Work Session 2: Introduction to Measurements, Conversions, and Significant Figures

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Work Session 2: Introduction to Measurements, Conversions, and Significant Figures Measurements are made using tools. The tool can be as simple as a ruler or as complex as the Hubble Space Telescope. It is typical that finer measurements require more expensive tools to make the measurement. For example, we have two types of electronic balances in the laboratory. One is a top-loading balance, and the other is an analytical balance. The top-loading balance is capable of measuring to the nearest 0.1 g, while the analytical balance measures to the nearest 0.001 g. A general principle when making measurements and recording the result is: always record the measurement to the full capacity of the tool used. Never record the measurement with more than or less than the capacity of the tool used. For example: a penny on the top-loading (decigram) balance in this lab may read 2.4 g on the display, whereas the same penny on the analytical (milligram) balance may read 2.413 g. If the display reads to the milligram, then record the mass with the appropriate level of precision and include all of the decimals shown. If the balance shows 2.400 in the display window, then record 2.400 g on the data sheet. The manner in which the data is recorded indicates the accuracy of the tool used to make the measurement. If you record 2.4, it is assumed that the balance used can only give readings to the tenth place. If, in fact, you used a balance that shows 2.400 g, make sure you write 2.400 g as the recorded mass. It is a common error for students to only record the first few numbers appearing on the display, and then to fill in zeroes when there is a need to record to the nearest milligram. A series of measurements that all end in zero is highly unlikely. Thus, be sure to record the correct values for your results. If you find an error in your data recording, make a note in the margin or remake the measurement. Never change your data. Balances can give readings different from the true value if they lose their calibration. If the same object is weighed several times on a decigram balance and several times on a decigram balance, the results might look like this: Table 1: Measuring the mass of a penny on four different balances. Certified mass of the penny used for the measurements below = 2.413 g Measurement Decigram Balance Decigram Balance Milligram Balance Milligram Balance 1 2 1 2 1 2.2 g 2.2 g 2.419 g 2.413 g 2 2.1 g 2.3 g 2.411 g 2.412 g 3 2.5 g 2.3 g 2.409 g 2.413 g 4 2.0 g 2.2 g 2.411 g 2.412 g 5 2.6 g 2.2 g 2.408 g 2.413 g Average = 2.3 g 2.2 g 2.412 g 2.413 g Inaccurate and Imprecise Inaccurate but Precise Accurate but Imprecise Accurate and Precise In Table 1, note how the words accurate and precise are used. Accurate describes whether the measurement is close to the actual (or true) value. Precise refers to the reproducibility of a measurement. [NOTE: The terms accurate and precision are also used to describe the quality of an instrument. In this context, an analytical balance is said to have a higher level of precision than a top-loading balance because it reads to 0.001 g rather than 0.1 g.] Chem1A Work Session 2: Measurements and Significant Figures 1

On the balances in our lab, a digital display provides the quantity that we need to record. However, for many other types of measurements and measurement devices, the user is required to manually read the value. In such instances, one would record all known digits plus one estimated digit. For example, Figure 1 shows a ruler with increments (or divisions) of 1 cm. The object being measured is between 58 cm and 59 cm long. Our readings of 58 cm or 59 cm are the known digits. We must add an estimated digit, which would approximate the measurement of object to approximately 58.1 cm. If your estimate is 58.2 cm, that is also an acceptable answer. Figure 1 Scientific Notation In science, we often work with numeric values that are very large or very small. Thus, to simplify the reporting of such quantities, we use scientific notation - a coefficient and power of 10. We can generalize scientific notation as a.bcd x 10 x. The a,b,c, and d are digits, collectively referred to as the coefficient. The power of 10 - represented as x in the example above - is the exponent. There are two guidelines for expressing a quantity in scientific notation: 1) 1 coefficient < 10 The coefficient must be greater than or equal to one, but less than ten. 2) The exponent is a whole number; may be positive or negative. Examples: 2.3 x 10 5, 8.89 x 10 5, and 9.99 x 10 2 are written in proper scientific notation 0.6 x 10 2, 22.53 x 10-3, and 10.01x 10 2 are not written in proper scientific notation because the coefficient does not lie between 1 and 10. 10.01x 10 2 should be expressed as 1.001x 10 3. Significant Figures In the prefacing part of this Work Session, you have learned that there is always some estimation or error involved when making a measurement. On an electronic balance, the last digit will sometimes flicker back and forth between two numbers, and you will need to make your best estimate of the last digit. There are rules for working with numbers obtained from measurements that take this estimation into account and prevent us from making erroneous calculations. Your textbook gives the rules for significant digits and many examples of their use in Appendix II: A6-A9. The expectations for handling significant figures can vary from instructor to instructor, so be sure to ask if you have any question Chem1A Work Session 2: Measurements and Significant Figures 2

Name: Date: Grade Work Session 2: Measurements, Conversions, and Significant Figures 1) In the space provided, record the values for the following measurements. (Be careful with the estimated digit.) cm cm ml ml o C o C o C o C Chem1A Work Session 2: Measurements and Significant Figures 3

2) Express the following results in proper scientific notation. Review can be found in Appendix III A11-A16. Result in Standard Notation Result in Scientific Notation 621.0 g 6.210 x 10 2 g 16432 cm 3,456,000 s 0.007 mi 0.000135 nm 0.08 kg 0.0009462 cm 55000 mi 0.00014 s 497 m 10,003 s 3) How many significant figures are in each of the following numbers? Review can be found in Appendix II A6-A10. Result # of Significant Figures 0.031 cm 2 sf 45.8736 mg 0.00239 ml 48,000 in 93.00 m 3.982 x 10 6 m 1.70 x 10-4 mm 0.00590 L 1.00040 km 4.00000 g 3800 m 23000 ± 10 m Chem1A Work Session 2: Measurements and Significant Figures 4

4) Round each of the following numbers to 3 significant figures. Do not change their values (that is, if a number is in the thousands before rounding, it will be in the thousands after rounding). Result Rounded to 3 Significant Figures 98715 ml 98700 ml 1367 m 0.0037421 km 1.5587 g 12.85 L 1.6683 x 10-4 m 1.632257 cm 5) Perform each of the following indicated operations and give the answer to the proper number of significant digits. Watch the order of operation involved in the same problem. When adding or subtracting numbers written in scientific notation, it often helps to rewrite the numbers so each one has the same index (that is, power of ten). For example, to add 3.42 x 10-3 and 5.223 x 10-4, first rewrite the second number as 0.5223 x 10-3. Remember, if you make the coefficient smaller, you make the power bigger, and vice versa. 0.5223 is smaller than 5.223, and 10-3 is bigger than 10-4. When adding or subtracting values, be sure that they have the same units. Problem Calculated Answer with Correct Units Rounded Answer with Proper SF and Correct Units 32.27 m x 1.54 m = 49.6955... m 2 49.7 m 2 3.68 g/0.07925 ml = 1.750m x 0.0342m = 0.00957 kg/2.9465 L = (3.2650 x 10 24 m) / (4.85 x 10 3 s) = 10.052 cm - 9.8742 cm = 0.01953 cm + (7.32 x 10-3 m) = (8.52 m+ 4.1586m) x (18.73 m+ 153.2 m) = (3.84 x 10-2 m) 3 = (0.000738 m 8.3 x 10-5 m) / (6.298 x 10-8 m) = log(22.6) = ln(12.55) = Chem1A Work Session 2: Measurements and Significant Figures 5

6) What are the standard metric (or SI) units for distance, mass, time, temperature, and amount? 7) Define accuracy and precision. Which term corresponds to the reproducibility of a measurement, and which term corresponds to the true value? 8) A cashier at Whole Foods measures the weight (mass) of fruit with an electronic scale at the register. If the cashier accidentally leaves a pen on the scale for each measurement, would this contribute to random error or systematic error? Explain. 9) The average mass of an M&M candy is 0.625 g. What is the mass of 12 M&Ms? The answer should be reported to three (3) significant figures. Why are there no sig figs associated with 12 M&Ms? 10) Calculate the density of a rectangular block, which has a mass of 25.71 g. The dimensions of the solid are 2.30 cm long, 2.01 cm wide, and 1.82 cm high. Chem1A Work Session 2: Measurements and Significant Figures 6

11) What is the Celsius equivalent of 30. F? Use appropriate number of significant figures. (Appendix A.) 12) Isopropyl alcohol, commonly known as rubbing alcohol, boils at 180 F. What is the boiling point of isopropyl alcohol in Kelvin units? 13) The elevation of City of Santa Clara is approximately 75 ft. What is the elevation in centimeters? 14) A car travels at 50.0 miles per hour. What is the equivalent speed in meters/min? 1.609 km = 1 mile 15) How many cubic centimeters are there in 2.11 yd 3? Chem1A Work Session 2: Measurements and Significant Figures 7

16) If a gas canister contains 1.45 L of fuel, and the fuel density is 0.710 g/cm 3. What is the mass of the fuel contained in the gas canister? 17) Distinguish between the calorie (cal) and Calorie (Cal) energy units. What is the definition of a calorie? 18) What is the amount of Joules in a Snickers bar that contains 215 Calories (Cal)? 1 cal = 4.184 J 19) During a bike ride, a cyclist s energy output was 5396-kJ. If a donut contains 200-Cal, how many donuts are sufficient to fuel the bike ride? Chem1A Work Session 2: Measurements and Significant Figures 8

20) Define the mole (mol) unit. 21) The Earth s population is approximately 8-billion people. If you had a mole of pennies and gave each person 10-billion dollars, how much money would you have left over? 22) What is the molar mass of any element? 23) What is the molar mass of Aluminum? 24) What is the density of Aluminum (Table 2.1, p39 of your textbook). 25) How many atoms are in 5.0-mL of Aluminum? Chem1A Work Session 2: Measurements and Significant Figures 9

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