chemistry: chapter 1 introduction to chemistry. distinguish between a scientific law and a...
TRANSCRIPT
Chemistry: Chapter 1
Introduction to Chemistry
Distinguish between a scientific law and a scientific theory.
• Scientific Law• Observation of a
natural event• Summary of what
occurs• Does not try to
explain why something occurs only tells what occurs
• Scientific Theory• Explanation of events• Tries to explain why
something occurs• Supported by several
experiments• Must be able to
predict what happens by using the theory
Explain and apply the steps of the scientific method.
• Observation• Seeing something that
makes you ask a question
• Formulate a question• What exactly do you
want to learn?• Research the question
• Find out what others have said about your question
• Develop a hypothesis• Use the information you
found in research to develop an educated guess in answer to your question
• Experiment/Collect Data• Test only one variable at a
time• Use a control
• Control is a version of the experiment where nothing is changed
• Draw conclusions• Analyze the data• Did the data support your
hypothesis?
Describe the relationship between pure science and technology.
• Pure science studies things that may never be useful
• Pure science seeks only to know• Technology is useful• Technology is applied science• Studying far off galaxies is pure science• Creating a vaccine for a disease is
technology
Distinguish between an independent and dependent variable.
• Independent variable• The variable that you
change in the experiment
• If you place one plant in the window and one in the closet the variable you are changing is the amount of light
• Amount of light would be the independent variable
• Dependent variable• The variable that
changes because of the change in the independent variable
• The plant in the closet is only 6 cm tall. The plant in the window is 12 cm tall.
• Height of the plant would be the dependent variable.
Chemistry: Chapter 2
Data Analysis
SI Units
For a measurement to make sense, it requires both a number and a unit.
Many of the units you are familiar with, such as inches, feet, and degrees Fahrenheit, are not units that are used in science.
Scientists use a set of measuring units called SI, or the International System of Units. The abbreviation stands for the French name Système International d'Unités.
SI is a revised version of the metric system. There are seven primary base units you need to
learn.
Base Units
Metric Prefixes
The metric unit for a given quantity is not always a convenient one to use.
A metric prefix indicates how many times a unit should be multiplied or divided by 10.
Learn these prefixes…
Identify the SI base units and compare the base units to derived
units• Derived units are made up of more than
one base unit• Examples of derived units : g/cm3, g/mol,
m3
• If it is not on the list of base units, it is a derived unit.
Derived Units
Solve density problems.• Density is the Mass divided by the Volume– D = M/V
• The equation can be rearranged to solve for any of the three variables.– M = D x V– V = M/D
• Example• A block of aluminum occupies a volume of 15.0 mL and has a
mass of 40.5 g. What is its density? • M = 40.5 g• V = 15.0 mL• D = M/V D = 40.5g/15.0 mL D = 2.7 g/mL
Density Problems cont. What is the mass of the ethyl alcohol that exactly
fills a 200.0 mL container? The density of ethyl alcohol is 0.789 g/mL. D = 0.789 g/ml (3 sig figs) V = 200.0 mL (4 sig figs) M = D x V M = 0.789g/ml x 200.0 mL M = 158 g (3 sig figs)
Density Problems cont. What volume of silver metal will have a mass of
exactly 2500.0 g. The density of silver is 10.5 g/cm3. D = 10.5 g/cm3
M = 2500.0 g V = M / D V = 2500.0 g/ 10.5 g/cm3
V = 238 cm3 (3 sig figs)
Density Problems cont. A rectangular block of copper metal has a mass of 1896 g. The
dimensions of the block are 8.4 cm by 5.5 cm by 4.6 cm. From this data, what is the density of copper?
First calculate the volume. (V = l x w x h) V = 8.4 cm x 5.5 cm x 4.6 cm V = 212.52 cm3
There are only 2 sig figs in the problem so you must round to 210 cm3
Now calculate the density. M = 1896 g V = 210 cm3
D = M/V D = 1896 g/ 210 cm3 D = 9.03 g/cm3
Can only have 2 sig figs therefore the answer would be 9.0 g/cm3
Density Practice1. Mercury metal is poured into a graduated cylinder that
holds exactly 22.5 mL. The mercury used to fill the cylinder has a mass of 306.0 g. From this information, calculate the density of mercury.
2. A flask that has a mass of 345.8 g is filled with 225 mL of carbon tetrachloride. The mass of the flask and carbon tetrachloride is found to be 703.55 g. From this information, calculate the density of carbon tetrachloride.
3. Calculate the density of sulfuric acid if 35.4 mL of the acid has a mass of 65.14 g.
4. Find the mass of 250.0 mL of benzene. The density of benzene is 0.8765 g/mL.
5. A block of lead has dimensions of 4.50 cm by 5.20 cm by 6.00 cm. The block ‘s mass is 1587 g. From this information, calculate the density of lead.
6. What is the volume of a substance with a mass of 0.35 g and a density of 0.9 g/ml?
Measuring Temperature A thermometer is an instrument that
measures temperature, or how hot an object is.
The two temperature scales that you are probably most familiar with are the Fahrenheit scale and the Celsius scale
You can convert from one scale to the other by using one of the following formulas.
The Kelvin Scale The Kelvin is the SI unit of temperature.
On the Kelvin scale, water freezes at about 273 K and boils at 373 K.
It is easy to convert from Celsius to Kelvin.Kelvin = °C + 273
No degree sign is needed with Kelvin.
Scientific Notation
Use scientific notation to represent very large and small numbers
300 000 000 Only 1 number allowed in
front of the decimal Count the number of times
the decimal must be moved this number becomes the exponent
If the original number is larger than one the exponent is positive
3.0 x 108
0.000 000 03 If the number is smaller
than one the exponent is negative
3.0 x 10-8
Write the following numbers in scientific notation
800 000 000 m 0.0015 kg 60 200 L 0.00095 m 8 002 000 km 0.000 000 000 06 kg 602 000 000 000 000 000 000 000 atoms
Write the following numbers in standard form
4.5 x 105
7.009 x 109
4.6 x 104
3.2 x 1015
3.115 x 10-8 6.05 x 10-3
1.99 x 10-10
3.01 x 10-6
Adding and Subtracting
1. Exponents must be the same or the operation cannot be performed. If the exponents do not agree, change the decimal and the power of ten notation of either number so as to agree with the other.
2. Add or subtract the number.3. Keep the same power of ten.
Multiplying and Dividing MULTIPLICATION:
1. Multiply the numbers.2. Add the exponents for the power of ten.
DIVISION:1. Divide the numbers as in any division problem.2. Subtract the denominator power of ten exponent
from the numerator power of ten exponent.
Dimensional Analysis Suppose you want to convert the height of Mount
Everest, 8848 meters, into kilometers. Based on the prefix kilo-, you know that 1 kilometer is 1000 meters. This ratio gives you two possible conversion factors.
Since you are converting from meters to kilometers, the number should get smaller. Multiplying by the conversion factor on the left yields a smaller number.
Notice that the meter units cancel, leaving you with kilometers (the larger unit).
Convert the following measurements
300 mm = _______m 2 km = ________hm 0.90 cm = _____mm 5.67 dm = _____km 3.6 Gm = _______m 4.5 g= _________g 34 kg = ________mg 45 ms = ________s
6.7 nm = ________m 37 kg = ________cg 23 ml = ________ kl 9.7 dam = ______m 0.0054 cg = _____mg 0.5 cm = _______mm 0.68 Mg = _______cg 1Gm= _________nm
Limits of Measurement
Precision--Precision is a gauge of how exact a measurement is.The precision of a measurement depends on the number of digits in the answer. Significant figures are all the digits that are known in a measurement, plus the last digit that is estimated. The fewer the significant figures, the less precise the measurement is.
Uncertainty
When you make calculations with measurements, the uncertainty of the separate measurements must be correctly reflected in the final result.
The precision of a calculated answer is limited by the least precise measurement used in the calculation.
So if the least precise measurement in your calculation has two significant figures, then your calculated answer can have at most two significant figures.
Accuracy
Accuracy is the closeness of a measurement to the
actual value of what is being measured.
Although an instrument is precise, it does not have to
be accurate.
Precision or Accuracy?
Define significant figures and know when to use them.
• When numbers are measured, measurements are always taken to the first number that is estimated (guessed).
• This is the last significant figure.• If the measurement is 100, the actual number
could be anywhere from 50-149.• If the measurement is 100.0 then it can only vary
from 99.5 and 100.4.• Significant figures indicate precision of
measurement.
Use significant figures in problem solving.
The answer to a problem cannot have more significant figures than the number in the problem with the fewest significant figures.
Once the correct number of significant figures has been reached, zeroes are used as place holders
76543210 written in 3 significant figures would be 76500000
Cannot drop the zeros. You wouldn’t want me to pay you 10 dollars if I owed you 1000. Dropping zeroes changes the value of the number. Round then hold the place with zeroes to keep the value the same.
If the number following the last significant figure is 5 or greater the last significant figure goes up one.
If the number following the last significant figure is 4 or less the last significant figure stays the same.
Rules for Significant Figures1. All non-zero numbers are always significant.2. Zeros between non-zero numbers are always
significant.3. All final zeros to the right of the decimal place
are significant.4. Zeros that act as placeholders are not
significant. Convert quantities to scientific notation to remove the placeholder zeros.
5. Counting numbers and defined constants have an infinite number of significant figures.
Determine the number of significant figures in each of the following:
1.560 1560 0.01560 300000 290100000 0.000002390
0.000000000002 14.9800 100 100.0 20000.0 3009000
Rounding
A calculated value with eight significant figures is not appropriate when you only need four significant figures.
Rules for Rounding
1. If the digit to the immediate right the last significant figure is less than five, do not change the last significant figure.
2. If the digit to the immediate right of the last significant figure is greater than five, round up the last significant figure.
3. If the digit to the immediate right of the last significant figure is equal to five and is followed by a nonzero digit, round up the last significant figure.
4. If the digit to the immediate right of the last significant figure is equal to five and is not followed by a nonzero digit, look at the last significant figure. If it is an odd digit, round it up. If it is an even digit, do not round up.
Round the following to 3 significant figures:
4.900 4.905 20087 653456 928227 5.596 300.0 (try scientific notation)
Rules for Significant Figures with Operations
When adding and subtracting numbers, your answer should have the same number of digits to the right of the decimal point.
Examples
1. 43.2 cm+ 51.0cm+ 48.7 cm2. 258.3 kg + 257.11 kg + 253 kg3. 0.0487 mg + 0.05834 mg + 0.00483 mg4. 93.26 cm – 81.14 cm5. 5.236 cm – 3.14 cm6. 4.32 x 103 cm – 1.6 x 103 cm
Multiplying and Dividing
When you multiply or divide numbers, your answer must have the same number of significant figures as the measurement with the fewest number of significant figures.
Examples
1. 24 m x 3.26 m2. 120 m x 0.10 m3. 1.23 m x 2.0 m4. 53.0 m x 1.53 m5. 4.84 m/2.4 s6. 60.2 m/20.1 s7. 102.4 m/51.2 s8. 168 m/58 s
Percent Error
Percent error is used to calculate the accuracy of experimental data values and the accepted value.
Percent error is the ratio of an error to its accepted value and can be found using the following formula:
Organizing Data
Scientists accumulate vast amounts of data by observing events and making measurements.
Interpreting these data can be a difficult task if they are not organized.
Scientists can organize their data by using data tables and graphs.
These tools make it easier to spot patterns or trends in the data that can support or disprove a hypothesis
Data Tables
The simplest way to organize data is to present them in a table.
The table relates two variables—an independent variable and a
dependent variable.
x y
1 2
3 4
5 6
Line Graphs
Typical Line Graph A line graph is useful for showing changes that occur in
related variables. In a line graph, the independent
variable is generally plotted on the horizontal axis, or x-axis.
The dependent variable is plotted on the vertical axis, or
y-axis, of the graph. A direct proportion is a relationship in which the ratio of two variables is constant.
An inverse proportion, a relationship in which the
product of two variables is a constant.
Bar Graphs
A bar graph is often used to compare a set
of measurements, amounts, or changes.
The bar graph makes it easy to see how the
data for one thing compares with the data for another.
Typical Bar Graph
Circle Graphs
A circle graph is a divided circle that shows how a part or share of something
relates to the whole.
Communicating Data
A crucial part of any scientific investigation is reporting the results.
Scientists can communicate results by writing in scientific journals or speaking at conferences.
Scientists also exchange information through conversations, e-mails, and Web sites.
Young scientists often present their research at science fairs
Peer Review Different scientists may interpret the same data
differently. This important notion is the basis for peer review, a process in which scientists
examine other scientists' work. Peer review encourages comments, suggestions,
questions, and criticism from other scientists. Peer review can also help determine if data
were reported accurately and honestly.
Lab Equipment
Erlenmeyer Flask
Graduated Cylinder
Triple Beam Balance
Watch glass Beakers Volumetric Flask
Lab Equipment
Test Tubes Test Tube Rack
Test Tube Holder
CruciblesCrucible Tongs
Bunsen Burner