Isochoric, Isobaric, Reversible and Irreversible Process

If a substance undergoes a process in which the volume remains constant, the process is called isochoric process. This note provides an information on isochoric, isobaric, reversible and irreversible process.

Summary

If a substance undergoes a process in which the volume remains constant, the process is called isochoric process. This note provides an information on isochoric, isobaric, reversible and irreversible process.

Things to Remember

If a substance undergoes a process in which the volume remains constant, the process is called isochoric process.

If the working substance is taken in an expanding chamber in which the pressure is kept constant, the process is called isobaric process.

A reversible process is one which can be retraced in the reverse order, so that it passes exactly through the same state as in the direct process.

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Subjective Questions

Q1:

What do you mean by ultrasonography imaging system?


Type: Short Difficulty: Easy

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Answer: <p>Ultrasonography imaging system is the system of imaging which uses the high frequency sound waves for visualizing the deep structures of the body as well as the body within the body i.e foetus. This system is used to examine the internal organs and soft tissues of our body such as heart and blood vessels, liver, gallbladder, spleen, pancreas, kidneys, uterus, ovaries, eyes, testicles etc. This system is painless as it is noninvasive.</p>

Q2:

Describe the principle of generation of ultrasound waves.


Type: Short Difficulty: Easy

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Answer: <p>Ultrasound waves are the high frequency sound waves which is used for the ultrasonography. One of the important component of ultrasonography system is transducer. There are piezo-electric crystals on the surface of the transducer. The transducer converts the electrical energy into the sound waves and again those sound waves back to electrical energy. When AC supply is supplied to the transducer, the mechanical distortion is produced in the crystals. This generates the vibration in the crystals and thus sound waves are generated. This process can be shown as follows:</p> <figure class="" style="width: 550px;"><img src="/uploads/ultr3.jpg" alt="Fig: Generation of US waves" width="550" height="256"><figcaption>Fig: Generation of US waves</figcaption></figure>

Q3:

Explain the components of basic pulse echo apparatus.


Type: Short Difficulty: Easy

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Answer: <p>The basic pulse echo apparatus consists of the following components as shown below:</p> <figure class="" style="width: 500px;"><img src="/uploads/ep1.png" alt="Fig: Components of Basic Pulse Echo Apparatus" width="500" height="270"><figcaption>Fig: Components of Basic Pulse Echo Apparatus</figcaption></figure><p></p> <ol><li>Transducer: Imaging system utilizes the pulsed ultrasound. The transducer generates a train of pulses of short duration at specific frequency determined by the pulse repetition frequency generator. These are converted into corresponding pulse of the ultrasonic waves by the piezo-electric crystal acting as a transmitting transducer.</li> <li>PRF generator: A single astable multivibrator is used to generate a train of pulses with required frequency and then use them to trigger monostable multivibrator which produces pulses of required width with the short pulse duration.</li> <li>Transmitter: It is driven by a pulse from PRF generator and is made to trigger an SCR circuit, which discharges a capacitor through the piezo-electric crystal.</li> <li>Swept Gain Control: The changes in tissue properties can shift the echo amplitudes to vary over a wide range. The gain is varied with distance and slope.</li> <li>Detector: This is of the capacitor type with an inductive filter to have additional filtering of the carrier frequency.</li> <li>Video amplifier: The signal requires amplification after its demodulation in the detector circuit before it is given to the CRT.</li> <li>Time Delay: It is desired in the special case such as the trace on CRT can be delayed so that it can be expanded to obtain a better display.</li> <li>Time maker: This produces pulses of known time. They are given to the video amplifier and then to the CRT for the display along with the echos.</li> <li>Display: There are two display format. They are: A-mode display and B-mode display.</li> </ol>

Q4:

Write short notes on :

  • A mode display
  • B mode display

Type: Short Difficulty: Easy

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Answer: <p>A mode display: This mode is also known as amplitude modulated mode. A single beam of untrasound is used for this mode and it gives only one dimensional information.The echo signals are applied to the CRT andthey are displayed as vertical reflections as the beam is swept across the CRT. The reflected echoes are shown as peaks along the horizontal axis. The height of the peak displayed is directly proportional to the strength of the corresponding echo. The applications of A mode are as follows:</p> <ul><li>It is used in the instrument called Echo-encephalography to detect mid-line of the brain.</li> <li>It is also used in instrument called Echo-opthalmoscope for the diagnosis of retinal detachment &amp; lens dislocation.</li> </ul><p>B mode display: This mode mode is aslo known as brightness modulated mode. Here multiple beams of ultrasound are used to give two dimensional information.The structure in B mode appears as light of dots whose position is related to the echoing interface with the body. This mode is also called "Grey Scale Imaging". This is the most popular mode of display used. The applications of B mode are as follows:</p> <ul><li>It is used to detect the size, location, displacement and velocity of various internal structures of the body for the diagnosis of stones, tumors etc.</li> <li>It is also used to detect foetus within the uterus.</li> </ul>

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Isochoric, Isobaric, Reversible and Irreversible Process

Isochoric, Isobaric, Reversible and Irreversible Process

Isochoric Process

If a substance undergoes a process in which the volume remains constant, the process is called isochoric process.

Work done for Isochoric Process

Ideal gas equation for n-mole

$$\frac {P}{T} = \frac {n R}{V}$$

In this process volume of system is constant

$$\text {So,} \frac {P}{T} = K [\because \frac {nR}{T} is constant ]$$

work done

$$W = \int _{v_1}^{v_2}P dV$$

$$= 0[\because \text {no change in volume}]$$

Variation of pressure and volume in isothermal, adiabatic, isobaric and isochoric processes
Variation of pressure and volume in isothermal, adiabatic, isobaric and isochoric processes

Isobaric Process

If the working substance is taken in an expanding chamber in which the pressure is kept constant, the process is called isobaric process.

Work done for Isobaric Process

Ideal gas equation for n-mole

$$PV = n RT$$

$$\frac {V}{T} = \frac {n R}{P}$$

$$\frac {V}{T} = \text {constant} $$

work done

$$W = \int _{v_1}^{v_2}P dV$$

$$ =P \int _{v_1}^{v_2} dV$$

$$=P(V_2 - V_1) $$

Variation of pressure and volume during reversible process.
Variation of pressure and volume during reversible process.

Reversible process

A reversible process is one which can be retraced in the reverse order, so that it passes exactly through the same state as in the direct process.

P-V diagram for a reversible process is shown in the figure.

Examples of reverse process

  1. All mechanical processes taking place under the action of conservative force.
  2. An infinitesimally slow expansion and compression of an ideal gas at a constant pressure.
  3. All thermal processes taking place at an infinitesimally slow rate.

Conditions for Reversible Process

  1. All the process taking place in the cycle of operation must be infinitely slow.
  2. There should not be any loss of energy due to conduction or radiation during the cycle of operation.

P-V diagram of the irreversible process.
P-V diagram of the irreversible process.

Irreversible process

Those processes which can not be retracted in the opposite order by reversing the controlling factors are known as shown in the figure.

Examples of irreversible process

  1. Rusting of iron
  2. Dissolving of soap in water
  3. Decay of matter
  4. Flow of current through the conductor.

Limitations of the First Law of Thermodynamics

The first law of thermodynamics has the following limitations:

  1. First law of thermodynamics does not indicate the direction of the heat transfer.
  2. First law of thermodynamics does not explain the phenomena why the process is reversible or irreversible.
  3. The first law off thermodynamics does not give to what extent the mechanical energy is obtained from the heat energy.

Lesson

First Law of Thermodynamics

Subject

Physics

Grade

Grade 11

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