Chemistry: The Central Science PDF

Summary

This document provides an introduction to chapter 1 of Chemistry: The Central Science. It covers basic concepts such as matter, its different forms (solid, liquid, gas), and the various types of properties. The chapter also introduces the concept of intensive and extensive properties, and provides examples of units of measurement.

Full Transcript

Chapter 1
Chemistry:
The Central Science

1
 1.1 The Study of Chemistry
Chemistry
– the study of all aspects of matter and the
changes that matter undergoes
Matter
– anything that has mass and occupies
space

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 Chemistry you may already know
– Familiar terms: molecules, atoms, and
chemical reactions
Familiar chemical formula: H2O

3
 Molecules can be represented several
different ways including molecular
formulas and molecular models.

– Molecular models can be “ball-and-stick” or
“space-fill.” Each element is represented
by a particular color

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5
 1.2: Classification of Matter
Matter is either classified as a substance or
a mixture of substances.
Substance
– Can be either an element or a compound
– Has a definite (constant) composition and
distinct properties
– Examples: sodium chloride, water, oxygen

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 Substances
Element: cannot be separated into
simpler substances by chemical means.
– Examples: iron, mercury, oxygen, and
hydrogen
Compounds: two or more elements
chemically combined in definite ratios
– Cannot be separated by physical means
– Examples: salt, water and carbon dioxide

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 Mixtures
Mixture: physical combination of two or
more substances
– Substances retain distinct identities
– No universal constant composition
– Can be separated by physical means
Examples: sugar/iron; sugar/water

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Molecular Comparison of Substances and Mixtures

Atoms of an element Molecules of an element

Molecules of a compound Mixture of two elements
and a compound
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 Types of Mixtures
– Homogeneous: composition of the mixture
is uniform throughout
Example: sugar dissolved in water
– Heterogeneous: composition is not
uniform throughout
Example: sugar mixed with iron filings

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Classification of Matter

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 Classify the following
Aluminum foil
Baking soda
Milk
Air
Copper wire

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Aluminum foil:
substance, element
Baking soda:
substance, compound
Milk:
mixture, homogeneous
Air:
mixture, homogeneous
Copper wire:
substance, element
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 1.3 Properties of Matter
Quantitative: expressed using numbers

Qualitative: expressed using properties

Physical properties: can be observed and measured
without changing the substance
– Examples: color, melting point, states of matter

Physical changes: the identity of the substance stays
the same
– Examples: changes of state (melting, freezing)
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 States of Matter

– Solid

particles close together in orderly fashion

little freedom of motion

a solid sample does not conform to the shape of its
container

– Liquid

particles close together but not held rigidly in position

particles are free to move past one another

a liquid sample conforms to the shape of the part of the
container it fills
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 – Gas
particles randomly spread apart
particles have complete freedom of
movement
a gas sample assumes both shape and
volume of container.

States of matter can be inter-converted
without changing chemical composition
solid ® liquid ® gas (add heat)
gas ® liquid ® solid (remove heat)
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States of Matter

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 Chemical properties: must be determined
by the chemical changes that are observed
– Examples: flammability, acidity, corrosiveness,
reactivity

Chemical changes: after a chemical change,
the original substance no longer exists
– Examples: combustion, digestion

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 Extensive property: depends on amount of
matter
– Examples: mass, length

Intensive property: does not depend on
amount
– Examples: density, temperature, color

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 1.4 Scientific Measurement
Used to measure quantitative properties of
matter
SI base units

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SI Prefixes

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 Mass: measure of the amount of matter
– (weight refers to gravitational pull)
Temperature:
– Celsius
Represented by °C
Based on freezing point of water as 0°C and
boiling point of water as 100°C
– Kelvin
Represented by K (no degree sign)
The absolute scale
Units of Celsius and Kelvin are equal in
magnitude
– Fahrenheit (the English system) (°F)

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Equations for Temperature Conversions

5
o
C = ( F - 32) ´
o

9

K = C + 273.15
o

9
o
F = ´ C + 32
o

5

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 Temperature Conversions

A clock on a local bank reported a
temperature reading of 28oC. What is this
temperature on the Kelvin scale?

K = C + 273.15
o

K = 28 C + 273.15 = 301 K
o

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 Practice
Convert the temperature reading on the
local bank (28°C) into the corresponding
Fahrenheit temperature.
9
o
F = ´ C + 32
o

5
9
o
F = ´ 28 C + 32 = 82 F
o o

5

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 Volume: meter cubed (m3)
– Derived unit
– The unit liter (L) is more commonly used in the
laboratory setting. It is equal to a decimeter
cubed (dm3).

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 Density: Ratio of mass to volume
– Formula: m
d=
V

– d = density (g/mL)
– m = mass (g)
– V = volume (mL or cm3)
(*gas densities are usually expressed in g/L)
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 Practice
The density of a piece of copper wire is 8.96
g/cm3. Calculate the volume in cm3 of a piece
of copper with a mass of 4.28 g.

m
d=
V
m 4.28 g
V= = = 0.478 cm 3

d 8.96 g
3
cm
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 1.5 Uncertainty in Measurement

Exact: numbers with defined values
– Examples: counting numbers, conversion
factors based on definitions

Inexact: numbers obtained by any method
other than counting
– Examples: measured values in the laboratory

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 Significant figures

– Used to express the uncertainty of inexact
numbers obtained by measurement

– The last digit in a measured value is an
uncertain digit - an estimate

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Guidelines for significant figures

– Any non-zero digit is significant

– Zeros between non-zero digits are significant

– Zeros to the left of the first non-zero digit are not
significant

– Zeros to the right of the last non-zero digit are
significant if decimal is present

– Zeros to the right of the last non-zero digit are not
significant if decimal is not present

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 Practice
Determine the number of significant figures in
each of the following.
345.5 cm
4 significant figures
0.0058 g
2 significant figures
1205 m
4 significant figures
250 mL
2 significant figures
250.00 mL
5 significant figures
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Calculations with measured numbers
– Addition and subtraction
Answer cannot have more digits to the
right of the decimal than any of original
numbers
Example:

102.50 two digits after decimal point
+ 0.231 three digits after decimal point
102.731 round to 102.73
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 Multiplication and division
– Final answer contains the smallest
number of significant figures
– Example:

1.4 x 8.011 = 11.2154 round to 11

(Limited by 1.4 to two significant figures in answer)

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 Exact numbers
– Do not limit answer because exact
numbers have an infinite number of
significant figures
– Example:
A penny minted after 1982 has a mass of
2.5 g. If we have three such pennies, the
total mass is
3 x 2.5 g = 7.5 g
– In this case, 3 is an exact number and
does not limit the number of significant
figures in the result.

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 Multiple step calculations
– It is best to retain at least one extra
digit until the end of the calculation to
minimize rounding error.
Rounding rules
– If the number is less than 5 round
“down”.
– If the number is 5 or greater round
“up”.

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 Practice
105.5 L + 10.65 L = 116.2 L
Calculator answer: 116.15 L
Round to: 116.2 L Answer to the tenth position

1.0267 cm x 2.508 cm x 12.599 cm = 32.44 cm3
Calculator answer: 32.4419664 cm3
Round to: 32.44 cm3 round to the smallest
number of significant figures

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 Accuracy and precision

– Two ways to gauge the quality of a set of
measured numbers

– Accuracy: how close a measurement is
to the true or accepted value

– Precision: how closely measurements of
the same thing are to one another

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both accurate and precise

not accurate but precise

neither accurate nor precise

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Describe accuracy and precision for each
set

Student A Student B Student C
0.335 g 0.357 g 0.369 g
0.331 g 0.375 g 0.373 g
0.333 g 0.338 g 0.371 g
Average:
0.333 g 0.357 g 0.371 g

True mass is 0.370 grams

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Student A’s results are precise but not accurate.

Student B’s results are neither precise nor accurate.

Student C’s results are both precise and accurate.
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 1.6 Using Units and Solving
Problems
Conversion factor: a fraction in which
the same quantity is expressed one way
in the numerator and another way in the
denominator
– Example: by definition, 1 inch = 2.54 cm

1 in 2.54 cm
2.54 cm 1 in
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 Dimensional analysis: a problem solving method
employing conversion factors to change one measure to
another often called the “factor-label method”
– Example: Convert 12.00 inches to meters

Conversion factors needed:

2.54 cm = 1 in and 100 cm = 1 meter

2.54 cm 1m
12.00 in ´ ´ = 0.3048 m
1 in 100 cm

*Note that neither conversion factor limited the number of significant
figures in the result because they both consist of exact numbers.
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 Notes on Problem Solving
Read carefully; find information given and
what is asked for
Find appropriate equations, constants,
conversion factors
Check for sign, units and significant figures
Check for reasonable answer

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 Practice
The Food and Drug Administration (FDA)
recommends that dietary sodium intake
be no more than 2400 mg per day. What
is this mass in pounds (lb), if 1 lb = 453.6 g?

1g 1 lb -3
2400 mg ´ ´ = 5.3 ´ 10 lb
1000 mg 453.6 g

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 Key Points
Classifying matter
SI conversions
Density
Temperature conversions
Physical vs chemical properties and
changes
Dimensional analysis

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