Chapter 1 Introduction to Physics PDF

Summary

This document introduces the fundamental concepts of physics, specifically focusing on the branch of mechanics and how to use units. It explains the importance of units in physics and provides examples of unit conversion and dimensional analysis.

Full Transcript

Chapter 1
Introduction to Physics

PH 133

“Nothing in life is to be feared, it is only to be
understood. Now is the time
to understand more, so that we may fear less.”

Maire Curie (1867 - 1934)
 Physics
From the Greek words physikos, "natural".

The study of the behavior of the universe:
– matter, energy, and time
– fundamental laws of nature

We will focus on the branch of physics called
Mechanics:
– the motion of objects and their response to forces.
 Math and Physics
In physics we attempt to describe the natural world through rules
and mathematics.
Math is the language of physics.

We perform experiments to compare mathematical calculations
to real life observations.

We use mathematical equations to simulate and predict real life
events.

Units are very important in physics!
We will primarily use the metric system.
How many countries do not use the metric system?

Three:
United States
Liberia
Myanmar
 Metric System
Developed in France in 1790’s; used by most of the world.
Based on set of common prefixes and powers of 10.
Base Units:
Length: meter (m); used like the foot.
Mass: gram (g); used like the ounce.
Time: second (s)

Attach a prefix to a base unit to change the size of the unit.
For example, if the base unit is a meter:
1 kilometer (km) = 1000 m
1 hectometer (hm) = 100 m
1 decameter (dam) = 10 m
1 meter = 10 decimeter (dm)
1 meter = 100 centimeter (cm)
1 meter = 1000 millimeter (mm)
Notice the abbreviations.
 Metric System
Based on a set of common prefixes and powers of 10.

Most common prefixes: kilo, hecto, deca, deci, centi, milli

kilo (k) Down  Multiply by 10 for each step
1000
(of base unit) hecto (h)
100
deca (da)
10
base (meter, liter, or gram)
1
deci (d)
0.1 = 1/10
centi (c)
0.01 = 1/100
Divide by 10 for each step  Up milli (m)
0.001 = 1/1000
 Metric Prefixes (full set)
Prefix Symbol Equivalent (compared to base unit)
yotta Y 1 Y = 1 000 000 000 000 000 000 000 000 (1024) base units
zetta Z 1 Z = 1 000 000 000 000 000 000 000 (1021) base units
exa E 1 E = 1 000 000 000 000 000 000 (1018) base units
Larger than base unit

peta P 1 P = 1 000 000 000 000 000 (1015) base units
tera T 1 T = 1 000 000 000 000 (1012) base units
giga G 1 G = 1 000 000 000 (109) base units
mega M 1 M = 1 000 000 (106) base units
kilo k 1 k = 1 000 (103) base units
hecto h 1 h = 100 (102) base units
deca da 1 da= 10 (101) base units For smaller units,
base 1 base = 1 (100) base units use these
equivalents:
deci d 1 d = 0.1 (10-1) base units 1 base = 10 d
centi c 1 c = 0.01 (10-2) base units 1 base = 100 c
Smaller than base unit

milli m 1 m = 0.001 (10-3) base units 1 base = 1000 m
micro µ 1 µ = 0.000 001 (10-6) base units 1 base = 10-6 µ
nano n 1 n = 0.000 000 001 (10-9) base units 1 base = 10-9 n
pico p 1 p = 0.000 000 000 001 (10-12) base units 1 base = 10-12 p
femto f 1 f = 0.000 000 000 000 001 (10-15) base units 1 base = 10-15 f
atto a 1 a = 0.000 000 000 000 000 001 (10-18) base units 1 base = 10-18 a
zepto z 1 z = 0.000 000 000 000 000 000 001 (10-21) base units 1 base = 10-21 z
*

yocto y 1 y = 0.000 000 000 000 000 000 000 001 (10-24) base units 1 base = 10-24 y
Once out the of most common prefix range, jump by 103.
Some common metric prefixes:

Name Abbreviation Amount of base units
Tera T 1012
Giga G 109
Mega M 106
Kilo k 103
Hecto h 102
Deca da 101
Deci d 10−1
Centi c 10−2
Milli m 10−3
Micro 𝜇𝜇 10−6
Nano n 10−9
Pico p 10−12
 Measurements and Unit Conversion
Every measurement consists of 2 parts: a number and a unit.
For example, 25 ft.
To convert units, use ‘unit fractions’.

A unit fraction has a value of 1.
Numerator and denominator contain different units,
but are equal.

Unit Conversion:
1. Write original quantity as a fraction.
2. Create a unit fraction using equivalent units.
12 in 1 ft
For example,12 in = 1 ft; unit fraction is or.
1 ft 12 in
Set up so that the unit not wanted cancels out.
3. Multiply the fractions: numerators across and denominators
across. Reduce numbers.
 Example
Convert 36 m to cm
36 m 100 cm
∗ = 3,600 cm
1 1m

Convert 1 yd2 to ft2
1 yd2 3 ft 3 ft
∗ ∗ = 9 ft 2
1 1 yd 1 yd

Convert 10.0 mph to m/s
10.0 mi 1 hr 1 min 1609 m
∗ ∗ ∗ = 4.47 m/s
hr 60 min 60 sec 1 mi
 Dimensional Analysis
The dimension is a type of quantity.
It is not tied to a specific unit.

Basic dimensions for our course:
Length [ L ]
Mass [ M ]
Time [ T ]
Any valid formula must be dimensionally consistent.
All terms in an equation must have the same dimension.
Remember can only add like terms.

The numbers in an equation do not affect the dimension and
can be ignored.
1
𝐴𝐴 = 𝑏𝑏𝑏 Area units [L2]. Both left and right sides are [L2]
2
Can also use units when checking dimensions.
For example, instead of [L] use m.
Example
Is this equation dimensionally correct?
V = lwh
Solution:
[L]3 = [L][L][L]
[L]3 =[L]3 OK!

What dimension must “t” be if x has the dimension of length
and v has the dimension of length/time?
x = xo + vavgt
Solution:
𝐿𝐿
𝐿𝐿 = 𝐿𝐿 + ⋅?
[𝑇𝑇]
t must have a dimension of time to cancel the [T] and have
all the terms as [L].
 Standard SI Units
SI: System International
Although there are many types of units for a given
“dimension”, there is a set of standard units used in this
class.
We will use the SI system of the metric system, established by
an international committee in 1960.
Dimension SI Standard Unit Abbreviation
Length [L] meter m
Mass [M] kilogram kg
Time [T] second s

Note: If a measurement is not in these units, may need to
convert before doing calculations.
SI standard units are not always the base units of the metric
system.
 quantity dimension SI units

area [ L ]2 m2

volume [ L ]3 m3

velocity [ L ] / [T] m/s

acceleration [ L ] / [ T ]2 m/s2

mass [M] kg
 Example
The smallest meaningful measure of length is called the
Planck length, and is defined in terms of three fundamental
constants in nature:
speed of light c = 3.00 × 108 m/s,
gravitational constant G = 6.67 × 10−11 m3/(kg ⋅ s2),
Planck's constant h = 6.63 × 10−34 kg ⋅ m2/s.
The Planck length ℓP is given by the following equation:
𝐺𝐺𝐺
ℓ𝑃𝑃 =
𝑐𝑐 3
Show that the dimensions of ℓP are length [L].

(The Planck length is the scale at which classical ideas
about gravity and space-time cease to be valid, and
quantum effects dominate.)
 Example Solution
Although the dimension is not tied to a specific unit, if the units
for each dimension match, you may use units to perform the
dimension check. (Often easier to write units.)
𝐺𝐺𝐺
ℓ𝑝𝑝 =
𝑐𝑐 3
1
2 1
2
𝑚𝑚3 𝑘𝑘𝑘𝑘𝑚𝑚 𝑚𝑚5 2 1
2
𝑠𝑠 𝑚𝑚5 𝑠𝑠 3 2
𝑘𝑘𝑘𝑘𝑠𝑠 𝑠𝑠 3
𝑚𝑚 =? =? =?
3
𝑚𝑚 3 𝑚𝑚 3 3
𝑠𝑠 𝑚𝑚
𝑠𝑠 𝑠𝑠
1
=? 𝑚𝑚2 2 = 𝑚𝑚
Okay!
 Order-of-Magnitude
An order-of-magnitude calculation is a estimate designed to be
accurate within a factor of about 10.
One purpose is to provide a quick idea of what should be expected
from a calculation.
The answer is reported as 10𝑥𝑥 , where 𝑥𝑥 is an integer. (10 to a power)

Example
Estimate how much water there is in a particular lake (in m3), which
is roughly circular, about 1 km across, and has an average depth of
about 10 m.

(For HW, may need to look up values for order-of-magnitude problems. This is
an estimate so do not need exact values.)
 Example solution
Solution:
 Accuracy and Precision
Careful measurements are very important in experiments so
that the error is minimized and results are reproducible.

Accuracy: How close a measured value is to the true value.
Poor accuracy involves errors that can often be corrected,
such as reading the instrument incorrectly.

Precision: How exact a measured value is based on the
measuring device.
Limited by smallest division of the measuring device.
To measure precision
read to smallest division,
and estimate one additional decimal place.
For lab, all measurements must have the correct precision.
 Precision
To measure precision, read to smallest division and
estimate one additional decimal place.

Smallest measure = 1 mm.
One additional decimal place = 0.1 mm
Ruler: Precision is 0.1 mm = 0.01 cm = 0.0001 m

Smallest measure = 0.1 g.
One additional decimal place = 0.01 g
Triple beam balance: Precision is 0.01 g = 1 cg = 0.00001 kg
 Significant Digits
Precision indicates the number of significant digits.
These are the number of reliably known digits.
Significant Digits are:
Non-zero digits 12.5
Trailing zeros in the decimal portion 12.50
Zeros between non-zero digits 120.5
Non-significant Digits:
Zeros in front of non-zero digits 0.00125
Zeros behind non-zero digits to the left of the decimal point 12500
If want to show all digits of 12,500 are significant, use scientific notation: 1.2500 x 104.
Operations with Significant Digits
Addition/subtraction: Round answer to the least number of decimal
places found in the original numbers.
Multiplication/division: Round answer to the least number of
significant figures found in the original numbers.
When have multiple types of operations, keep all digits and round
to the least number of significant digits in the original numbers
at the end.
 Examples:
(Follow standard rules for rounding, as needed.)

1. How many significant figures are in the number 10001?
2. How many significant figures are in the number 0.01500?
3. How many significant figures are in the number 100?
4. How many significant figures are in the number 1.00 x 102?
5. What is the difference between 103.5 and 102.24?
6. What is the product of 12.56 and 2.12?

Answers
5
4
1
3
103.5-102.24=1.26. Round to 1.3
12.56x2.12=26.6272. Round to 26.6