent having positive or negative values and N can vary between 1 to 10). e.g. We can write 232.508 as 2.32508 x102 in scientific notation. Similarly, 0.00016 can be written as 1.6 x 10–4. Precision refers to the closeness of various measurements for the same quantity. Accuracy is the agreement of a particular value to the true value of the result Significant Figures The reliability of a measurement is indicated by the number of digits used to represent it. To express it more accuratelywe express it with digits that are known with certainty. These are called as Significant figures. They contain all thecertain digits plus one doubtful digit in a number. Rules for Determining the Number of Significant Figures All non-zero digits are significant. For example, 6.9 has two significant figures, while 2.16 has three significantfigures. The decimal place does not determine the number of significant figures. A zero becomes significant in case it comes in between non zero numbers. For example, 2.003 has four significantfigures, 4.02 has three significant figures. Zeros at the beginning of a number are not significant. For example, 0.002 has one significant figure while 0.0045has two significant figures. All zeros placed to the right of a number are significant. For example, 16.0 has three significant figures, while 16.00has four significant figures. Zeros at the end of a number without decimal point are ambiguous. In exponential notations, the numerical portion represents the number of significant figures. For example, 0.00045 isexpressed as 4.5 x 10 -4 in terms of scientific notations. The number of significant figures in this number is 2, while inAvogadro's number (6.023 x 1023) it is four. The decimal point does not count towards the number of significant figures. For example, the number 345601 has sixsignificant figures but can be written in different ways, as 345.601 or 0.345601 or 3.45601 all having same number ofsignificant figures. Retention of Significant Figures - Rounding off Figures The rounding off procedure is applied to retain the required number of significant figures. 1. If the digit coming after the desired number of significant figures happens to be more than 5, the precedingsignificant figure is increased by one, 4.317 is rounded off to 4.32. 2. If the digit involved is less than 5, it is neglected and the preceding significant figure remains unchanged, 4.312 isrounded off to 4.31. 3. If the digit happens to be 5, the last mentioned or preceding significant figure is increased by one only in case ithappens to be odd. In case of even figure, the 3 preceding digit remains unchanged. 8.375 is rounded off to 8.38 while8.365 is rounded off to 8.36. Dimensional Analysis During calculations generally there is a need to convert units from one system to other. This is called factor label method or unit factor method or dimensional analysis. For example- 5 feet and 2 inches (height of an Indian female) is to converted in SI unit 1 inch = 2.54 x 10-2 m then, 5 feet and 2 inch = 62 inch Physical Classification of Matter Properties Solid Liquid Gas 1. volume Definite Definite Indefinite 2. Shape Definite Indefinite Indefinite 3. Inter molecular Very high Moderate Negligible / Very force of attraction low 4. arrangement of Orderly arranged Free to move Free to move every molecules within the volume where 5. Inter molecular Very small Slightly greater Very great space 7. Compressibility Not compressible Not compressible Highly compressible 8. Expansion on Very little Very little Highly expand heating 9. Rigidity Very rigid Not rigid knownas Not rigid and fluid known as fluid 9. Fluidity Can’t flow Can flow Can flow 10. Diffusion They can diffuse Can diffuse And Can diffuse And due to kinetic rate of diffusion is rate of diffusion is energy of very fast very fast liquid/gases Chemical Classification of matter--- 4 Elements An element is the simplest form of matter that cannot be split into simpler substances or built from simpler substances by any ordinary chemical or physical method. There are 114 elements known to us, out of which 92 are naturally occurring while the rest have been prepared artificially. Elements are further classified into metals, non-metals and metalloids. Compounds A compound is a pure substance made up of two or more elements combined in a definite proportion by mass, which could be split by suitable chemical methods. Characteristics of compound Compounds always contain a definite proportion of the same elements by mass. The properties of compounds are totally different from the elements from which they are formed. Compounds are homogeneous. Compounds are broadly classified into inorganic and organic compounds. Inorganic compounds are those, which areobtained from non-living sources such as minerals. For example, common salt, marble and limestone. Organiccompounds are those, which occur in living sources such as plants and animals. They all contain carbon. Commonorganic compounds are oils, wax, fats etc. Mixtures A mixture is a combination of two or more elements or compounds in any proportion so that the components do not lose their identity. Air is an example of a mixture Mixtures are of two types, homogeneous and heterogeneous. Homogeneous mixtures have the same composition throughout the sample. The components of such mixtures cannot be seen under a powerful microscope. They are also called solutions. Examples of homogeneous mixtures are air, seawater, gasoline, brass etc. Heterogeneous mixtures consist of two or more parts (phases), which have different compositions. These mixtures have visible boundaries of separation between the different constituents and can be seen with the naked eye e.g., sand and salt, chalk powder in water etc. LAWS OF CHEMICAL COMBINATIONS Law of Conservation of Mass (Given by Antoine Lavoisier in 1789). It states that matter (mass) can neither be created nor destroyed. Law of Definite Proportions or Law of Constant Composition: This law was proposed by Louis Proust in 1799, which states that: 'A chemical compound always consists of the same elements combined together in the same ratio, irrespective of the method of preparation or the source from where it is taken'. Law of Multiple Proportions Proposed by Dalton in 1803, this law states that: 5 'When two elements combine to form two or more compounds, then the different masses of one element, which combine with a fixed mass of the other, bear a simple ratio to one another'. Gay Lussac’s Law of Gaseous Volumes (Given by Gay Lussac in 1808.) According to this law when gases combine or are produced in a chemical reaction they do so in a simple ratio by volume provided all gases are at same temperature and pressure. e.g.H2(g) + Cl2(g) ---→2HCl(g) 1V 1V 2V All reactants and products have simple ratio 1:1:2. Avogadro Law (In 1811, Given by Avogadro) According to this law equal volumes of gases at the same temperature and pressure should contain equal number of molecules. Dalton's Atomic Theory All substances are made up of tiny, indivisible particles called atoms. Atoms of the same element are identical in shape, size, mass and other properties. Atoms of different elements are different in all respects. Atom is the smallest unit that takes part in chemical combinations. Atoms combine with each other in simple whole number ratios to form compound atoms called molecules. Atoms cannot be created, divided or destroyed during any chemical or physical change. Atoms and Molecules The smallest particle of an element, which may or may not have independent existence is called an atom, while the smallest particle of a substance which is capable of independent existence is called a molecule. Molecules are classified as homoatomic and heteroatomic. Homoatomic molecules are made up of the atoms of the same element and heteroatomic molecules are made up of the atoms of the different element have different atomicity (number of atoms in a molecule of an element) like monoatomic, diatomic, triatomic and polyatomic. Atomic Mass Unit One atomic mass unit is defined as a mass exactly equal to one twelfth the mass of one carbon -12 atom. And 1 amu = 1.66056×10–24 g. Today, ‘amu’ has been replaced by ‘u’ which is known as unified mass. Atomic Mass Atomic mass of an element is defined as the average relative mass of an atom of an element as compared to the mass of an atom of carbon -12 taken as 12. Gram Atomic Mass The quantity of an element whose mass in grams is numerically equal to its atomic mass. In simple terms, atomic mass of an element expressed in grams is the gram atomic mass or gram atom. 6 For example, the atomic mass of oxygen = 16 amu Therefore gram atomic mass of oxygen = 16 g Molecular Mass Molecular mass of a substance is defined as the average relative mass of its molecule as compared to the mass of an atom of C-12 taken as 12. It expresses as to how many times the molecule of a substance is heavier than 1/12th of the mass of an atom of carbon. For example, a molecule of carbon dioxide is 44 times heavier than 1/12th of the mass of an atom of carbon. Therefore the molecular mass of CO2 is 44 amu. It is obtained by adding the atomic masses of all the atoms present in one molecule. Gram Molecular Mass A quantity of substance whose mass in grams is numerically equal to its molecular mass is called gram molecular mass. In simple terms, molecular mass of a substance expressed in grams is called gram molecular mass. e.g., the molecular mass of oxygen = 32 amu Therefore, gram molecular mass of oxygen = 32 g Formula Mass- Sum of atomic masses of the elements present in one formula unit of a compound. It is used for the ionic compounds. Mole Concept. Mole is defined as the amount of a substance, which contains the same number of chemical units (atoms, molecules, ions or electrons) as there are atoms in exactly 12 grams of pure carbon-12. A mole represents a collection of 6.022 x1023( Avogadro's number) chemical units.. The mass of one mole of a substance in grams is called its molar mass. Molar Volume The volume occupied by one mole of any substance is called its molar volume. It is denoted by Vm. One mole of all gaseous substances at 273 K and 1 atm pressure occupies a volume equal to 22.4 litre or 22,400 mL. The unit of molar volume is litre per mol or millilitre per mol PERCENTAGE COMPOSITION— The mass percentage of each constituent element present in any compound is called its percentage composition Mass % of the element=Mass of element in 1 molecule of the compound x 100 Molecular mass of the compound Empirical Formula and Molecular Formula— An empirical formula represents the simplest whole number ratio of various atoms present in a compound. E.g. CH is the empirical formula of benzene. The molecular formula shows the exact number of different types of atoms present in a molecule of a compound. E.g. C6H6 is the molecular formula of benzene. Relationship between empirical and molecular formulae The two formulas are related as Molecular formula = n x empirical formula 7 Chemical Equation- Shorthand representation of a chemical change in terms ofsymbols and formulae of the substances involved in the reaction is called chemical equation.. The substances that react among themselves to bring about the chemical changes are known as reactants, whereas the substances that are produced as a result of the chemical change, are known as products. Limiting Reagent- The reactant which gets consumed first or limits the amount of product formed is known as limiting reagent Reactions in Solutions-- The concentration of a solution can be expressed in any of the following ways. 1. Mass Percent is the mass of the solute in grams per 100 grams of the solution. A 5 % solution of sodium chloride means that 5 g of NaCl is present in 100g of the solution. 2. Volume percent is the number of units of volume of the solute per 100 units of the volume of solution. A 5 % (v/v) solution of ethyl alcohol contains 5 cm3 of alcohol in 100 cm3 of the solution 3. Molarity of the solution is defined as the number of moles of solute dissolved per litre (dm3) of the solution. It isdenoted by the symbol M. Measurements in Molarity can change with the change in temperature because solutionsexpand or contract accordingly. Molarity of the solution = No. of moles of the solute =n Volume of the solution in litre V The Molarity of the solution can also be expressed in terms of mass and molar mass Molarity of the solution = Mass of the solute Molar mass of the solute X volume of the solution in liter In terms of weight, molarity of the substance can be expressed as: Molarity equation To calculate the volume of a definite solution required to prepare solution of other molarity, the following equation is used: M1V1 = M2V2, where M1= initial molarity, M2= molarity of the new solution, V1= initial volume and V2= volume of the new solution. 4. Molality- Molality is defined as the number of moles of solute dissolved per 1000 g (1 kg) of solvent. Molality is expressed as 'm'. 8 5. Mole Fraction is the ratio of number of moles of one component to the total number of moles (solute and solvents) present in the solution. It is expressed as 'x'. Mole fraction of the solute = Moles of the solute Moles of solute + Moles of solvent Mole fraction of the solvent = Moles of the solvent Moles of solute + Moles of solvent Mole fraction of the solute + Mole fraction of solvent = 1 One Mark questions with answers 1. What is the significant figures in 1.050 x 104? Ans. Four 2. What is the S.I. unit of Density? Ans. Kg m-3 3. What do mean by Mole fraction? Ans. Mole Fraction is the ratio of number of moles of one component to the total number of moles (solute and solvents) present in the solution. It is expressed as 'x'. 4. Round off up to 3 significant figure (a) 1.235 (b) 1.225 Ans. (a) 1.24 (b) 1.22 5. What is AZT? Ans. Azidothymidine. 6. What is limiting reagent? Ans.The reactant which gets consumed first or limits the amount of product formed is known as limiting reagent 7. What is the relation between temperature in degree Celsius and degree fahrenheit? Ans. 8. Define one mole? Ans. One mole is the amount of a substance that contains as many particles as there are atoms in exactly 12 g of the carbon-12. 9. Calculate the formula mass calcium chloride. Ans. Formula mass of CaCl2= 40+2 x35.5=40+71 = 111 u 10. What is the law called which deals with the ratios of the volumes of the gaseous reactants and products? Ans. Gay Lussac’s law of gaseous volumes. Two Marks questions with answers 1. Give the two points of differences between homogeneous and heterogeneous mixtures. Ans. 9 Homogeneous mixture Heterogeneous mixture 1. Homogeneous mixtures 1. Heterogeneous mixtures consist of have the same composition two or more parts (phases), which throughout the sample. have different compositions. 2. These mixtures have visible 2. The components of such boundaries of separation between the mixtures cannot be seen different constituents and can be seen under a powerful with the naked eye microscope. 2. Copper oxide obtained by heating copper carbonate or copper nitrate contains copper and oxygen in the same ration by mass. Which law is illustrated by this observation? State the law. Ans.Law of Definite Proportions This law states that: A chemical compound always consists of the same elements combined together in the same ratio, irrespective of the method of preparation or the source from where it is taken. 3. Write the empirical formula of the following: (a) N2O4 (b) C6H12O6 (c) H2O (d) H2O2 Ans. (a)NO2 (b) CH2O (c) H2O (d) HO 4. Briefly explain the difference between precision and accuracy. Ans. Precision refers to the closeness of various measurements for the same quantity. However, accuracy is the agreement of a particular value to the true value of the result. 5. Define the law of multiple proportions. Explain it with one example. Ans.When two elements combine to form two or more compounds, then the different masses of one element, which combine with a fixed mass of the other, bear a simple ratio to one another. For example- carbon combines with oxygen to form two compounds CO and CO2. Compound CO CO2 Mass of C 12 12 Mass of O 16 32 Masses of oxygen which combine with a fixed mass of carbon (12g) bear a simple ratio of 16:32 or 1:2. 6. Chlorine has two isotopes of atomic mass units 34.97 and 36.97. The relative abundance of the isotopes is 0.755 and 0.245 respectively. Find the average atomic mass of chlorine. Ans. Average atomic mass = 34.97 x 0.755 +36.97 x 0.245 = 35.46 u 7. Calculate the percentage composition of water. Ans. Mass % of an element = mass of that element in the compound × 100 molar mass of the compound Molar mass of water = 18.02 g Mass % of hydrogen = 2× 1.008 × 100 18.02 = 11.18 Mass % of oxygen = 16.00 × 100 = 88.79 18.02 10 8. State the number of significant figures in each of the following: (i) 208.91 (ii) 0.00456 (iii) 453 (iv) 0.346 Ans. (i) 208.91 has five significant figures. (ii) 0.00456 has three significant figures. (iii) 453 has three significant figures. (iv) 0.346 has three significant figures. 8. Express the results of the following calculations to the appropriate number of significant figures. Ans. = 0.05608 = 0.0561 ` = 0.2615 x 10-4 = 0.3 x 10-4 9. How are 0.50 mol Na2CO3 and 0.50 M Na2CO3 different? Ans. Molar mass of Na2CO3= 2 x 23 +12 + 3 x 16 = 106 g / mol 0.50 molNa2CO3means 0.50 x 106 = 53 g 0.50 M Na2CO3 means 0.50 mol i.e. 53 g of Na2CO3 are present in I L of the solution. Three Marks questions with answers- 1. What is unit factor method? Express the following in SI units - 93 million miles (distance between earth and sun) Ans. Method to convert units from one system to other is called unit factor method. 93 million miles = 93 x 106 miles 1 mile = 1.60934 km = 1.60934 x 103 m = 1.5 x 1011 m 2. Write the three points of difference between compound and mixture. Ans. Compound Mixture Constituents are always present in a Constituents may be present in any fixed ratio by mass ratio May or may not be homogeneous in Always homogeneous in nature nature Constituents can be easily separated Constituents cannot be easily 11 by simple mechanical means separated by simple mechanical means Properties are midway between those Properties are entirely different from of its constituents. those of its constituents. 3. What do mean bygram atomic mass.One million silver atoms weigh 1.79 x 1016 g. Calculate the gram atomic mass of silver. Ans.atomic mass of an element expressed in grams is the gram atomic mass Number of silver atoms = 1 million = 1 x 106 Mass of one million Ag atoms = 1.79 x 1016 g Mass of 6.023 x 1023 atoms of silver = 1.79 x 1016 g x 6.023 x 1023 1 x 106 = 107.8 g 4. What is the percentage of carbon, hydrogen and oxygen in ethanol? Ans. Molecular formula of ethanol is : C2H5OH Molar mass of ethanol is : (212.01 + 61.008 + 16.00) g = 46.068 g Mass per cent of carbon = (24.02g / 46.068g) ×100 = 52.14% Mass per cent of hydrogen = (6.048g / 46.068g)×100 = 13.13% Mass per cent of oxygen = (16.00 g / 46.068g)×100 = 34.73% 5. What do mean by molarity.Calculate the molarity of NaOH in the solution prepared by dissolving its 4 g in enough water to form 250 mL of the solution. Ans.The number of moles of solute dissolved per litre (dm3) of the solution is called molarity Since molarity (M) = No. of moles of solute /Volume of solution in litres =(Mass of NaOH/Molar mass of NaOH)/0.250 L =(4 g / 40 g 0.1 mol)/0.250L =0.1 mol/0.250 L = 0.4 mol L-1 = 0.4 M 6. Classify the following as pure substances or mixture- (a) ethyl alcohol (b) oxygen (c) blood (d) carbon (e) steel (f) distilled water Ans. Pure substance- ethyl alcohol ,oxygen , carbon, distilled water Mixture- blood, steel 7. What are the rules for rounding off? Ans.1. If the digit coming after the desired number of significant figures happens to be more than 5, the precedingsignificant figure is increased by one, 2. If the digit involved is less than 5, it is neglected and the preceding significant figure remains unchanged, 12 3.If the digit happens to be 5, the last mentioned or preceding significant figure is increased by one only in case it happens to be odd. In case of even figure, the preceding digit remains unchanged. 8. Define –(a) Average atomic mass (b) Molecular mass (c) Formula mass Ans. (a) Average atomic mass- Atomic mass of an element is defined as the average relative mass of an atom of an element as compared to the mass of an atom of carbon -12 taken as 12. (b) Molecular mass- it is sum of atomic masses of the elements present in a molecule. (c) Formula mass- it is sum of atomic masses of the elements present in a formula unit of a compound. 9. Express the following in the scientific notation with 2 significant figures- (a) 0.0048 (b) 234,000 (c) 200.0 Ans. (a) 4.8 x 10-3 (b) 2.3 x 105 (c) 2.0 x 102 10. Calculate the number of atoms in each of the following (i) 52 moles of Ar (ii) 52 u of He (iii) 52 g of He Ans. (i) 1 mole of Ar = 6.022 × 1023 atoms of Ar 52 mol of Ar = 52 × 6.022 × 1023 atoms of Ar = 3.131 × 1025 atoms of Ar (ii)1 atom of He = 4 u of He Or, 4 u of He = 1 atom of He 1 u of He = 1/4 atom of He 52u of He = 52/4 atom of He = 13 atoms of He (iii) Molar mass of He = 4 g/mol 4 g of He contains = 6.022 × 1023 atoms of He 52 g of He contains = 6.022 × 1023 x 52 = 78.286 x 1023 atoms of He 4 Five Marks questions with answers- 1. What is the difference between empirical and molecular formula? A compound contains 4.07 % hydrogen, 24.27 % carbon and 71.65 % chlorine. Its molar mass is 98.96 g. What are its empirical and molecular formulas? Ans. An empirical formula represents the simplest whole number ration of various atoms present in a compound whereas the molecular formula shows the exact number of different types of atoms present in a molecule of a compound. 13 The empirical formula of the above compound is CH2Cl. empirical formula mass is 12 + (1x2) + 35.5 = 49.5 n= molecular mass/ empirical formula mass =98.96/49.5 = 2 Hence molecular formula is C2H4Cl2 2. Dinitrogen and dihydrogen react with each other to produce ammonia according to the following chemical equation: N2(g) + H2(g) → 2NH3(g) (i) Calculate the mass of ammonia produced if 2.00 × 10 3 g dinitrogen reacts with 1.00 × 103 g of dihydrogen. (ii) Will any of the two reactants remain unreacted? (iii) If yes, which one and what would be its mass? Ans. (i) Balancing the given chemical equation, From the equation, 1 mole (28 g) of dinitrogen reacts with 3 mole (6 g) of dihydrogen to give 2 mole (34 g) of ammonia. ⇒ 2.00 × 103 g of dinitrogen will react with dihydrogen i.e., 2.00 × 103 g of dinitrogen will react with 428.6 g of dihydrogen. Given, Amount of dihydrogen = 1.00 × 103 g Hence, N2 is the limiting reagent. 28 g of N2 produces 34 g of NH3. Hence, mass of ammonia produced by 2000 g of N2 = 2428.57 g 14 (ii) N2 is the limiting reagent and H2 is the excess reagent. Hence, H2 will remain unreacted. (iii) Mass of dihydrogen left unreacted = 1.00 × 103 g – 428.6 g = 571.4 g 3. A welding fuel gas contains carbon and hydrogen only. Burning a small sample of it in oxygen gives 3.38 g carbon dioxide, 0.690 g of water and no other products. A volume of 10.0 L (measured at STP) of this welding gas is found to weigh 11.6 g. Calculate (i) empirical formula, (ii) molar mass of the gas, and (iii) molecular formula. Ans. (i) 1 mole (44 g) of CO2 contains 12 g of carbon. 3.38 g of CO2 will contain carbon = 0.9217 g 18 g of water contains 2 g of hydrogen. 0.690 g of water will contain hydrogen = 0.0767 g Since carbon and hydrogen are the only constituents of the compound, the total mass of the compound is:= 0.9217 g + 0.0767 g= 0.9984 g Percent of C in the compound = 92.32% Percent of H in the compound = 7.68% Moles of carbon in the compound = 7.69 Moles of hydrogen in the compound = = 7.68 Ratio of carbon to hydrogen in the compound = 7.69: 7.68= 1: 1 Hence, the empirical formula of the gas is CH. (ii) Given, Weight of 10.0L of the gas (at S.T.P) = 11.6 g Weight of 22.4 L of gas at STP = 25.984 g≈ 26 g Hence, the molar mass of the gas is 26 g. 15 (iii) Empirical formula mass of CH = 12 + 1 = 13 g n=2 Molecular formula of gas = (CH)n= C2H2 HOTS (Higher Order Thinking Skills) 1. What is the difference between 160 cm and 160.0 cm Ans. 160 has three significant figures while 160.0 has four significant figures. Hence, 160.0 represents greater accuracy. 2. In the combustion of methane, what is the limiting reactant and why? Ans. Methane is the limiting reactant because the other reactant is oxygen of the air which is always present in excess. Thus, the amounts of CO 2 and H2O formed depend upon the amount of methane burnt. 3. A compound made up of two elements A and B has A= 70 %, B = 30 %. Their relative number of moles in the compound are 1.25 and 1.88. calculate a. Atomic masses of the elements A and B b. Molecular formula of the compound , if its molecular mass is found to be 160 Ans. Relative no. of moles of an element = % of the element Atomic mass Or atomic mass = % of the element = 70 = 56 Relative no. of moles 1.25 Atomic mass of B = 30/1.88 = 16 Calculation of Empirical formula Element Relative no. of Simplest molar Simplest whole no. moles ratio molar ratio A 1.25 1.25/1.25 = 1 2 B 1.88 1.88/1.25 = 1.5 3 Empirical formula = A2B3 Calculation of molecular formula- Empirical formula mass = 2 x 56 + 3x 16 = 160 n= molecular mass / Empirical formula mass = 160/160 = 1 Molecular formula = A2B3 16