Use approximate atomic masses H = 1.008, C = 12.01 and O = 16.00. H2O: 2(1.008)+16.00 = 18.02 g mol^-1. CO2: 12.01+2(16.00)=44.01 g mol^-1. CH4: 12.01+4(1.008)=16.04 g mol^-1.
(i) H2O = 18.02 g mol^-1, (ii) CO2 = 44.01 g mol^-1, (iii) CH4 = 16.04 g mol^-1.
Molar mass of Na2SO4 = 2(22.99)+32.06+4(16.00)=142.04 g mol^-1. Mass percent Na = 45.98/142.04 x 100 = 32.37%. Mass percent S = 32.06/142.04 x 100 = 22.57%. Mass percent O = 64.00/142.04 x 100 = 45.06%.
Na = 32.37%, S = 22.57%, O = 45.06%.
In 100 g compound, moles of Fe = 69.9/55.85 = 1.252 and moles of O = 30.1/16.00 = 1.881. Dividing by 1.252 gives Fe:O = 1:1.50. Multiplying by 2 gives 2:3, so the empirical formula is Fe2O3.
Fe2O3.
The reaction is C + O2 -> CO2. (i) 1 mol C gives 1 mol CO2 = 44 g. (ii) 16 g O2 = 0.5 mol O2, so oxygen is limiting and gives 0.5 mol CO2 = 22 g. (iii) With 2 mol C and only 0.5 mol O2, oxygen is again limiting and gives 0.5 mol CO2 = 22 g.
(i) 44 g CO2. (ii) 22 g CO2. (iii) 22 g CO2.
Moles required = M x V = 0.375 mol L^-1 x 0.500 L = 0.1875 mol. Mass = 0.1875 x 82.0245 = 15.38 g.
15.38 g.
Mass of 1 L solution = 1.41 g mL^-1 x 1000 mL = 1410 g. Mass of HNO3 = 69% of 1410 = 972.9 g. Molar mass of HNO3 = 63.01 g mol^-1, so moles = 972.9/63.01 = 15.4 mol. Therefore concentration = 15.4 mol L^-1.
15.4 mol L^-1.
Molar mass of CuSO4 = 63.55+32.06+4(16.00)=159.61 g mol^-1. Copper fraction = 63.55/159.61. From 100 g CuSO4, copper obtained = 100 x 63.55/159.61 = 39.8 g.
39.8 g copper.
For 100 g oxide, moles Fe = 69.9/55.85 = 1.252 and moles O = 30.1/16.00 = 1.881. The simplest ratio is Fe:O = 1:1.5 = 2:3. Therefore the formula of the oxide is Fe2O3.
Fe2O3.
Average atomic mass = (75.77 x 34.9689 + 24.23 x 36.9659)/100 = 35.45 u.
35.45 u.
Each mole of C2H6 contains 2 mol C atoms and 6 mol H atoms. Therefore 3 mol C2H6 contains 6 mol C atoms and 18 mol H atoms. Number of ethane molecules = 3 x 6.022 x 10^23 = 1.81 x 10^24.
(i) 6 mol C atoms. (ii) 18 mol H atoms. (iii) 1.81 x 10^24 molecules of ethane.
Molar mass of C12H22O11 = 12(12.01)+22(1.008)+11(16.00) = about 342 g mol^-1. Moles = 20/342 = 0.0585 mol. Molarity = 0.0585/2.0 = 0.029 mol L^-1.
0.029 mol L^-1.
Moles of methanol needed = 0.25 x 2.5 = 0.625 mol. Molar mass of CH3OH is about 32.04 g mol^-1, so mass = 0.625 x 32.04 = 20.0 g = 0.0200 kg. Volume = mass/density = 0.0200/0.793 = 0.0252 L = 25.2 mL.
0.0252 L, or 25.2 mL.
1034 g cm^-2 = 1.034 kg per 10^-4 m^2 = 1.034 x 10^4 kg m^-2. Pressure = weight/area = (1.034 x 10^4)(9.8) = 1.01 x 10^5 N m^-2 = 1.01 x 10^5 Pa.
1.01 x 10^5 Pa.
SI prefixes denote powers of ten: micro means 10^-6, deca means 10, mega means 10^6, giga means 10^9 and femto means 10^-15.
(i) micro = 10^-6; (ii) deca = 10; (iii) mega = 10^6; (iv) giga = 10^9; (v) femto = 10^-15.
Measurements contain uncertainty. Significant figures show the precision of a measurement by retaining the digits known with certainty plus one estimated digit.
Significant figures are the meaningful digits in a measured or calculated value, including all certain digits and the first uncertain digit.
15 ppm by mass means 15 parts in 10^6 parts by mass. Percent by mass = 15/10^6 x 100 = 0.0015%. For 1 kg water sample, mass of CHCl3 is 15 mg = 0.015 g. Molar mass of CHCl3 = 12.01+1.008+3(35.45)=119.37 g mol^-1, so moles = 0.015/119.37 = 1.26 x 10^-4 mol. The solvent mass is essentially 1 kg, so molality = 1.26 x 10^-4 mol kg^-1.
(i) 0.0015% by mass. (ii) 1.26 x 10^-4 mol kg^-1.
Scientific notation writes a number as a x 10^n, where 1 <= a < 10. Moving the decimal point gives the listed powers of ten.
(i) 4.8 x 10^-3; (ii) 2.34 x 10^5; (iii) 8.008 x 10^3; (iv) 5.000 x 10^2; (v) 6.0012 x 10^0.
Leading zeros are not significant; zeros between non-zero digits are significant; zeros after a decimal point are significant. For 126,000 without a decimal point, the trailing zeros are not taken as significant, so it has 3 significant figures.
(i) 2; (ii) 3; (iii) 4; (iv) 3; (v) 4; (vi) 5.
Keep three significant figures and round using the next digit. 34.216 -> 34.2; 10.4107 -> 10.4; 0.04597 -> 0.0460, where the final zero is significant; 2808 -> 2810, better written as 2.81 x 10^3 to show three significant figures.
(i) 34.2; (ii) 10.4; (iii) 0.0460; (iv) 2.81 x 10^3.
For a fixed mass of dinitrogen, the masses of dioxygen combining with it are in small whole-number ratios. Converting all data to 14 g dinitrogen gives oxygen masses 16, 32, 16 and 40 g, which are in the ratio 2:4:2:5 after division by 8. This illustrates the law of multiple proportions: when two elements form more than one compound, the masses of one element that combine with a fixed mass of the other are in simple whole-number ratios. Unit conversions follow from kilo = 10^3, milli = 10^-3, pico = 10^-12, nano = 10^-9 and 1 L = 1 dm^3.
(a) Law of multiple proportions. (b) (i) 1 km = 10^6 mm = 10^15 pm; (ii) 1 mg = 10^-6 kg = 10^6 ng; (iii) 1 mL = 10^-3 L = 10^-3 dm^3.
2.00 ns = 2.00 x 10^-9 s. Distance = speed x time = (3.0 x 10^8)(2.00 x 10^-9) = 0.600 m.
0.600 m.
Mole measures quantity, independent of volume. Molarity measures moles of solute per litre of solution, so it specifies concentration.
0.50 mol Na2CO3 is an amount of substance; 0.50 M Na2CO3 is a concentration equal to 0.50 mol Na2CO3 per litre of solution.
For gases at the same temperature and pressure, volume ratios follow mole ratios. The balanced equation is 2H2 + O2 -> 2H2O. Therefore 10 volumes H2 react with 5 volumes O2 to produce 10 volumes H2O vapour.
10 volumes of water vapour.
1 pm = 10^-12 m and 1 mg = 10^-6 kg. Therefore 28.7 pm = 28.7 x 10^-12 m = 2.87 x 10^-11 m; 15.15 pm = 1.515 x 10^-11 m; 25365 mg = 25365 x 10^-6 kg = 2.5365 x 10^-2 kg.
(i) 2.87 x 10^-11 m. (ii) 1.515 x 10^-11 m. (iii) 2.5365 x 10^-2 kg.
- i. 1 g Au (s)
- ii. 1 g Na (s)
- iii. 1 g Li (s)
- iv. 1 g of Cl2(g)
For elements, atoms in 1 g are proportional to 1/atomic mass. Lithium has the smallest atomic mass among Au, Na and Li, so 1 g Li contains the most atoms. For Cl2, 1 g gives 2/70.9 mol atoms, still less than 1/6.94 mol atoms for Li.
(iii) 1 g Li (s).
Assume 1 L water, so mass of water = 1000 g and moles of water = 1000/18 = 55.56 mol. If mole fraction of ethanol is 0.040, then n_ethanol/(n_ethanol+55.56)=0.040. Thus n_ethanol = (0.040/0.960)(55.56)=2.31 mol. Taking the solution volume approximately as 1 L, molarity = 2.31 M.
2.31 M approximately.
One mole of 12C atoms has mass 12 g and contains 6.022 x 10^23 atoms. Mass of one atom = 12/(6.022 x 10^23) = 1.99 x 10^-23 g.
1.99 x 10^-23 g.
Average molar mass = 35.96755(0.00337)+37.96272(0.00063)+39.9624(0.99600) = 39.95 g mol^-1.
39.95 g mol^-1.
(i) 52 mol Ar contains 52 x 6.022 x 10^23 = 3.13 x 10^25 atoms. (ii) One He atom has mass about 4 u, so 52 u He contains 52/4 = 13 atoms. (iii) 52 g He = 52/4 = 13 mol He, so atoms = 13 x 6.022 x 10^23 = 7.83 x 10^24.
(i) 3.13 x 10^25 atoms. (ii) 13 atoms. (iii) 7.83 x 10^24 atoms.
Moles C from CO2 = 3.38/44.01 = 0.0768 mol. Moles H from water = 2(0.690/18.015)=0.0766 mol. Ratio C:H is approximately 1:1, so empirical formula is CH and empirical formula mass is about 13 g mol^-1. At STP, 10.0 L gas = 10.0/22.4 = 0.446 mol. Molar mass = 11.6/0.446 = 26.0 g mol^-1. Molecular formula factor = 26/13 = 2, so molecular formula is C2H2.
(i) CH. (ii) 26.0 g mol^-1. (iii) C2H2.
Moles HCl = 0.75 x 0.025 = 0.01875 mol. From CaCO3 + 2HCl -> CaCl2 + CO2 + H2O, moles CaCO3 required = 0.01875/2 = 0.009375 mol. Molar mass CaCO3 is about 100.09 g mol^-1, so mass = 0.009375 x 100.09 = 0.94 g.
0.94 g CaCO3.
Molar mass of MnO2 = 54.94+2(16.00)=86.94 g mol^-1. Moles MnO2 = 5.0/86.94 = 0.0575 mol. The reaction requires 4 mol HCl per mol MnO2, so moles HCl = 4(0.0575)=0.230 mol. Mass HCl = 0.230 x 36.46 = 8.4 g.
8.4 g HCl.