Chapter 1 Methods and Measurement PDF

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This document is Chapter 1 of a General, Organic, and Biochemistry textbook. It covers introductory chemistry concepts, including methods and measurement.

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GENERAL, ORGANIC, AND
BIOCHEMISTRY
10TH Edition
Katherine J. Denniston
Joseph J. Topping
Danaè R. Quirk Dorr
Robert L. Caret

Chapter 1
Chemistry:
Methods and Measurement

©2020 McGraw-Hill Education. All rights reserved. Authorized only for instructor use in the classroom. No reproduction or further distribution permitted without the prior
 1.1 Strategies for Success in
Chemistry
Science of Learning Chemistry:
Repetition is central
In physical exercise, repetition is
required to build muscle
In learning, repetition is required for
long-term retention of facts

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 Study Cycle
1. Preview material prior to class
2. Attend class and be an active
participant
3. Review your notes soon after class
4. Study using 3 to 5 short, intense,
formatted study sessions
5. Assess what you know well and
determine what you need to study
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 Study Session Format
1. Establish goal for session in first 2 to
5 min
2. Spend 30 to 50 min studying with
focus
3. Take a 5 to 10 min break
4. After break, review material 5 min

Once a week, review all material you
have been studying for the week
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 1.2 The Discovery Process

Chemistry:
the study of matter
its chemical and physical properties
the chemical and physical changes it
undergoes
As matter undergoes changes, it gains or
loses energy

Matter - anything that has mass and
occupies space
Energy - the ability to do work to
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 Role of Chemistry

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 The Scientific Method
Scientific Method - a systematic approach
to the discovery of new information
Observation
Formulation of a question
Pattern recognition
Theory development
Hypothesis: attempt to explain observation(s)
Theory: hypothesis supported by extensive testing
Experimentation
Data: the individual result of a single measurement
Results: the outcome of an experiment
Information summarization
Scientific law: summary of a large quantity of
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information
 Representation of the Scientific Method

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 Models in Chemistry
Aid in the
understanding of a
chemical unit or
system
often based on
everyday experience
Ball and stick model
of methane
color coded balls
(atoms)
sticks (attractive
forces holding atoms
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 1.3 The Classification of Matter
Properties - characteristics of matter
scientists can use to categorize
different types of matter

Ways to Categorize matter:
1. By State
2. By Composition

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 Three States of Matter
1. Gas - particles widely separated, no
definite shape or volume solid
2. Liquid - particles closer together,
definite volume but no definite
shape
3. Solid - particles are very close
together, define shape and definite
volume

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 Composition of Matter

Pure substance - a substance that has only
one component
Mixture - a combination of two or more
pure substances in which each substance
retains its own identity, not undergoing a
chemical reaction
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 Pure Substances

Element - a pure substance that cannot be
changed into a simpler form of matter by
any chemical reaction
Compound - a pure substance resulting
from the combination of two or more
elements in a definite, reproducible way, in a
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 Mixture

Mixture - a combination of two or more pure
substances in which each substance retains
its own identity
Homogeneous - uniform composition,
particles well mixed, thoroughly intermingled
Heterogeneous – nonuniform composition,
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 Classes of Matter

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 Physical Property versus Physical
Change
Physical property - is observed
without changing the composition or
identity of a substance
Physical change - produces a
recognizable difference in the
appearance of a substance without
causing any change in its composition
or identity
conversion from one physical state to
another
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 Physical Properties and Physical
Change

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 Separation by Physical Properties

Magnetic iron is separated from other
nonmagnetic substances, such as sand. This
property is used as a large-scale process in
the recycling industry.
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 Chemical Property versus Chemical
Reaction
Chemical property - results in a
change in composition and can be
observed only through a chemical
reaction
Chemical reaction (chemical
change) - a chemical substance is
converted in to one or more different
substances by rearranging, removing,
hydrogen  oxygen water
replacing, or adding atoms
reactants products
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 Classification of Properties
Classify the following as either a
chemical or physical property:
a. Color
b. Flammability
c. Hardness
d. Odor
e. Taste

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 Classification of Changes
Classify the following as either a
chemical or physical change:
a. Boiling water becomes steam
b. Butter turns rancid
c. Burning of wood
d. Mountain snow melting in spring
e. Decay of leaves in winter

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 Intensive and Extensive Properties
Intensive properties - a property of
matter that is independent of the
quantity of the substance
Color
Melting Point

Extensive properties - a property of
matter that depends on the quantity of
the substance
Mass
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 1.4 The Units of Measurement
Units - the basic quantity of mass, volume
or whatever quantity is being measured
A measurement is useless without its
units
English system - a collection of
functionally unrelated units
Difficult to convert from one unit to
another
1 foot = 12 inches = 0.33 yard = 1/5280
miles
Metric System - composed of a set of
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 Metric System Units 1

Mass - the quantity of matter in an
object
not synonymous with weight
Weight = mass × acceleration due to gravity
standard unit is the gram (g)
The pound (lb) is the common English unit
1 lb = 454 g

Mass must be measured on a balance (not a
scale)
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 Metric System Units 2

Length - the distance between two
points
standard unit is the meter (m)
The yard is the common English unit
1 yd = 0.914 m
Volume - the space occupied by an
object
standard unit is the liter (L)
The quart is the common English unit
1 qt = 0.946 L
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 Metric System Prefixes
Basic units are the units of a quantity
without any metric prefix
Prefix Abbreviati Meaning Decimal Equality with major
on Equivalent metric units (g, m, or L
are represented by x in
each)
mega M 106 1,000,000. 1 Mx = 106 x
kilo k 103 1,000. 1 kx = 103 x
deka da 101 10. 1 dax = 101 x
deci d 10−1 0.1 1 dx = 10−1 x
centi c 10−2 0.01 1 cx = 10−2 x
milli m 10−3 0.001 1 mx = 10−3 x
micro μ 10−6 0.000001 1 μx = 10−6 x
nano n 10−9 0.000000 1 nx = 10−9 x
001
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 Relationship among
various volume units
Volume 
Length width height
Volume 
1 dm 1 dm 1 dm 
3
1 dm
3
1 dm 1 L
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 1.5 The Numbers of Measurement
Information-bearing digits or figures in
a number are significant figures

The measuring device used
determines the number of significant
figures in a measurement

The degree of uncertainty associated
with a measurement is indicated by
the number of figures used to
represent the information
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 Significant Figures Example

Significant figures - all digits in a
number representing data or results
that are known with certainty plus one
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 Recognition of Significant Figures
All nonzero digits are significant
7.314 has four significant digits

The number of significant digits is
independent of the position of the
decimal point
73.14 also has four significant digits

Zeros located between nonzero digits
are significant
60.052 has five significant digits
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 Use of Zeros in Significant Figures
Zeros at the end of a number (trailing
zeros) are:
Significant if the number contains a
decimal point
4.70 has three significant digits
Insignificant if the number does not
contain a decimal point
100 has one significant digit; 100. has three

Zeros to the left of the first nonzero
integer are not significant
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 How many significant figures are in
the following?
1. 3.400

2. 3004

3. 300.

4. 0.003040

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 Scientific Notation
Used to express very large or very
small numbers easily and with the
correct number of significant figures
Represents a number as a power of ten
Example:
3
4,300 4.3 1, 000 4.3 10

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 Scientific Notation Rules 1

To convert a number greater than 1 to
scientific notation, the original
decimal point is moved x places to the
left, and the resulting number is
multiplied by 10x
The exponent x is a positive number equal
to the number of places the decimal
3 point
moved 6200 6.2 10
What if you want to express the above number
with three significant figures?
3
6.2 10
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 Scientific Notation Rules 2

To convert a number less than 1 to
scientific notation, the original
decimal point is moved x places to
the right, and the resulting
number is multiplied by 10−x

The exponent x is a negative number
equal to the number of places
3
the
0.0062
decimal point 6.2 10
moved

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 Scientific Notation Example
When a number is exceedingly large or
small, scientific notation must be used
to input the number into a calculator:
0.000000000000000000000006692 g
must be entered into calculator as:
 24
6.692 10

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 Represent the following numbers in
scientific notation:
1. 0.00018

2. 3004

3. 300.

4. 0.00304

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 Accuracy and Precision
Accuracy - the degree of
agreement between the
true value and the
measured value
Error - the difference
between the true value
and our estimation
Random
Systematic

Precision - a measure of
the agreement of replicate
measurements
Deviation – amount of
variation present in a set
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 Exact (Counted) and Inexact
Numbers
Inexact numbers have uncertainty
(degree of doubt in final significant
digit)
Exact numbers are a consequence of
counting
A set of counted items (beakers on a
shelf) has no uncertainty
Exact numbers by definition have an
infinite number of significant figures

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 Rules for Rounding Numbers
When the number to be dropped is less
than 5, the preceding number is not
changed
When the number to be dropped is 5
or larger, the preceding number is
increased by one4 unit
3.34966 10
Round the following 4 number to 3
 3.35 10
significant figures:

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 Round off each number to three
significant figures:
1. 61.40

2. 6.171

3. 0.066494

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 Significant Figures in Calculation
of Results
Rules for Addition and Subtraction
The result in a calculation cannot have
greater significance than any of the
quantities that produced the result
Consider:
37.68
liters
6.71862
liters
108.428
liters
correct answer 152.83 liters
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 Report the result of each to the proper
number of significant figures:

1. 4.26 + 3.831

2. 8.321 − 2.4

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 Adding and Subtracting in Scientific
Notation
There are two ways to solve the following:
6 5
9.47 10  9.3 10
SOLUTION 1: convert both numbers to
standard form and add

0.000009
47
+ 0.000093
0.000102
correct
47 answer 1.02 × 10 −4

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 Addition Example
There are two ways to solve the following:
6 5
9.47 10  9.3 10
SOLUTION 2: change one of the
exponents so that both have the same
power of 10, then add
9.47 × 10−60.9
changes
47 × to 0.947 × 10−5

10−5
+ 9.3 ×
10−5
correct
10.2 47 × answer 1.02 × 10 −4

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 Rules for Multiplication and Division
The answer can be no more precise than the
least precise number from which the answer
is derived
The least precise number is the one with the
fewest significant
3
figures
(4.2 10 )(15.94)
4
2.96886918 (on calculator)
2.255 10
Which number has the fewest
significant figures? 4.2  103 has only 2
The answer is therefore, 3.0
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 1.6 Unit Conversion
Factor-Label Method (Dimensional
Analysis)
Uses Conversion Factors to:
Convert from one unit to another within
the same system
Convert units from one system to
another

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 English Unit Conversion - Example
To convert from one unit to another
you must know the conversion factor,
which is the relationship between the
two units

The Relationship:
1 gal = 4 qt

The Conversion Factor:
1 gal 4 qt
or
4 qt 1 gal
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 Using Conversion Factors
Convert 12 gallons to quarts
The Relationship (English system):
1 gal = 4 qt
The Conversion Factor:
1 gal 4 qt
or
4 qt 1 gal
Data Given: 12 gal
Use Conversion Factor with gal in
denominator
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 Using Conversion Factors - Solution
Convert 12 gallons to quarts
Solution:
Write the Data Given
Multiply by the Conversion Factor with
the unit of the Data Given (gal) in the
denominator 4 qt
12 gal  48 qt
1 gal
Desired Result
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 Unit Conversion - Example
Convert 360 feet to miles
The Relationship (English system):
5280 ft = 1 mi

The Conversion Factor:
5280 ft 1 mi
or
1 mi 5280 ft
Data Given: 360 ft
Use Conversion Factor with ft in
denominator
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 Unit Conversion - Solution
Convert 360 feet to miles
Solution:
Write the Data Given
Multiply by the Conversion Factor with
the unit of the Data Given (ft) in the
denominator 1 mi
360 ft  0.068 miles
5280 ft
Desired Result
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 Multistep Conversion - Example
Convert 0.0047 kilograms to
milligrams
The Relationships (metric system):
1 kg = 103 g and 103 mg = 1 g
The 103 g Factors:
1 kgConversion 1 mg 10 3 g
3
or and 3
or
10 g 1 kg 10 g 1 mg
Data Given: 0.0047 kg
1. Use Conversion Factor with kg in
denominator to convert to Initial Data
Result in g
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 Multistep Conversion - Solution
Convert 0.0047 kilograms to
milligrams
3
10 g
0.0047 kg  4.7 g
1 kg
Data Given × Conversion Factor = Initial Data
Result
1 mg 3
4.7 g   3 4.7 10 mg
10 g
Initial Data Result × Conversion Factor = Desired
Result
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 Multistep Conversions - Alternate
Solution
Convert 0.0047 kilograms to
milligrams
Alternatively, solve in a single step:
3
10 g 1 mg 3
0.0047 kg    3 4.7 10 mg
1 kg 10 g

Data Given × Conversion Factor × Conversion
Factor
= Desired Result

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 Practice Unit Conversions
1. Convert 5.5 inches to millimeters

2. Convert 50.0 milliliters to pints

3. Convert 1.8 in2 to cm2

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 1.7 Additional Experimental
Quantities
Temperature - the degree of
“hotness” of an object

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 Conversions Between Fahrenheit
and Celsius

T F  32
T C 
1.8
T F 1.8 T C  32

1. Convert 75 degrees C to degrees F
2. Convert −10 degrees F to degrees C

1. Answer: 167 2. Answer: −23
degrees F
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degrees C
 Kelvin Temperature Scale
The Kelvin (K) scale is another
temperature scale
It is of particular importance because it
is directly related to molecular motion
As molecular speed increases, the
Kelvin temperature proportionately
increases
TK T C  273.15
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 Energy
Energy - the ability to do work
kinetic energy - the energy of motion (energy
of action)
potential energy - the energy of position
(stored energy)

Energy is also categorized by form:
light
heat
electrical
mechanical
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 Characteristics of Energy
Energy cannot be created or destroyed
Energy may be converted from one
form to another
Energy conversion always occurs with
less than 100% efficiency
All chemical reactions involve either a
“gain” or “loss” of energy

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 Units of Energy
Basic Units:
calorie or joule
1 calorie (cal) = 4.18 joules (J)

kilocalorie (kcal) = food Calorie
1 kcal = 1 Calorie = 1000 calories
1 calorie = amount of heat energy
required to increase the temperature
of 1 gram of water 1 degree C.
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 Concentration
Concentration:
the number or mass of particles of a
substance contained in a specified volume
Often used to represent the mixtures
of different substances
Concentration of oxygen in the air
Pollen counts
Proper dose of an antibiotic

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 Density and Specific Gravity
Density
the ratio of mass to volume
mass m
d 
volume V
an extensive property
use to characterize a substance as each
substance has a unique density
Units for density include:
g/mL
g/cm3
g/cc
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 Density
Examples

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 Densities of Some Common
Materials
Substance Density (g/mL) Substan Density (g/mL)
ce
Air 0.00129 (at 0 degrees Mercury 13.6
C)
Ammonia 0.000771 (at 0 Methanol 0.792
degrees C)
Benzene 0.879 Milk 1.028 to 1.035
Blood 1.060 Oxygen 0.00143 (at 0
degrees C)
Bone 1.7 to 2.0 Rubber 0.9 to 1.1
Carbon 0.001963 (at 0 Turpentin 0.87
dioxide degrees C) e
Ethanol 0.789 Urine 1.010 to 1.030
Gasoline 0.66 to 0.69 Water 1.000 (at 4 degrees
C)
Gold 19.3 Water 0.998 (at 20
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 Calculating Density
A 2.00 cm3 sample of aluminum is
found to weigh 5.40 g. Calculate the
density in g/cm3 and g/mL.
Use the expression:
Density (d) = m/V

5.40information
Substitute g given
3
into the
d
expression 3
2.70 g cm
2.00 cm
Since 1 cm3 = 1 mL,
= 2.70 g/mL
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 Use Density in Calculation
Calculate the volume, in mL, of a liquid
that has a density of 1.20 g/mL and a
mass of 5.00 g.
Density can
1.20beg written as1amL
Conversion
Factor or
1 mL 1.20 g
Multiply the Data Given (g) by the
Conversion Factor with the unit g in the
denominator 1 mL
5.00 g  4.17 mL
1.20 g
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 Density Calculations
Air has a density of 0.0013 g/mL.
What is the mass of 6.0-L sample of
air?
Calculate the mass in grams of 10.0
mL if mercury (Hg) if the density of Hg
is 13.6 g/mL.
Calculate the volume in milliliters, of a
liquid that has a density of 1.20 g/mL
and a mass of 5.00 grams.
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 Specific Gravity
Values of density are often related to a
standard
Specific gravity - the ratio of the density of
the object in question to the density of pure
water at 4 degrees C
Specific gravity is a unitless term because
the 2 units cancel
Often the health industry uses  g 
specific
density of object 
gravity to test urine and blood samples mL 
specific gravity 
 g 
density of water 
 mL 
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