today is friday (!), february 6 th, 2014 pre-class: get your calculators and get ready. something...
TRANSCRIPT
Today is Friday (!),February 6th, 2014
Pre-Class:Get your calculators and get ready.
Something else to do:What would it mean if I told you that when it comes to basketball, I’m not
very accurate but I am very precise?
Last thing:Today (or maybe tomorrow) I will teach you how 5 x 5 = 30.
SIDE NOTE: Turn in your Separation of a Mixture Labs.
Stuff You Need:Calculator
Paper Towel
In This Lesson:Measurement and Significant
Figures(Lesson 3 of 6)
Today’s Agenda
• Measurement• Significant Figures
• Where is this in my book?– P. 63 and going for quite a few pages…
By the end of this lesson…
• You should be able to differentiate between accuracy and precision.
• You should be able to determine which digits of a number are significant.
Measurement
• Yes, in the world of chemistry, even a term such a measurement has a distinct definition.– A measurement is a quantitative observation that
consists of two parts:• Number• Scale (unit)
– If you leave out either one, I must deduct points.• For example:– 21 grams– 6.63 x 10-34 Joule seconds
Uncertainty
• As it turns out, not every measurement is perfectly accurate.
• In any measurement there’s a degree of uncertainty.
• For example, how many mL do you see here?– 53 mL sounds good, but you
can estimate one more digit. 52. 9 mL?
• (In this class, you should estimate that extra digit)
http://www.jce.divched.org/JCESoft/Programs/CPL/Sample/modules/gradcyl/pic/00322409.jpg
Accuracy versus Precision
• In addition to uncertainty, measurements also can be judged according to their accuracy or their precision.– What’s the difference?
• Accuracy is how close a measurement comes to reality.
• Precision is how “repeatable” a measurement is or the number of decimal places an instrument measures.– “60% of the time, it works every time.”
Accuracy versus Precision
http://antoine.frostburg.edu/chem/senese/101/measurement/slides/img017.GIF
High Accuracy,High Precision
Low Accuracy,High Precision
High Accuracy, Low Precision
Low Accuracy, Low Precision
2.
3.1.
4.
Accuracy and Precision• Suppose you have an electronic
balance that provides measurements to two decimal places.– It’s certain to two. Other digits are
uncertain.• If the balance always gives you the
same mass for the same object, it’s precise.
• If it gives you the right mass, it’s accurate.– Are there ways in which it could be
accurate but not precise?– How about precise but not accurate?
http://hxdzjs.net/uploadfile/20100601/20100601134741293.jpg
Pre-Class Part Deux
• Facebook was recently found to have 845 million users1.– Is it exactly 845,000,000?– Could it possibly be 845,000,001?
• If you needed to calculate the circumference of a circle but you only knew the diameter was 8, what would you do?– Most of us would multiply by pi (π).– How much is pi, again?
1USA Today, Facebook IPO, 2/2/2012
Significant Figures• Scientists need to be clear with one another about
how many digits to which they are rounding.– In other words, they need to be clear about the level of
uncertainty they’re willing to accept.– One scientist may say pi is 3.141, another may say
3.141592654.
• To determine how many digits your answer should be, we use significant figures.
• Significant figures are the “digits that count” – overall, they’re used as a special form of rounding.– Also known as Significant Digits, or Sig Figs, or Sig Digs
4 Rules for Counting Sig Figs
1. If the number contains a decimal point, count from right to left until only zeros or no digits remain.
Examples: 20.05 grams 4 sig figs
7.2000 meters 5 sig figs
0.0017 grams 2 sig figs
4 Rules for Counting Sig Figs
2. If the number does not contain a decimal point, count from left to right until only zeros or no digits remain.
Examples: 255 meters 3 sig figs
1,000 kilograms 1 sig fig
Quick Interlude: Oceanic Sig Figs• Here’s a way to remember Rules 1 and 2, although it
doesn’t work in Hawaii:• If there is a decimal point present, count in the
direction of the Pacific (to the left).• If the decimal point is absent, count in the direction
of the Atlantic.
4 Rules for Counting Sig Figs
3. For numbers in scientific notation (M x 10n), count only the sig figs in the M number – use rules 1 and 2 normally.
Examples: 1.43 x 10-16 cm 3 sig figs
2 x 105 g 1 sig fig
4 Rules for Counting Sig Figs
4. Exact numbers have an infinite number of significant figures.
Rare in this class (usually for unit conversions).
1 inch = 2.54 cm exactly
1 dozen = 12 exactly
How many significant figures in each of the following?
1.0070 m = 5 sig figs
17.10 kg = 4 sig figs
100,890 L = 5 sig figs
3.29 x 103 s = 3 sig figs
0.0054 cm = 2 sig figs
3,200,000 = 2 sig figs
Counting Sig Figs
Now for some practice…
• Significant Figures in Measurements and Calculations– Part I – choose 15.
• Difficult and/or Scientific Notation:– 13, 14, 18-20
• The competition will be afterward!
Now for a break…
• Let’s take a look at some pretty interesting uses of measurements (particularly in terms of accuracy).– Parallel Parking video.
Rules for Significant Figures in Mathematical Operations
• Addition and Subtraction:• The number of digits after the decimal point in the
result equals the number of digits after the decimal point in the least precise measurement. • Round the “end” normally.
6.8 + 11.934 =6.8 + 11.934 = 18.734 18.7
3.24 m + 7.0 m
Calculation Calculator says: Answer
10.24 m 10.2 m
100.0 g - 23.73 g 76.27 g 76.3 g
0.02 cm + 2.371 cm 2.391 cm 2.39 cm
713.1 L - 3.872 L 709.228 L 709.2 L
1818.2 lb + 3.37 lb 1821.57 lb 1821.6 lb
2.030 mL - 1.870 mL 0.16 mL 0.160 mL
Adding and Subtracting
Now for some practice…
• Significant Figures in Measurements and Calculations– Part II – choose 5.– Part III – choose 3.
• Difficult and/or Scientific Notation:– 28, 30
• The competition will be afterward!
Rules for Significant Figures in Mathematical Operations
• Multiplication and Division:• The number of significant figures in the result equals
the number of significant figures in the least precise measurement used in the calculation.• Round the “end” normally.
6.38 x 2.0 =6.38 x 2.0 = 12.76 13 (2
sig figs)
3.24 m x 7.0 m
Calculation Calculator says: Answer
22.68 m2 23 m2
100.0 g ÷ 23.7 cm3 4.219409283 g/cm3 4.22 g/cm3
0.02 cm x 2.371 cm 0.04742 cm2 0.05 cm2
710 m ÷ 3.0 s 236.6666667 m/s 240 m/s
1818.2 lb x 3.23 ft 5872.786 lb·ft 5870 lb·ft
1.030 g x 2.87 mL 2.9561 g·mL 2.96 g·mL
Multiplying and Dividing
Now for some practice…
• Significant Figures in Measurements and Calculations– Part IV – choose 5.– Part V – choose 3.
• Difficult and/or Scientific Notation (you must try one of these):– 45, 46, 48, 50, 51, 55
• The competition will be afterward!
Closure
• So, using sig fig rules, solve this problem:• 5 x 5 = ?• 5 x 5 = 30
• Now solve this one:• 5.0 x 5.0 = ?• 5.0 x 5.0 = 25.0
Closure Part Deux
• Try this one:• 15 g x 4.0 g = ?• 15 g x 4.0 g = 60 g…but it needs to be 2 sig figs!• 15 g x 4.0 g = 60.0 g…is 3 sig figs!
• Write this down: When in doubt, make it scientific notation (we’ll do this later).
• 6.0 x 101 g
More sig fig practice:
Do this:http://www.sciencegeek.net/Chemistry/taters/Unit0Sigfigs.htm
Then try 10:http://science.widener.edu/svb/tutorial/sigfigures.html