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NEET Exam  >  NEET Tests  >  Chemistry Class 11  >  Test: Molecular Velocity (Old NCERT) - NEET MCQ

Test: Molecular Velocity (Old NCERT) - NEET MCQ


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20 Questions MCQ Test Chemistry Class 11 - Test: Molecular Velocity (Old NCERT)

Test: Molecular Velocity (Old NCERT) for NEET 2024 is part of Chemistry Class 11 preparation. The Test: Molecular Velocity (Old NCERT) questions and answers have been prepared according to the NEET exam syllabus.The Test: Molecular Velocity (Old NCERT) MCQs are made for NEET 2024 Exam. Find important definitions, questions, notes, meanings, examples, exercises, MCQs and online tests for Test: Molecular Velocity (Old NCERT) below.
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Test: Molecular Velocity (Old NCERT) - Question 1
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Direction (Q. Nos. 1-15) This section contains 15 multiple choice questions. Each question has four choices (a), (b), (c) and (d), out of which ONLY ONE option is correct.

Q. Pressure and temperature needed to confine 1.0 x 1025 gas molecules, each with a mass of 1.0x 1025 kg and root mean square velocity of 1.0x 103ms-1 in a 1.0 m3 container are 

Detailed Solution for Test: Molecular Velocity (Old NCERT) - Question 1

Applying the formula 
PV = 1/3(mNV2rms)
Where m = mass of each particle and N = no of particles
We get P = 3.33*105 pascal or 3.3 bar
 Applying the formula
Vrms = √(3RT/M)
 We get T = 2405 K(approx)
So option a is correct. 

Test: Molecular Velocity (Old NCERT) - Question 2
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At 298 K, which of the following gases has the lowest average molecular speed?

Detailed Solution for Test: Molecular Velocity (Old NCERT) - Question 2

Under the same conditions the average kinetic energy of the gases should be equal.
speed of gas1/speed of gas 2 = square root of (molar mass of gas2/molar mass of gas 1)
So gases with small molar mass will move quicker
eg speed of N2/speed of CO2 = sq. rt (44/28) = 1.25
speed of N2/speed of F2 = sq rt. (38/28) = 1.16
So order is N2, F2 and CO2
then we concluded right ans. is (A)

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Test: Molecular Velocity (Old NCERT) - Question 3
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By what ratio will the average velocity of the molecules in a gas change when the temperature is raised from 50°C to 200°C?

Detailed Solution for Test: Molecular Velocity (Old NCERT) - Question 3


This is the correct answer. If we take v200/v50, then we will get option b. But that is not according to the question.

Test: Molecular Velocity (Old NCERT) - Question 4
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The root mean square velocity of a monoatomic gas (molar mass = m g mol-1) is u. Its kinetic energy per mole (E) is related to u by equation
Detailed Solution for Test: Molecular Velocity (Old NCERT) - Question 4

K.E = ½ × mass × Vrms2
Dividing both sides by moles
K.E/Moles = ½ × mass × Vrms2 /Mole
K.E/mole = ½ Vrms2 × molar mass
Given, K.E/mole = E, molar mass = m and Vrms = u
E = ½ × m × u2
u2 = 2E/m 
u = √(2E/m)

Test: Molecular Velocity (Old NCERT) - Question 5
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Root mean square velocity (u) is dependent on temperature. Value of  is
Detailed Solution for Test: Molecular Velocity (Old NCERT) - Question 5

The correct answer is option B
Root mean square is v=under root 3RT/M
so we simply do differentiation with respect to temperature DU/DT=D /DT 
So,
=  3R/2M

Test: Molecular Velocity (Old NCERT) - Question 6
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The pressure needed to confine 1.00 mole of N2 molecules to 24.8 L flask is 1.0 bar. Thus, root mean square velocity of the gas assuming ideal behaviour is
Detailed Solution for Test: Molecular Velocity (Old NCERT) - Question 6

Vrms = √ 3RT/M = √ 3pV/M
 = √ (3×105 × 24.8×10-3)/28    
 = 51.4 ms-1 
So according to me, option A is correct

Test: Molecular Velocity (Old NCERT) - Question 7
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The ratio between the root mean square speed of H2 gas at 50 K and that of O2 gas at 800 K is

[IIT JEEE 1996]
Detailed Solution for Test: Molecular Velocity (Old NCERT) - Question 7

Test: Molecular Velocity (Old NCERT) - Question 8
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The rms velocity of hydrogen gas is √7 times of the rms velocity of nitrogen gas. If T is the temperature of the gas, then

[IIT JEE 2000]
Detailed Solution for Test: Molecular Velocity (Old NCERT) - Question 8

Test: Molecular Velocity (Old NCERT) - Question 9
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For CO2, given that average velocity at T, is equal to most probable velocity at T2.

Thus, T1/T2 is 
Test: Molecular Velocity (Old NCERT) - Question 10
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For gaseous state, if most probable speed is denoted by C*, average speed by  and mean square speed by C, then for a large number of molecules, the ratios of these speeds are

[JEE Main 2013]
Detailed Solution for Test: Molecular Velocity (Old NCERT) - Question 10

RMS velocity = √ (3RT/M) = 1.732k
Average velocity = √ (8RT/πM)
Most probable velocity = √ (2RT/M)
=√2:√8/π:√3=1:1.128:1.225
 
So, C∗:C:C=1:1.128:1.225

Test: Molecular Velocity (Old NCERT) - Question 11
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Molar mass of a certain gas B is double that of A.

Also RMS velocity of gas A is 200 ms -1 at a certain temperature. RMS velocity of gas B at the temperature half that of A is 
Detailed Solution for Test: Molecular Velocity (Old NCERT) - Question 11

The correct answer is Option B.
Molar mass of B  is double that of A.
2 MA = 8 MB

Test: Molecular Velocity (Old NCERT) - Question 12
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A vessei of capacity 1 dm3 contains 1.03 x 1023 H2 molecules exerting a pressure of 101.325 kPa. Calculate RMS speed and average speed.
Detailed Solution for Test: Molecular Velocity (Old NCERT) - Question 12

V = 1dm3 = 10-3m3
M.w = 2*10-3g
P = 101.325kPa
= 1.03*1023 H2 mol
No of moles = number of molecules/NA
= 1.03/6.023
= 101.325 * 103 * 10-3 = 8.314 * 1.03/6.023 * T
T = 71.27K
uavg = (8RT/πM)1/2
= [(8*8.314*71.27)/(3.142*2*10-3)]^1/2
= 868.53 m/s
urms = (3RT/M)1/2
[(3*8.314*71.27)/(2*10-3)]1/2
= 942.5 m/s

Test: Molecular Velocity (Old NCERT) - Question 13
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The molecular velocity of any gas is

[AlEEE 2011]
Detailed Solution for Test: Molecular Velocity (Old NCERT) - Question 13

The molecular velocity of any gas whether it is average velocity, root mean square velocity and most probable velocity. It must be proportional to the square to the square root of absolute temperature.

Test: Molecular Velocity (Old NCERT) - Question 14
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Distribution of molecules with velocity is represented by the curve as shown   Select the correct statement(s).

 
*Multiple options can be correct
Test: Molecular Velocity (Old NCERT) - Question 15
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Select the correct statement (s).
*Answer can only contain numeric values
Test: Molecular Velocity (Old NCERT) - Question 16
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Direction (Q. Nos. 16 and 17) This section contains 2 questions. when worked out will result in an integer from 0 to 9 (both inclusive).

Q. Temperature of an ideal gas is changed from -173°C to 127°C. Thus average velocity changes by .......... times.

Detailed Solution for Test: Molecular Velocity (Old NCERT) - Question 16

T1 = 273 - 173 = 100K
T2 = 273 + 127 = 400K
c1/c2 = (T1/T2)^1/2
c1/c2 = (100/400)^1/2
c1/c2 = (1/4)^1/2
c1/c2 = 1/2
c2 = 2c1

*Answer can only contain numeric values
Test: Molecular Velocity (Old NCERT) - Question 17
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At what temperature (in °C) root mean square velocity of O2 gas at 300 K is equal to most probable velocity of Ne(20 g mol-1)?

Detailed Solution for Test: Molecular Velocity (Old NCERT) - Question 17

Vrms = √(3RT/M)
Vmp 0= √(2RT/M)
Putting corresponding values,
3×300/32 = 2×T/20
On solving, we get T = 281.5K
T in °C = 281.5-273 = 8.1 °C = 8

Test: Molecular Velocity (Old NCERT) - Question 18
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Direction (Q. Nos. 18-20) This section contains a paragraph, wach describing theory, experiments, data etc. three Questions related to paragraph have been given.Each question have only one correct answer among the four given options (a),(b),(c),(d).

Distribution of molecular velocities was studied by Maxwell and is given by


 is also called probability P.

 

Q. 
Based on following curves, arrange temperatures T1 , T2 and T3 in increasing order,​
Detailed Solution for Test: Molecular Velocity (Old NCERT) - Question 18

The correct answer is option (C)
The correct order of temperature is,
T1  < T2 < T3
For a particular speed, the number of molecules having that speed is more at lower temperature than the number of molecules having that speed is more at higher temperature.
 

Test: Molecular Velocity (Old NCERT) - Question 19
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Distribution of molecular velocities was studied by Maxwell and is given by

 is also called probability P.

 

Q. Following is the distribution of molecules at 300 K for gases X, Y and Z

Thus,
Test: Molecular Velocity (Old NCERT) - Question 20
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Distribution of molecular velocities was studied by Maxwell and is given by

 is also called probability P.

Q. 
As velocity increases, probability also increases. It is maximum at a particular velocity. This is called most probable velocity. At this point, variation of probability P with velocity u is 

Thus, based on this, velocity is
Detailed Solution for Test: Molecular Velocity (Old NCERT) - Question 20

The correct answer is Option B.
The speed of an individual gas particle is:

The most probable speed is the maximum value on the distribution plot.

This is established by finding the velocity when the derivative of Equation;

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