The metric system is based on a base unit that …...•Metric system is based on powers of 10 •For conversions within the metric system, each “step” is 1 decimal place to the

The metric system is based on a base unit

that corresponds to a certain kind of

measurement Length = meter

Volume = liter

Weight (Mass) = gram

Prefixes plus base units make up the metric

system

• Example:

Centi + meter = Centimeter

Kilo + liter = Kiloliter

The three prefixes that we will use the most are:

• Kilo= 1000

• centi = 1/100 (one hundredth)

• milli= 1/1000 (one thousandth)

How do you remember all of them?

Kilo

(1000)

Hecto

(100)

Deca

(10)

Base Units

meter

gram

liter

deci

(1/10)

centi

(1/100)

milli

(1/1000)

Kissing Hairy Dark space dogs causes mono

So if you needed to measure length you would

choose meter as your base unit

• Length of a tree branch = 1.5 meters

• Length of a room = 5 meters

But what if you need to measure a longer distance, like from your house to school?

• Let’s say you live approx. 10 miles from school

10 miles = 16093 meters

• 16093 is a big number, but what if you could add a prefix onto the base unit to make it easier to manage:

16093 meters = 16.093 kilometers (or 16.1 if rounded to 1 decimal place)

What metric unit would you use to measure the

length of the room?

What metric unit would you use to measure the

distance between the mall and school?

What metric unit would you use to measure your

weight?

What metric unit would you use to measure the

amount of liquid in a soda bottle?

What unit would you use to measure the amount of

liquid in an eye dropper?

These prefixes are based on powers of 10. What does this mean?

• From each prefix every “step” is either: 10 times larger

or

10 times smaller

• For example Centimeters are 10 times larger than millimeters

1 centimeter = 10 millimeters

Kilo

(1000)

Hecto

(100)

Deca

(10)

Base Units

meter

gram

liter

deci

(1/10)

centi

(1/100)

milli

(1/1000)

• Centimeters are 10 times

larger than millimeters so it

takes more millimeters for

the same length

1 centimeter = 10 millimeters(Example not to scale)

1 mm 1 mm 1 mm 1 mm 1 mm 1 mm 1 mm 1 mm 1 mm 1 mm

1 cm

40

41

41

40

For each “step” to right,

you are multiplying by 10

For example, let’s go from a base unit to centi-

1 liter = 10 deciliters = 100 centiliters

2 grams = 20 decigrams = 200 centigrams

( 1 x 10 = 10) = (10 x 10 = 100)

(2 x 10 = 20) = (20 x 10 = 200)

Kilo

(1000)

Hecto

(100)

Deca

(10)

Base Units

meter

gram

liter

deci

(1/10)

centi

(1/100)

milli

(1/1000)

Kilo

(1000)

Hecto

(100)

Deca

(10)

Base Units

meter

gram

liter

deci

(1/10)

centi

(1/100)

milli

(1/1000)

An easy way to move within the metric system is by moving the decimal point one place for each “step” desired

Example: change meters to centimeters

1 meter = 10 decimeters = 100 centimeters

Kilo

(1000)

Hecto

(100)

Deca

(10)

Base Units

meter

gram

liter

deci

(1/10)

centi

(1/100)

milli

(1/1000)

Now let’s try our previous example from meters

to kilometers:

16093 meters = 1609.3 decameters = 160.93

hectometers = 16.093 kilometers

So for every “step” from the base unit to kilo, we

moved the decimal 1 place to the left

(the same direction as in the diagram below)

Kilo

(1000)

Hecto

(100)

Deca

(10)

Base Units

meter

gram

liter

deci

(1/10)

centi

(1/100)

milli

(1/1000)

If you move to the left in the diagram,

move the decimal to the left

If you move to the right in the diagram,

move the decimal to the right

Kilo

(1000)

Hecto

(100)

Deca

(10)

Base Units

meter

gram

liter

deci

(1/10)

centi

(1/100)

milli

(1/1000)

Now let’s start from centimeters and convert to

kilometers

400000 centimeters = ? kilometers

Kilo

(1000)

Hecto

(100)

Deca

(10)

Base Units

meter

gram

liter

deci

(1/10)

centi

(1/100)

milli

(1/1000)

Kilo

(1000)

Hecto

(100)

Deca

(10)

Base Units

meter

gram

liter

deci

(1/10)

centi

(1/100)

milli

(1/1000)

Now let’s start from meters and convert to centimeters

5 meters = ? centimeters

Now let’s start from kilometers and convert to meters

0.3 kilometers = ? meters

Kilo

(1000)

Hecto

(100)

Deca

(10)

Base Units

meter

gram

liter

deci

(1/10)

centi

(1/100)

milli

(1/1000)

Summary

• Base units in the metric system are meter, liter, gram

• Metric system is based on powers of 10

• For conversions within the metric system, each “step”

is 1 decimal place to the right or left

• Using the diagram below, converting to the right,

moves the decimal to the right and vice versa

Accuracy: measurements are close to true (“correct”) value

Precision: measurements are consistent/ reproducible;

measurements are close to each other.

Accuracy vs. Precision

Significant Figures

What are they?• A way to indicate the accuracy of a

measurement or calculations involving

measurements.

• Significant figures in a measurement

include all the digits known with certainty

plus one final digit, which is estimated.

554321 54321

Significant Figures

5

54321

54321

Rules for Significant Figures

• 2.35 g has three sig figs

• 2251 g has two sig figsNon-Zero Rule: All digits 1 – 9 are always

significant.

• 205 m has three sig figs

• 80.04 m has four sig figs

Righty-Righty Rule: Zeros at the end of a number and to the right of a decimal point

ARE significant.

• 2.30 mL has three sig figs

• 20.0 mL has three sig figsStraddle Rule: Zeros appearing between

significant digits ARE significant.

• 0.095 897 m has five sig figs

• 0.000 09 L has one sig fig

Beginning Zeros Rule: Zeros appearing to the left of ALL non-zero digits are NOT

significant.

• 3500 kg has two sig figs

• 10,000 m has one sig fig

Ending Zeros rule: Zeros at the end of a number, but to the left of the decimal

place are NOT significant.

• 3500 g has two sig figs

• 3500. g has four sig figs

Decimal Point Rule: A decimal point may be used to indicate the significance of

zeros to the left of it.

Zeros between

Non-zeros ARE

significant

All figures are

significant

(4 sig figs)

Zero to the

right of the

decimal ARE

significant

All figures are

Significant

(5 sig figs)

Significant Figures Examples

No decimal

point

Zeros are not

significant!

2 sig

figs

Decimal

Point

All digits including

zeros to the left of

The decimal are

significant.

6 sig figs

Significant Figures Examples

Zeros to the right of the decimal

with no non-zero values before the

decimal are not significant

3 sig figs

Zeros to the right of the decimal

And to the right of non zero values

Are significant

5 sig figs

Significant Figures Examples

How many significant figures are in

each of the following measurements?

1. 28.6 g

2. 3440. cm

3. 910 m

4. 0.046 04 L

5. 0.006 700 0 kg

6. 804.05 g

7. 0.014 403 0 km

8. 1002 m

9. 400 mL

10. 30,000. cm

11. 0.000 625 000 kg

• Three

• Four

• Two

• Four

• Five

• Five

• Six

• Four

• One

• Five

• Six

When adding or subtracting decimals, the

answer must have the same number of digits

to the right of the decimal point as there are

in the measurement having the fewest digits

to the right of the decimal point.

25.1 g + 2.03 g = 27.13 g

= 27.1 g

Significant Figures

Rules for Addition & Subtraction

Significant Figures

Rules for Addition & Subtraction

The sum of an

unknown number

and a 6 is not valid.

The same is true

For the 2

The numbers in

these positions are

not zeros, they are

unknown

The answer is rounded to the

position of least significance

For multiplication and division, the answer

can have no more significant figures than

are in the measurement with the fewest

number of significant figures.

Significant Figures

Rules for Multiplication & Division

1. What is the sum of 2.099 g and 0.05681 g?

2.156 g

2. Calculate the quantity 87.3 cm – 1.655 cm.

85.6 cm

3. What is the density of a substance with a

mass of 1.425 g and a volume of 2.1 mL?

0.68 g/mL

4. Calculate the area of a crystal surface that

measures 1.34 mm by 0.7488 mm.

1.00 mm2

5. 1.35 m x 2.467 m = __________

3.33 m2

6. 1,035 m2 42 m = __________

25 m

7. 12.01 mL + 35.2 mL + 6 mL = __________

53 mL

8. 55.46 g – 28.9 g = __________

26.6 g

9. 0.021 cm x 3.2 cm x 100.1 cm = __________

3.7 cm3

10. 0.15 cm + 1.15 cm + 2.051 cm = __________

3.35 cm

11. 150 L3 4 L = __________

40 L2

12. 505 kg – 450.25 kg = __________

55 kg

13. 1.252 cm x 0.115 cm x 0.012 cm = __________

0.0017 cm3

14. 4.6 m – 2.15 m + .08 m = __________

2.5 m

Significant Figures

& Exact Numbers

Exact equivalences have an unlimited

number of significant figures.

There are exactly 3 feet in exactly 1 yard.

Therefore the “3” can be 3 or 3.0 or 3.00 or 3.000 etc.

and the “1” can be 1 or 1.0 or 1.00 or 1.000 etc. !

The same is

true for:

Scientific notation is a way of expressing really big numbers or really small numbers.

For very large and very small numbers, scientific notation is more concise.

Every number written in scientific notation has two basic parts.

• The first part is always a decimal number between 1.00 and 9.99…

• The second part is 10 times some exponent

N x 10x

Place the decimal point so that there is one non-zero digit to the left of the decimal point.

Count the number of decimal places the decimal point has “moved” from the original number. This will be the exponent on the 10.

If the original number was less than 1, then the exponent is negative. If the original number was greater than 1, then the exponent is positive.

Example:

• Given: 289,800,000

• Start with: 2.898

• Decimal needs to move 8 places to the right

• Answer: 2.898 x 108

Simply move the decimal point to the right for positive exponent 10.

Move the decimal point to the left for negative exponent 10. (Use zeros to fill in places.)

Example:

Given: 5.093 x 106

Move: 6 places to the right (positive)

Answer: 5,093,000

The exponent on the 10 tells you which

direction to move the decimal and how

many times it should be moved.

• POSITIVE EXPONENT means move RIGHT

• NEGATIVE EXPONENT means move LEFT

A standard notation number LOWER

than 1 means NEGATIVE exponent

A standard notation number GREATER

than 1 means POSITIVE exponent