Lecture 1 - Heat PDF

Summary

This lecture provides an overview of temperature scales, including Celsius, Fahrenheit, and Kelvin. It explains how to convert between these scales and discusses the concepts of temperature change.

Full Transcript

Chapter 1: Heat

Chapter 1
Temperature & Heat

Temperature (T):
Temperature is a measure for the degree of hotness or coldness of the bodies.

Temperature scales
The temperature is measured in many scales, The most common types are:

1- Celsius scale (0C)

2- Fahrenheit scale (0F)

3- Kelvin scale (K)

Where:

- The freezing point of water is: 0 0C = 32 0F = 273.15 K

- The boiling point of water is: 100 0C = 212 0F = 373.15 K

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 Chapter 1: Heat

TC is a certain temperature in the Celsius scale while TF and TK are the
corresponding temperatures for TC in Fahrenheit and Kelvin scales.

To find the relation between these scales, one can use the following relation:

TC −0 F T −32
K T −273.15
⸫ = =
100−0 212−32 373.15−273.15

𝐓𝐂 𝐓𝐅 −𝟑𝟐 𝐓𝐊 −𝟐𝟕𝟑.𝟏𝟓
⸫
𝟏𝟎𝟎
= 𝟏𝟖𝟎
= 𝟏𝟎𝟎

- Relation between TC and TF:
T
C TF −32
⸪ 100 = 180

TF −32
⸫ TC = 100 x
180

𝟓
⸫ 𝐓𝐂 = (𝐓𝐅 − 𝟑𝟐)
𝟗

Or

𝟗
⸫ 𝐓𝐅 = ( 𝐓𝐂 ) + 𝟑𝟐
𝟓

For two different temperatures in Celsius scale TC1 and TC2 (as: TC2 > TC1) and their
corresponding temperatures in Fahrenheit scale TF1 and TF2 (as: TF2 > TF1)

5
TC1 = (T − 32)
9 F1
And

5
TC2 = (T − 32)
9 F2

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 Chapter 1: Heat

⸫ The change in temperatures in Celsius scale ΔTC, is:

ΔTC = TC2 – TC1
5
⸫ ΔTC = (TF2 − TF1 )
9

𝟓
⸫ 𝚫𝐓𝐂 = 𝚫𝐓𝐅
𝟗

Where, ΔTF = TF2 – TF1 ≡ corresponding change in temperature in Fahrenheit scale

- Relation between TC and TK:
T
C 𝐓𝐊 −𝟐𝟕𝟑.𝟏𝟓
⸪ 100 = 𝟏𝟎𝟎

⸫ 𝐓𝐂 = 𝐓𝐊 − 𝟐𝟕𝟑. 𝟏𝟓

Or

⸫ 𝐓𝐊 = 𝐓𝐂 + 𝟐𝟕𝟑. 𝟏𝟓

For two different temperatures in Celsius scale TC1 and TC2 (as: TC2 > TC1) and their
corresponding temperatures in Kelvin scale TK1 and TK2 (as: TK2 > TK1)

TC1 = TK1 − 273.15

And

TC2 = TK2 − 273.15

⸫ The change in temperature in Celsius scale ΔTC, is:

ΔTC = TC2 – TC1

⸫ ΔTC = TK2 − TK1

⸫ 𝚫𝐓𝐂 = 𝚫𝐓𝐊

Where, ΔTK = TK2 – TK1 ≡ corresponding change in temperature in Kelvin scale
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 Chapter 1: Heat

- Relation between TF and TK:

⸪ TK = TC + 273.15
and
5
⸪ TC = (TF − 32)
9

𝟓
⸫ 𝐓𝐊 = [ (𝐓𝐅 − 𝟑𝟐)] + 𝟐𝟕𝟑. 𝟏𝟓
𝟗

Or

𝟗
⸫ 𝐓𝐅 = [ (𝐓𝐊 − 𝟐𝟕𝟑. 𝟏𝟓)] + 𝟑𝟐
𝟓

For two different temperatures in Kelvin scale TK1 and TK2 (as: TK2 > TK1) and their
corresponding temperatures in Fahrenheit scale TF1 and TF2 (as: TF2 > TF1)
5
⸪ ΔTC = ΔTF
9

and

⸪ ΔTC = ΔTK

𝟓
⸫ 𝚫𝐓𝐊 = 𝚫𝐓𝐅
𝟗

Where,

ΔTK = TK2 – TK1 ≡ change in temperature in Kelvin scale

ΔTF = TF2 – TF1 ≡ corresponding change in temperature in Fahrenheit scale

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 Chapter 1: Heat

Example 1:
Convert the following temperatures from the Fahrenheit scale to the Celsius one:

a) 78 0F b) 300 0F

Solution

𝟓
⸪ 𝐓𝐂 = (𝐓𝐅 − 𝟑𝟐)
𝟗

a) TF = 78 0F ➔ TC = ??
5
⸫ TC = (78 − 32)
9

⸫ TC = 25.56 0C

b) TF = 300 0F ➔ TC = ??
5
⸫ TC = (300 − 32)
9

⸫ TC = 148.89 0C

Example 2:
Convert the following temperatures from the Celsius scale to the Kelvin one:

a) 20 0C b) -65 0C

Solution

⸫ 𝐓𝐊 = 𝐓𝐂 + 𝟐𝟕𝟑. 𝟏𝟓

a) TC = 20 0C ➔ TK = ??

⸫ TK = 20 + 273.15

⸫ TK = 293.15 K

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 Chapter 1: Heat

b) TC = -65 0C ➔ TK = ??

⸫ TK = −65 + 273.15

⸫ TK = 208.15 K

Example 3:
Convert the following temperatures from the Fahrenheit scale to the Kelvin one:

a) 82 0F b) 272 0F

Solution

𝟓
⸫ 𝐓𝐊 = [ (𝐓𝐅 − 𝟑𝟐)] + 𝟐𝟕𝟑. 𝟏𝟓
𝟗

a) TF = 82 0F ➔ TK = ??
5
⸫ TK = [ (82 − 32)] + 273.15
9

⸫ TK = 300.92 K

b) TF = 272 0F ➔ TK = ??
5
⸫ TK = [ (272 − 32)] + 273.15
9

⸫ TK = 406.48 K

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 Chapter 1: Heat

Example 4:
A block of material is heated from 30 0C to 90 0C. Calculate the change in the
temperature in:

a) Celsius scale b) Fahrenheit scale and c) Kelvin scale

Solution

TC1 = 30 0C, TC2 = 90 0C

a) ΔTC = ??

⸪ ΔTC = TC2 – TC1

⸫ ΔTC = (90 – 30) 0C

⸫ ΔTC = 60 0C

b) ΔTF = ??
𝟓
⸪ 𝚫𝐓𝐂 = 𝚫𝐓𝐅
𝟗

9
⸫ ΔTF = ΔTC
5

9
⸫ ΔTF = x 60 0F
5

⸫ ΔTF = 108 0F

c) ΔTK = ??

⸪ 𝚫𝐓𝐊 = 𝚫𝐓𝐂

⸫ ΔTK = 60 K

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 Chapter 1: Heat

Example 5:
At what temperature does Celsius and Fahrenheit scales coincide?

Solution

TC = TF = T = ??
𝟓
⸪ 𝐓𝐂 = (𝐓𝐅 − 𝟑𝟐)
𝟗

5
⸫T = (T − 32)
9

9
⸫ T = T − 32
5

9
⸫ T = T − 32
5

4
⸫ T = − 32
5

⸫ T = - 40 0

⸫ Celsius and Fahrenheit scales coincide at - 40 0

i.e., TC = - 40 0C in Celsius scale corresponds to TF = - 40 0F in Fahrenheit scale

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 Chapter 1: Heat

Heat energy (Q):
Heat is a form of energy which can be transferred from a hot substance to a colder
one.

Heat energy (Q) is measured in calorie (cal), Kilocalorie (Kcal) or Joule (J)

As: 1 cal = 4.18 J, 1 Kcal = 103 cal & 1 Kcal = 4180 J

Heating an object:

If we have a substance of mass m and initial
temperature Ti gains an amount of heat energy
Q, its temperature will be raised to a final
temperature TF. (i.e., TF > Ti)

⸫ ΔT = TF - Ti

Cooling an object:

If we have a substance of mass m and initial
temperature Ti loses an amount of heat energy
Q, its temperature will be lowered to a final
temperature TF. (i.e., TF < Ti)

⸫ ΔT = Ti – TF
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 Chapter 1: Heat

- The amount of heat Q gained (or lost) by the substance, without changing its state
(phase), is given as:

𝐐 = 𝐦 𝐒 𝚫𝐓

Where,

m = mass of the substance (g or Kg)

ΔT = The change in temperature (0C)
cal Kcal J
S = Specific heat of substance ( , and )
g.0 C Kg.0 C Kg.0 C

Note:

In the previous law, we will deal (in this course), with the Celius scale only.

Specific heat of substance (S):
𝐐
S=
𝐦 𝚫𝐓

It is defined as:

“The amount of heat gained (or lost) by the substance to change the temperature of
a unit mass (1 g or 1 Kg) by 10C”

- We must know that:

The specific heat of water (Sw); is
cal Kcal J
Sw = 1 =1 = 4180
g.0 C Kg.0 C Kg.0 C

Definition of calorie:
“It is the amount of heat gained (or lost) by 1 g of water to change its temperature
by 1 0C”

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 Chapter 1: Heat

VERY IMPORTANT NOTE:

We use the previous law [𝐐 = 𝐦 𝐒 𝚫𝐓], only if the substance maintains the same
phase (state).
Phase (or state) means: Solid, liquid or gas.

Example 6:
Calculate the amount of heat required to raise the temperature of 4 Kg of water from
20 0C to the boiling point.

(Given that: The specific heat of water is 4180 J/Kg.0C)

Solution

m = 4 Kg, Ti = 20 0C, TF = 100 0C, Sw = 4180 J/Kg.0C, Q = ??

⸪ 𝐐 = 𝐦 𝐒𝐖 𝚫𝐓

⸫ Q = m SW (TF − Ti )

⸫ Q = 4 x 4180 x (100 – 20) J

⸫ Q = 1.34 x 106 J

Example 7:
If 6.7 KJ of heat energy is supplied to 100 g of glass at initial temperature of 20 0C.
Find the final temperature.

(Given that: The specific heat of glass is 670 J/Kg.0C)

Solution

Q = 6.7 KJ ➔ Q = 6.7 x 103 J

m = 100 g ➔ m = 0.1 Kg

Ti = 20 0C

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 Chapter 1: Heat

Sglass = 670 J/Kg.0C

TF = ??

⸪ 𝐐 = 𝐦 𝐒𝐠𝐥𝐚𝐬𝐬 𝚫𝐓

⸫ 6.7 x 103 = 0.1 x 670 x ΔT

⸫ ΔT = 100 0C

⸪ ΔT = TF - Ti

⸫ 100 = TF – 20

⸫ TF = 120 0C

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