Transcript Introductory Chemistry: Concepts & Connections 4th Edition
Introductory Chemistry:
Chapter 1
Chemistry and You
Tuesday, 9/9/14
•
Learning Target
: Students must be able to explain why chemistry is central to many human endeavors.
Chapter 1 2
Learning Chemistry
• Different people learn chemistry differently.
• What do you see in the picture?
• Some people see a vase on a dark background, some people see two faces.
Chapter 1 3
Problem Solving
• Connect the 9 dots using only four straight lines.
• Experiment until you find a solution.
• However, we have used 5 straight lines.
• No matter which dot we start with, we still need 5 lines.
Chapter 1 4
Problem Solving
• Are we confining the problem?
• We need to go beyond the 9 dots to answer the problem.
Chapter 1 5
D.
G.
A.
Lab Safety Symbols Identify the following symbols
B.
C.
E.
H.
F.
I.
• What is the definition of chemistry?
– The science that studies the composition of matter and its properties.
Chemistry: The Central Science
• Why????
• Most other sciences demand an understanding of basic chemical principles, and Chemistry is often referred to as the Central Science Chapter 1 8
Modern Chemistry
•
Chemistry
is a science that studies the composition of matter and its properties.
• Chemistry is divided into several branches: –
Organic chemistry
is the study of substances containing carbon –
Inorganic chemistry
is the study of all other substances –
Biochemistry
is the study of substances derived from plants and animals –
Analytical
is the study of matter and ways to study the properties of matter.
–
Physical
is the physics of chemistry. Thermodynamics and quantum mechanics.
Chapter 1 9
Wednesday, 9/10/14
Learning Target:
Students must know the metric system, SI units and derived units.
Learning Outcome
: Measurement Pre-Lab Chapter 1 10
The Standard Units
• Scientists have agreed on a set of international standard units for comparing all our measurements called the SI units
Quantity
length mass time temperature
Unit
meter kilogram second kelvin
Symbol
m kg s K
Length
• SI unit = meter – About a yard • Commonly use centimeters (cm) – 1 m = 100 cm – 1 cm = 0.01 m = 10 mm – 1 inch = 2.54 cm
Mass
• Measure of the amount of matter present in an object – weight measures the gravitational pull on an object, which depends on its mass • SI unit = kilogram (kg) – about 2 lbs. 3 oz.
• Commonly measure mass in grams (g) or milligrams (mg)
Time
• measure of the duration of an event • SI units = second (s)
Temperature Scales
• Fahrenheit Scale, °F – used in the U.S.
• Celsius Scale, °C – used in all other countries • Kelvin Scale, K – The SI unit for temperature
Prefix
mega kilo deci centi milli micro nano pico M k d c m m n p Prefix Multipliers in the SI System
Symbol Decimal Equivalent Power of 10
1,000,000 1,000 0.1
Base x 10 6 Base x 10 3 Base x 10 -1 Base x 10 -2 0.01
0.001
0.000 001 Base x 10 -3 Base x 10 -6 0.000 000 001 Base x 10 -9 0.000 000 000 001 Base x 10 -12
What Is a Measurement?
• quantitative observation • every measurement has a number and a unit • every digit written is certain, the last one which is estimated
Estimation in Weighing
• What is the uncertainty in this reading?
Thursday, 9/11/14
Learning Target:
Students must be able to compare and contrast accuracy and precision in measurement.
Learning Outcome
: Complete “Measurement Lab” Chapter 1 20
Uncertainty in Measured Numbers
uncertainty comes from: • limitations of the instruments used for comparison, • the experimental design, • the experimenter, • nature’s random behavior
Precision and Accuracy
•
accuracy
is an indication of how close a measurement comes to the
actual
value of the quantity Percent error = •
precision
is an indication of how reproducible a measurement is
Accuracy vs. Precision
Precision
• imprecision in measurements is caused by
random errors
– errors that result from random fluctuations • we determine the precision of a set of measurements by evaluating how far they are from the actual value and each other called standard deviation.
• Do multiple trials to lesson error and improve precision.
Accuracy
• inaccuracy in measurement caused by
systematic errors
– errors caused by limitations in the instruments or techniques or experimental design • we determine the accuracy of a measurement by evaluating how far it is from the actual value • Use
percent error
to calculate how accurate you are
Mass & Volume
• mass and volume are
extensive properties
– the value depends on the quantity of matter – extensive properties cannot be used to identify what
type
of matter something is • if you are given a large glass containing 100 g of a clear, colorless liquid and a small glass containing 25 g of a clear, colorless liquid - are both liquids the same stuff?
Mass vs. Volume of Brass
Mass grams
20
Volume cm 3
2.4 32 40 50 100 150 3.8 4.8 6.0 11.9 17.9
Monday 9/15/14
Learning Target:
Know how to use significant figures in labs and in problems.
Learning Outcome:
Complete significant figures problems.
Chapter 1 28
Accuracy versus Precision
Chapter 1 29
Significant Figures
• the non-place-holding digits in a reported measurement are called
significant figures
• significant figures tell us the range of values to expect for repeated measurements • We use significant figures in science because measurement is always involved.
Counting Significant Figures
1) All non-zero digits are significant – 1.5 has 2 sig. figs.
2) Interior zeros are significant – 1.05 has 3 sig. figs.
3) Leading zeros are
NOT
significant – 0.001050 has 4 sig. figs.
Counting Significant Figures
4) Trailing zeros may or may not be significant
1) If a decimal is present
, t railing zeros are significant • 1.050 has 4 sig. figs.
2) If a decimal is NOT present
, trailing zeros are NOT significant. • • if 150 has 2 sig. figs. then 1.5 x 10 2 but if 150. has 3 sig. figs. then 1.50 x 10 2 **These are considered ambiguous and should be avoided by using scientific notation
Determining the Number of Significant Figures in a Number How many significant figures are in each of the following?
0.04450 m 5.0003 km 1.000 × 10 5 s 4 sig. figs.; the digits 4 and 5, and the trailing 0 5 sig. figs.; the digits 5 and 3, and the interior 0’s 0.00002 mm 10,000 m 4 sig. figs.; the digit 1, and the trailing 0’s 1 sig. figs.; the digit 2, not the leading 0’s Ambiguous, generally assume 1 sig. fig.
Multiplication and Division with Significant Figures
• when multiplying or dividing measurements with significant figures, the answer must reflect the fewest number of significant figures
1) 5.02 × 89,665 × 0.10 = 2) 5.892 ÷ 6.10 =
Addition and Subtraction with Significant Figures
• when adding or subtracting measurements with significant figures, the answer should reflect the largest uncertainty
1) 5.74 + 0.823+ 2.651 = 2) 4.8 - 3.965 =
Rounding
if the number after the place of the last significant figure is: 0 to 4, round down – drop all digits after the last sig. fig. and leave the last sig. fig. alone 5 to 9, round up – drop all digits after the last sig. fig. and increase the last sig. fig. by one To avoid accumulating extra error from rounding, round only at the end, keeping track of the last sig. fig. for intermediate calculations
Rounding
rounding to 2 significant figures • 2.34 rounds to 2.3
• 2.37 rounds to 2.4
• 2.349865 rounds to 2.3
Rounding
rounding to 2 significant figures • 0.0234 rounds to 0.023
• 0.0237 rounds to 0.024
• 0.02349865 rounds to 0.023
Rounding
rounding to 2 significant figures • 234 rounds to 230 • 237 rounds to 240 • 234.9865 rounds to 230
Both Multiplication/Division and Addition/Subtraction with Significant Figures
• First, evaluate the significant figures in the parentheses • Second, do the remaining steps
3.489 × (5.67 – 2.3) =
Perform the following calculations to the correct number of significant figures a) 1 .
10 0 .
5120 4 .
0015 3 .
4555 b) 0 .
355 105 .
1 100 .
5820 c) 4 .
562 3 .
99870 452 .
6755 452 .
33 d) 14 .
84 0 .
55 8 .
02
Example 1.6 Perform the following calculations to the correct number of a) 1 .
10 0 .
5120 significant figures 4 .
0015 3 .
4555 0 .
65219 0 .
652 b) 0 .
355 105 .
1 100 .
5820 4 .
8730 4.9
c) 4 .
562 3 .
99870 452 .
6755 452 .
33 52 .
79904 52 .
80 d) 14 .
84 0 .
55 8 .
02 0 .
142 0 .
14
Tuesday 9/16/14
Learning Target:
Know how to use and convert numbers into scientific notation.
Learning Outcome:
I will be able to use scientific notation in problems and convert standard notation into scientific notation.
Chapter 1 43
•
Why are significant figures not important in your math class?
Chapter 1 44
Density
• Ratio of mass:volume – Solids = g/cm 3 • 1 cm 3 = 1 mL – Liquids = g/mL – Gases = g/L • Volume of a solid can be determined by water displacement – Archimedes Principle
Density
• Density : solids > liquids >>> gases – except ice is less dense than liquid water!
• Heating an object generally causes it to expand, therefore the density changes with temperature
Density
• Iron has a density of 7.86 g/cm 3 . Could a block of metal with a mass of 18.2 g and a volume of 2.56 cm 3 be iron?
Density
• What volume would a 0.871 g sample of air occupy if the density of air is 1.29 g/L?
Wednesday, 9/17/14
Learning Target:
Be able to apply dimensional analysis to convert from one unit of measure to another.
Learning Outcome:
I will be able to complete single-step unit conversion problems.
Chapter 1 49
Units
• Always include units in your calculations – you can do the same kind of operations on units as you can with numbers • cm × cm = cm • cm + cm = cm • cm ÷ cm = 1 2
Dimensional Analysis
• Using units as a guide to problem solving is called
dimensional analysis
• This is the technique that we have learned to convert between two different units.
Problem Solving and Conversion Factors
• Conversion factors are relationships between two units – May be exact or measured • Conversion factors are generated from unit equalities – e.g., 1 inch = 2.54 cm can give 2 .
54 cm 1 in or 1 in 2 .
54 cm
Problem Solving and Dimensional Analysis
• Arrange conversion factors so given unit cancels – Arrange conversion factor so given unit is on the bottom of the conversion factor • May string conversion factors – So we do not need to know every relationship, as long as we can find something else the given and desired units are related to given unit desired unit given unit desired unit
• •
Using a ruler from the front counter, measure the length, width and height of a Chemistry textbook to the nearest 1 cm.
How many meters wide is it?
•
How many inches is the width of the textbook (2.54 cm = 1 in)?
•
How many feet is your textbook?
54
Thursday, 9/18/14
Learning Target:
Be able to apply dimensional analysis to convert from one unit of measure to another.
Learning Outcome:
I will be able to complete multi-step unit conversion problems.
Chapter 1 55
Warm-Up
Convert – 232.1 kPa to Pa Chapter 1 56
Practice – Convert 154.4 lbs to kg
Practice – Convert 30.0 mL to quarts
(1 L = 1.057 qt)
– any length unit cubed occupied
Volume
• Derived unit (width x length x height) • Measure of the amount of space • SI unit = cubic meter (m cubic centimeters (cm – 1 m – 3 = 10 6 cm
1 mL = 1 cm 3
3 3 ) volume in milliliters (mL) 3 ) • Commonly measure solid volume in • Commonly measure liquid or gas – 1 L is slightly larger than 1 quart
How many cubic centimeters are there in 2.11 yd
3
?
Impossible Conversions
• Is it possible to find how many seconds in a kilogram?
• In order to do unit conversions they must be able to correspond to the same quantity.
– For example, kilograms and pounds are both units of mass.
Graphing in Science
• All graphing that is done in science must include the following: 1. A descriptive title 2. X and Y axis labeled with units.
3. The X – axis is the manipulated variable and the Y- axis is the responding variable.
4. A trend line (or line of best fit) to show the trend in the data that has been plotted.
Volume vs. Mass of Brass
160 140 120 100 80 60 40 20 0 0.0
2.0
4.0
6.0
8.0
10.0
Volume, cm 3
12.0
14.0
16.0
18.0
• •
Convert 30.0 mL to quarts
Sort information Strategize
Given: Find: Concept Plan:
154.4 lbs Lbs to kg
Relationships:
1 L = 1.057 qt 1 L = 1000 mL • • • Follow the concept plan to
solve
the problem Sig. figs. and round Check
Solution: Round:
0.03171 qt = 0.0317 qt
Check:
Units & magnitude are correct
Scientific Investigations
• Science is the methodical exploration of nature followed by a logical explanation of the observations.
• Scientific investigation entails: – planning an investigation – carefully recording observations – gathering data – analyzing the results 65
The Scientific Method
• The
scientific method
is a systematic investigation of nature and requires proposing an explanation for the results of an experiment in the form of a general principle.
• The initial, tentative proposal of a scientific principle is called a
hypothesis
.
• After further investigation, the original hypothesis may be rejected, revised, or elevated to the status of a scientific principle.
Chapter 1 66
a test of a hypothesis or theory
Scientific Method
a tentative explanation of a single or small number of natural phenomena the careful noting and recording of natural phenomena a general explanation of natural phenomena a generally observed natural phenomenon
Conclusions Continued
• After sufficient evidence, a hypothesis becomes a
scientific theory
.
• A
natural law
is a measurable relationship.
Chapter 1 68
Conclusions
• Scientists use the scientific method to investigate the world around them.
• Experiments lead to a hypothesis, which
may
to a scientific theory or a natural law.
lead • Chemistry is a central science with many branches.
• The impact of chemistry is felt in many aspects of our daily lives.
Chapter 1 69
QUIZE - CHAPTER -1
1. What is the difference between a hypothesis and theory 2. According to the ancient Greeks, which of the following are not basic elements found in nature: I.
Air II. Coal III. Fire IV. Earth V. Gold VI. Water Chapter 1 70