Transcript Chapter 2
Measurement
• Quantitative Observation
• Comparison Based on an Accepted Scale
– e.g. Meter Stick
• Has 2 Parts – the Number and the Unit
– Number Tells Comparison
– Unit Tells Scale
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Scientific Notation
• Technique Used to Express Very Large or
Very Small Numbers
• Based on Powers of 10
• To Compare Numbers Written in Scientific
Notation
– First Compare Exponents of 10
– Then Compare Numbers
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Writing Numbers in Scientific Notation
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Locate the Decimal Point
Move the decimal point to the right of the nonzero digit in the largest place
– The new number is now between 1 and 10
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Multiply the new number by 10n
– where n is the number of places you moved the
decimal point
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Determine the sign on the exponent n
– If the decimal point was moved left, n is +
– If the decimal point was moved right, n is –
– If the decimal point was not moved, n is 0
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Writing Numbers in Standard Form
1 Determine the sign of n of 10n
– If n is + the decimal point will move to the right
– If n is – the decimal point will move to the left
2 Determine the value of the exponent of 10
– Tells the number of places to move the decimal
point
3 Move the decimal point and rewrite the
number
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Related Units in the Metric System
• All units in the metric system are related to
the fundamental unit by a power of 10
• The power of 10 is indicated by a prefix
• The prefixes are always the same,
regardless of the fundamental unit
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Table 2.2: The Commonly used Prefixes in the Metric
System
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Length
• SI unit = meter (m)
– About 3½ inches longer than a yard
• 1 meter = one ten-millionth the distance from the North Pole to the
Equator = distance between marks on standard metal rod in a Paris
vault = distance covered by a certain number of wavelengths of a
special color of light
• Commonly use centimeters (cm)
– 1 m = 100 cm
– 1 cm = 0.01 m = 10 mm
– 1 inch = 2.54 cm (exactly)
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Table 2.3: The Metric System for Measuring Length
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Figure 2.1: Comparison of English and metric units for
length on a ruler
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Volume
• Measure of the amount of three-dimensional space
occupied by a substance
• SI unit = cubic meter (m3)
• Commonly measure solid volume in cubic centimeters
(cm3)
– 1 m3 = 106 cm3
– 1 cm3 = 10-6 m3 = 0.000001 m3
• Commonly measure liquid or gas volume in milliliters
(mL)
–
–
–
–
1 L is slightly larger than 1 quart
1 L = 1 dm3 = 1000 mL = 103 mL
1 mL = 0.001 L = 10-3 L
1 mL = 1 cm3
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Figure 2.2:
Cubes
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Figure 2.3: A 100-ml
Graduated Cylinder
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Mass
• Measure of the amount of matter present in
an object
• SI unit = kilogram (kg)
• Commonly measure mass in grams (g) or
milligrams (mg)
– 1 kg = 2.2046 pounds, 1 lbs.. = 453.59 g
– 1 kg = 1000 g = 103 g, 1 g = 1000 mg = 103 mg
– 1 g = 0.001 kg = 10-3 kg, 1 mg = 0.001 g = 10-3 g
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Figure 2.4: An
electronic
analytical
balance used in
chemistry labs
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Uncertainty in Measured Numbers
• A measurement always has some amount of
uncertainty
• Uncertainty comes from limitations of the
techniques used for comparison
• To understand how reliable a measurement
is, we need to understand the limitations of
the measurement
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Reporting Measurements
• To indicate the uncertainty of a single
measurement scientists use a system called
significant figures
• The last digit written in a measurement is
the number that is considered to be
uncertain
• Unless stated otherwise, the uncertainty in
the last digit is ±1
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Figure 2.5: Measuring a Pin
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Rules for Counting Significant Figures
• Nonzero integers are always significant
• Zeros
– Leading zeros never count as significant figures
– Captive zeros are always significant
– Trailing zeros are significant if the number has
a decimal point
• Exact numbers have an unlimited number of
significant figures
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Exact Numbers
• Exact Numbers are numbers known with certainty
• Unlimited number of significant figures
• They are either
– counting numbers
• number of sides on a square
– or defined
•
•
•
•
100 cm = 1 m, 12 in = 1 ft, 1 in = 2.54 cm
1 kg = 1000 g, 1 LB = 16 oz
1000 mL = 1 L; 1 gal = 4 qts.
1 minute = 60 seconds
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Calculations with Significant Figures
• Calculators/computers do not know
about significant figures!!!
• Exact numbers do not affect the number of
significant figures in an answer
• Answers to calculations must be rounded to
the proper number of significant figures
– round at the end of the calculation
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Rules for Rounding Off
• If the digit to be removed
• is less than 5, the preceding digit stays the
same
• is equal to or greater than 5, the preceding
digit is increased by 1
• In a series of calculations, carry the extra
digits to the final result and then round off
• Don’t forget to add place-holding zeros
if necessary to keep value the same!!
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Multiplication/Division with
Significant Figures
•
•
•
Result has the same number of significant figures
as the measurement with the smallest number of
significant figures
Count the number of significant figures in each
measurement
Round the result so it has the same number of
significant figures as the measurement with the
smallest number of significant figures
4.5 cm
2 sig figs
x
0.200 cm =
3 sig figs
0.90 cm2
2 sig figs
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Adding/Subtracting Numbers
with Significant Figures
•
•
•
•
Result is limited by the number with the
smallest number of significant decimal places
Find last significant figure in each
measurement
Find which one is “left-most”
Round answer to the same decimal place
450 mL + 27.5 mL = 480 mL
precise to 10’s place
precise to 0.1’s place
precise to 10’s place
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Problem Solving and Dimensional Analysis
• Many problems in chemistry involve using
equivalence statements to convert one unit of
measurement to another
• Conversion factors are relationships between two units
– May be exact or measured
– Both parts of the conversion factor should have the same
number of significant figures
• Conversion factors generated from equivalence
statements
– e.g. 1 inch = 2.54 cm can give 2.54cm or
1in
1in
2.54cm
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Problem Solving and Dimensional Analysis
• Arrange conversion factors so starting unit
cancels
– Arrange conversion factor so starting unit is on
the bottom of the conversion factor
• May string conversion factors
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Converting One Unit to Another
•
•
•
Find the relationship(s) between the
starting and goal units. Write an
equivalence statement for each
relationship.
Write a conversion factor for each
equivalence statement.
Arrange the conversion factor(s) to cancel
starting unit and result in goal unit.
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Converting One Unit to Another
•
•
•
•
Check that the units cancel properly
Multiply and Divide the numbers to give
the answer with the proper unit.
Check your significant figures
Check that your answer makes sense!
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Temperature Scales
• Fahrenheit Scale, °F
– Water’s freezing point = 32°F, boiling point = 212°F
• Celsius Scale, °C
– Temperature unit larger than the Fahrenheit
– Water’s freezing point = 0°C, boiling point = 100°C
• Kelvin Scale, K
– Temperature unit same size as Celsius
– Water’s freezing point = 273 K, boiling point = 373 K
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Figure 2.6: Thermometers based on the three temperature
scales in (a) ice water and (b) boiling water
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Figure 2.7: The three major temperature scales
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Figure 2.8: Converting 70°C to units measured on
the Kelvin scale
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Figure 2.9: Comparison of the Celsius and Fahrenheit
scales
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Density
• Density is a property of matter representing the mass per unit
volume
• For equal volumes, denser object has larger mass
• For equal masses, denser object has small volume
• Solids = g/cm3
– 1 cm3 = 1 mL
Mass
Density
• Liquids = g/mL
Volume
• Gases = g/L
• Volume of a solid can be determined by water displacement
• Density : solids > liquids >>> gases
• In a heterogeneous mixture, denser object sinks
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Using Density in Calculations
Mass
Density
Volume
Mass
Volume
Density
Mass Density Volume
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Figure 2.10: (a) Tank of water. (b) Person submerged in the
tank, raising the level of the water.
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