Lecture 1.2 - Measurements.pptx

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SciET 141
CHEMISTRY

Ms. Maria Fatima D. De Torres, LPT, MAEd

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1
MEASUREMENT
S
SI UNITS
BASIC TYPES OF QUANTITY
SIGNIFICANT FIGURES

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 Measurement
Observations in science can either be qualitative or
quantitative.

Qualitative observation does not involve a number.

A quantitative observation is called a measurement,
which always has two parts: a number and a scale (called
a unit). Both parts must be present for the measurement
to be meaningful.
6 kilograms unit

number

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 Measurement
Scientists recognized long ago that standard systems
of units had to be adopted if measurements were to be
useful.
The two major systems are the English system used in
the United States and the metric system used by most of
the rest of the industrialized world.
In 1960, an international agreement set up a system of
units called the International System (le Systeme
International in French), or the SI system. This system is
based on the metric system and units derived from the
metric system.

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 Measurement
Physical Quantity Name of Unit Abbreviation
Mass kilogram kg
Length meter m
Time second s
Temperature kelvin K
Electric current ampere A
Amount of substance Mole mol
Luminous intensity candela cd

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 Measurement
To express small or large measured quantities in
terms of a few simple digits, prefixes are used with
these base units and other derived units. These prefixes
multiply the unit by various powers of 10.

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 Basic Types of Quantity
Fundamental Quantities
It is referred to as the basic quantities. Quantities
which are measured by the direct method. The units
assigned to the fundamental quantities are called
fundamental units.
The fundamental units meter, kilogram and second
(MKS) are the standard units for length, mass, and time,
respectively. However, for smaller quantities, centimeter,
gram, and second (CGS) are used as fundamental units.

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 Basic Types of Quantity
Derived Quantities
Quantities that emanate or a result of the
combination of fundamental quantities after a set of
operations.
Area, volume, and density are some examples of
derived quantities.
Area square meter m2
Volume cubic meter m3
Density kilogram per cubic meter kg/m3

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 Basic Types of Quantity

One physical quantity that is very important in
chemistry is volume, which is not a fundamental SI unit
but is derived from length.
The most common conversion factors for volume is
shown below:
1 L = 1 (dm)3 = (10 cm)3 = 1000 cm3
1cm3 = 1 mL
1L = 1000 cm3 = 1000 mL

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 Significant Figures
It is very important to realize that a measurement
always has some degree of uncertainty. The uncertainty
of a measurement depends on the precision of the
measuring device. Consider the measurement of the
volume of a liquid using a burette.

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 Significant Figures
The first three numbers (20.1) remain the
same regardless of who makes the
measurement; these are called certain digits.
The digit to the right of the 1 must be
estimated and therefore varies; it is called an
uncertain digit.
We customarily report a measurement by
recording all digits that are known with certainty
plus the first uncertain digit. These numbers are
called the significant figures of a
measurement.
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 Significant Figures
Rules for counting Significant Figures
1. Non-zero Integers
These always count as significant figures. The
number 1458 has four (4) non-zero digits, all of which
count as significant figures.
2. Zeros
a. Leading zeros are zeros that precede all the non-zero
digits. These do not count as significant figures. The
number 0.0025, the three zeros simply indicate the
position of the decimal point. This number has only
two (2) significant figures.

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 Significant Figures
Rules for counting Significant Figures
b. Captive zeros are zeros between non-zero digits.
These always count as significant figures. The
number 1.008 has four (4) significant figures.
c. Trailing zeros are zeros at the right end of the
number. They are significant only if the number
contains a decimal point. The number 100 has only
one significant figure, whereas the number 1.00 x
10^2 has three (3) significant figures. The number one
hundred written as 100. also has three (3) significant
figures.

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 Significant Figures
Rules for counting Significant Figures
3. Exact Numbers
These involve numbers that were not obtained using
measuring devices but were determined by counting: 10
experiments, 3 apples, 8 molecules. They can be
assumed to have an infinite number of significant figures.
Other examples of exact numbers are the 2 in 2πr
(the circumference of a circle) and the 4 and the 3 in
4/3πr3 (the volume of a sphere).
Exact numbers also can arise from definitions such as
1 inch is defined as exactly 2.54 centimeters.

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 Significant Figures
Exponential Notation
The number 1.00 x 10^2 is written in exponential notation
or scientific notation.
This type of notation has at least two advantages:
a. the number of significant figures can be easily indicated
b. fewer zeros are needed to write a very large or very small
number.
For example, 0.000060 is much more conveniently
represented as 6.0 x 10-5. (The number has two significant
figures.) It is often necessary to set the decimal point using
the power-of-10 notation to avoid introducing the appearance
of unwanted significant figures.
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 Significant Figures
Scientific Notation

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 Significant Figures
Scientific Notation
For 2300000, to change it into scientific notation:

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 Significant Figures
Scientific Notation
The speed of light is 300,000 km/s. We can write this
number as 3.0 X 105km/s.
The mass of a carbon atom is
0.000000000000000000000002 grams. We can write this as
2.0 X 10-23 grams.
The number of hydrogen atoms in 1 gram of hydrogen is
623,000,000,000,000,000,000,000. We can write this as 6.23
X 1023.
You can see why we write in scientific notation.

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 Significant Figures
Rules for Significant Figures in Mathematical Operations
a. For multiplication or division, the number of significant
figures in the result is the same as the number in the
least precise measurement used in the calculation. For
example, consider the calculation:
4.56 x 1.4 = 6.38

Final answer = 6.4
The product should have only two significant figures,
since 1.4 has only two significant figures.
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 Significant Figures
Rules for Significant Figures in Mathematical Operations
b. For addition and subtraction, the result has the same
number of decimal places as the least precise
measurement used in the calculation. For example,
consider the sum:
22.13
17.0
+ 2.024
Final answer is 41.2 since 17.0
41.154
has only one decimal place.

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 Precision and Accuracy
Two terms often used to describe the
reliability of measurements are
precision and accuracy.
Accuracy refers to the agreement of
a particular value with the true value.
Precision refers to the degree of
agreement among several
measurements of the same quantity.
Precision reflects the reproducibility of a
given type of measurement.

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 Precision and Accuracy

Two different types of errors are
illustrated in Figure.
large random error
A random error (also called an (poor technique)
indeterminate error) means that a
measurement has an equal probability
of being high or low. This type of error
occurs in estimating the value of the last
digit of a measurement.

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 Precision and Accuracy
The second type of error is called
small random
systematic error (or determinate error). errors but large
This type of error occurs in the same systematic error
direction each time; it is either always
high or always low.

small random
errors but no
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systematic error
 Dimensional Analysis

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 Dimensional Analysis
Some equivalents in the English and metric
system are given as follow:
Volume Length Mass
SI Unit: cubic meter SI Unit: meter (m) SI Unit: kilogram (kg)
(m3)
10-3 m3 1m 1.0936yards 1 pound 453.59 grams
1L 1 dm3 (lb) 0.45359 kg
1.0567 quarts 1 cm 0.39370 inch 16 ounces

4 quarts 1 inch 2.54
1 gallon 8 pints centimeters 1000 grams
3.7854 Liters 1 kg 2.2046 lbs
1 km 0.62137 miles

1 quart 32 fluid ounces 1 mile 5280 feet 1 ton 2000 lbs
0.94633 Liter 1.6093 km 907.185 kg
1 10-10 m 1 Metric 1000 kg
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m
 Temperature

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 Dimensional Analysis

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 Dimensional Analysis
Example 2: A student has entered a 10.0 km
run. How long is the run in miles?
kilomet
meter yards miles
er

Solution: Equivalence statements:
1km=1000m
1m=1.094yd
1760yd=1mi

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 Dimensional Analysis
1km=1000m
1m=1.094yd
1760yd=1mi

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 Dimensional Analysis

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 Dimensional Analysis

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 Sample Problem

A sample oil has a density of
1.08 g/mL. What is the mass of
4.00 barrels of oil in kilograms if
a barrel of oil is 45 gallons? You
are given that one gallon is
3.8754 L.
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