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Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced PDF Download

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes

(1) Isochoric process

V = constant  
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

dV = 0

 W = 0

dU = dqV
ΔU = qV  = nCVΔT

 ΔH = nCpΔT

Calculation of q, w, ∆H, ∆U for an IRREVERSIBLE ISOCHORIC process involving an ideal gas:

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
w= 0   

∵ dV = 0

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

(2) Isobaric process

W = - Pext (V2-V1)

Reversible & isobaric process

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

W = - P (V2-V1)
= - nR (T2-T1)
Irreversible & isobaric process
P1 = P2 = Pext
For reversible & irreversible isobaric or isochoric process, workdone is same.


(3) Isothermal process

(a) Reversible Expansion or compression

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

W = -P∫ dv
= -∫Pgas dV

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

In Expansion W = - ve
ΔE = 0

 q = -W

Calculation of q, w , ∆H, ∆U for a reversible isothermal process involving an ideal gas :
ΔU = q + w = 0 ⇒ -w

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced


(b) Single stage irreversible expansion

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

W = - Pext(V2 - V1)

|Wrev| > |Wirr| (in case of expansion)

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced


(c) Two Stage irreversible Expansion

Stage I. Pext  = 3 atm, Pi = 5 atm
Stage II. Pext  = 2 atm , Pf = 2 atm

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Work done in 2nd stage > Work done in Ist stage

(d)  n- stage expansion 

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced Compression - (One stage Compression ) 

| Wirr | = Pext DV
P1 = 1 atm , P2 = 5 atm , Pext = 5 atm

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced | Wirr | > | Wrev | For compression

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced 

Calculation of q, w, ∆H, ∆U for an Irreversible isothermal process involving an ideal gas:

For isothermal process involving

ΔH = ΔU = 0 ∵ ΔT = 0

Also,

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced 
For isobaric process

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

= -nR(T2 - T1) (∵ Pext = P)
= -nRΔT

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Example 1. 2 moles of an ideal gas initially present in a piston fitted cylinder at 300 K, and 10 atm are allowed to expand against 1 atm but the piston was stopped before it stablished the mechanical equilibrium. If temperature were maintained constant through out the change and system delivers 748.26 J of work, determine the final gas pressure and describe the process on PV diagram. 
Solution. 
Wirrv = - 748.26
Wirr = - Pext [1/P2- 1/P1]nRT
P2 = 4atm

Example 2. 1150 Kcal heat is released when following reaction is carried out at constant volume. 
C7H16(l) 11O2(g) → 7CO2(g) 8H2O(l) 
Find the heat change at constant pressure. 
The pressure of liquid is a linear function of volume (P = a + bV) and the internal energy of the liquid is U = 34 + 3PV find a, b, w, ΔE & ΔH for change in state from 100 Pa, 3m3 to 400 Pa, 6m3 

Solution. 100 = a + bV
⇒ 100 = a + 3b
Also, 400 = a + 6b
⇒ a = -200, b = 100
ΔU = 34 + 3(P2V2 - P1V1)
= 6300 J
ΔH = ΔU + P2V2 - P1V1
= 6300 + 2100 = 8400 J
P is a linear function
Pext = (400 + 100)/2 = 250
W = - Pext(dV)
= - 250(6 - 3) = - 750 J

Example 3. 4 moles of an ideal gas (Cv = 15 J) is subjected to the following process represented on P - T graph. From the given data find out whether the process is isochoric or not ? also calculate q, w, ΔU, ΔH,

 Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Solution. PV = nRT
4V = 4R × 400
V = 400 R ........(1)
3V = 4R × 300
⇒ V = 400 R ........(2)
i.e., V is constant
w = 0
ΔU = nCV  + ΔT ⇒ 4 ×15 ×100 = 6000 J
ΔH = nCP + ΔT ⇒ n (C+ R ) ΔT
⇒ 4 ×(15 8.3)×100
⇒ 9320 J

 q = ΔU = 6kj

Example 4. 2 mole of a gas at 1 bar and 300 K are compressed at constant temperature by use of a constant pressure of 5 bar. How much work is done on the gas ?  
Solution. 
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced = 19953.6 J

Example 5. 2 moles of an ideal diatomic gas (C = 5/2 R) at 300 K, 5 atm expanded irreversibly and adiabatically to a final pressure of 2 atm against a constant pressure of 1 atm. 
(1) Calculate final temperature q, w, ΔH & ΔU 
(2) Calculate corresponding values if the above process is carried out reversibly. 
Solution. 
w = C(T2 - T1

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Given T2 = 270K
Pext = 1,P2 = 2,P= 5
q = 0
w = ΔU = nCVΔT
= -1247.1 J
ΔH = nCPΔT
= 1745.94 J
If process is reversible Pvγ = Constant
P1- γTγ  = Constant

T = 231 K

Example 6. 10 gm of Helium at 127°C is expanded isothermally from 100 atm to 1 atm Calculate the work done when the expansion is carried out
(i) In single step
(ii) In three steps the intermediate pressure being 60 and 30 atm respectively and
(iii) Reversibly.

Solution. 
(i) Work done = V.ΔP
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
(ii) In three steps
VI = 83.14 × 10-5 m3
WI = (83.14 × 10-5) × (100 - 60) × 105
= 3325.6 Jules
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
WII = V. DP
WII = 138.56 × 10-5 (60 - 30) × 105
= 4156.99 ≈ 4157 J.
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
WIII = 277.13 × 10-5 (30 - 1) × 105
WIII = 8036.86 J.
W total  =  WI + WII + WIII 
= 3325.6 + 4156.909 + 8036.86 = 15519.45 J.
(iii) For reversible process
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Example 7. Calculate the amount of work done by 2 mole of an ideal gas at 298 K in reversible isothermal expansion from 10 litre to 20 litre.

Solution. Amount of work, done in reversible isothermal expansion,
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
Given, n = 2, R = 8.314 JK-1 mol-1, T = 298 K, V2 = 20 L and V1 = 10 L.
Substituting the values in above equation,
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
= -2.303 × 8.314 × 298 × 0.3010 = -3434.9 J
i.e., work is done by the system.

Example 8. 5 moles of an ideal gas expand isothermally and reversibly film a pressure of 10 atm to 2atm at 300K. What is the largest mass which can be lifted through a height of l metre in this expansion?

Solution. Work done by the system
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
Let M be the mas which can be lifted through a height of 1 m.

Work done in lifting the mass = Mgh = M × 9.8 × 11
So, M × 9.8 = 20.075 × 103 M
= 2048.469 kg

(4) Adiabatic Ideal Gas Expansion & Compression

dq = 0
dU = dW 

Δ U = W
 W = nCΔT = nCV T2 - T1)

For an ideal gas CP - CV = R

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Reversible Adiabatic Ideal Gas Expansion & Compression

nCVdT = - Pext dV
Pint = dP = Pext

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

⇒ T2(V2)γ - 1 = V1γ - 1T1

TVγ - 1 = Constant

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Calculation of q, w, ∆H, ∆U for reversible adiabatic process:Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

For an adiabatic process,

dq = 0 ⇒ dU = dw

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

for a reversible change

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
Now substituting V = nRT/P in equation

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

substituting T = PV/nR in eq...

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
⇒ Equation (i), (ii) and (iii) is valid only for reversible adiabatic process, for irreversible adiabatic process these equations are not applicable.

  • Expression for work:

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

  • Expression for ΔH and ΔU

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced


Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Irreversible Adiabtic Ideal Gas Expansion & Compression

dU = dW

⇒ nCV(T2 - T1) = - Pext dV

= - Pext [V2 - V1]

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Calculation of Q, W, ∆H, ∆U For Irreversible Adiabatic Process involving An Ideal Gas:

Operation wise adiabatic process and isothermal process are similar hence all the criteria that is used for judging an isothermal irreversible process are applicable to adiabatic process.

If large amount of dust particles are removed abruptly an irreversible adiabatic expansion take place.

In an irreversible adiabatic process, an ideal gas is subjected to compression or expansion in a thermally insulated vessel.

The heat absorbed in the process =0
⇒ dU = wirr ....(i)
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
If Pext, = P2 = Pfinal
Then

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
eq. (ii) or (iii) can be solved for T2
Expression for w

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Note: If two states A and B are connected by a reversible path then they can never be connected by an irreversible path.
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & AdvancedIf the two states are linked by an adiabatic reversible and irreversible path then wrev = ∆Urev
But as U is a state function
Therefore, ∆U irrev = ∆Urev
wirrev = wrev
as work is a path function.

If we assume that
wirrev = wrev

It implies that   which again is a contradiction as U is a state function.
∆U irrev ≠ ∆Urev
Two states A and B can never lie both on a reversible as well as irreversible adiabatic path.

There lies only one unique adiabatic path linkage between two states A and B.

Example 1. Two moles of an ideal monoatomic gas at NTP are compressed adiabatically and reversibly to occupy a volume of 4.48 dm3. Calculate the amount of work done, ∆U, final temperature and pressure of the gas. Cv for ideal gas 12.45J K -1 mol-1.
Solution. For an ideal gas,
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
Initial volume, V= 2 × 22.4 = 44.8 dm3 
Initial pressure, P1 = 1 atm
Initial temperature, T1 = 273 K
Final volume, V2 = 4.48 dm3
Let the final pressure be Pand temperature be T
Applying

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
or

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

or

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
P2 = (10)1.667(P1 = 1 given)
log P2 = 1.667 log 10= 1.667
P2 = antilog 1.667= 46.45 atm
Final temperature 

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
= 1268 K

Work done on the system = n.Cv.ΔT
= 2 × 12.45 × (1268 - 273)
= 2 × 12.45 × 995 = 24775.5 J
From the first law of thermodynamics,
ΔE = q + w = 0 + 24775.5 = 24775.5 J

Example 2. A certain volume of dry air at NTP is expanded reversibiy to four times its volume (a) isothermally (b) adiabatically. Calculate thefinal pressure and temperature in each case, assuming ideal behaviour.
(CP \ CV for air = 1.4)
Solution. 
Let V1 be the initial volume of dry air at NTP.
(a) Isothermal expansion: During isothermal expansion, the temperature remains the same throughout. Hence, final temperature will be 273 K.
Since P1V1 = P2V2
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
(b) Adiabatic expansion:
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Comparison of Reversible Isothermal And Reversible Adiabatic Ideal Gas Expansion 

Expansion

(i) If final volumes are same
Isothermal process.
P1v1 = Piso V
⇒  Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Adiabatic process.
Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

P1v1γ  = Padia V2γ 

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

⇒ Piso > Padia

(ii) If final pressures are same
Isothermal process.

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

P1V1 = P2 Viso 

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced .......(1)

P1V1γ  = P2Vγ adia

 Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

In ideal gas expansion,
| Wiso | > | Wadia |

Hence

⇒ Viso > Vadia

Compression 

(i) If final volumes are same

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

For isothermal process

P1V1 = PisoV2

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced ..........(1)

Adiabatic process.

P1V1γ  = PadiaV2γ 

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced ..........(2)

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Padia > Piso 

 

(ii) If final pressures are same

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

P1V1 = PViso ..........(1)

P1V1γ  = PVγ adia ..........(2)

 ⇒  Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced

⇒ Vadia > Viso

The document Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes | Chemistry for JEE Main & Advanced is a part of the JEE Course Chemistry for JEE Main & Advanced.
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FAQs on Enthalpy, Heat, Internal Energy & Work Done Calculations in Different Processes - Chemistry for JEE Main & Advanced

1. What is an adiabatic process in thermodynamics?
Ans. An adiabatic process is a thermodynamic process in which no heat is transferred to or from the system. This means that the change in internal energy of the system is equal to the work done on or by the system.
2. How is enthalpy related to heat in thermodynamics?
Ans. Enthalpy is a measure of the total heat content of a system at constant pressure. It is defined as the sum of the internal energy of the system and the product of pressure and volume. In a constant pressure process, the change in enthalpy is equal to the heat added to or removed from the system.
3. How can internal energy be calculated in an adiabatic ideal gas process?
Ans. In an adiabatic ideal gas process, the internal energy change can be calculated using the first law of thermodynamics, which states that the change in internal energy is equal to the work done on the system. This can be represented as ΔU = W.
4. What is the work done in an adiabatic compression process of an ideal gas?
Ans. In an adiabatic compression process of an ideal gas, the work done on the gas can be calculated using the formula W = -ΔU, where ΔU is the change in internal energy. Since no heat is transferred in an adiabatic process, the work done is equal to the decrease in internal energy.
5. How does the temperature change in an adiabatic expansion of an ideal gas?
Ans. In an adiabatic expansion of an ideal gas, the temperature decreases as the gas expands. This is because the gas is doing work on its surroundings, leading to a decrease in internal energy and temperature. The relationship between temperature and volume in an adiabatic process is given by the equation TV^(γ-1) = constant, where γ is the heat capacity ratio.
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