Advertisements
Advertisements
प्रश्न
An air bubble of radius 2.0 mm is formed at the bottom of a 3.3 m deep river. Calculate the radius of the bubble as it comes to the surface. Atmospheric pressure = 1.0 × 105 Pa and density of water = 1000 kg m−3.
Advertisements
उत्तर
Here,
\[ V_1 = \frac{4}{3}\pi {(2.0 \times {10}^{-3 })}^3 \]
h = 3.3 m
P1 = Po + ρgh
⇒ P1 = 1.0 × 105 + 1000 × 9.8 × 3.3
⇒ P1 = 1.32 × 105 Pa
P2 = 1.0 × 105 Pa
Since temperature remains the same, applying Boyle's law we get
P1 V1 = P2 V2
⇒ V2 = \[ \frac {P_1 V_1}{P_2} \]
⇒ V2 = \[ \frac{1.32 × {10}^5 × \frac{4}{3}\pi {(2.0 ×{10}^{-3} )}^3}{1.0 × {10}^5} \]
Let R2 be the new radius. Then,
\[ \frac{4}{3}\pi R_2^3 \] = \[ \frac{1.32 × {10}^5 × \frac{4}{3}\pi {(2.0 × {10}^{-3} )}^3}{1.0 ×{10}^5} \]
⇒ \[ R_2^3 = \frac{1.32 × {10}^5 × {(2.0 × {10}^{-3 })}^3}{1.0 × {10}^5} \]
⇒ \[ R_3 = \sqrt[3]{\frac{1.32 × {10}^5× {(2.0 × {10}^{-3} )}^3}{1.0 × {10}^5}} \]
⇒ R3 = 2.2 × 10-3 m
APPEARS IN
संबंधित प्रश्न
From a certain apparatus, the diffusion rate of hydrogen has an average value of 28.7 cm3 s–1. The diffusion of another gas under the same conditions is measured to have an average rate of 7.2 cm3 s–1. Identify the gas
[Hint: Use Graham’s law of diffusion: R1/R2 = (M2/M1)1/2, where R1, R2 are diffusion rates of gases 1 and 2, and M1 and M2 their respective molecular masses. The law is a simple consequence of kinetic theory.]
While gas from a cooking gas cylinder is used, the pressure does not fall appreciably till the last few minutes. Why?
A gas is kept in a rigid cubical container. If a load of 10 kg is put on the top of the container, does the pressure increase?
Explain why cooking is faster in a pressure cooker.
A gas behaves more closely as an ideal gas at
The pressure of a gas kept in an isothermal container is 200 kPa. If half the gas is removed from it, the pressure will be
2 g of hydrogen is sealed in a vessel of volume 0.02 m3 and is maintained at 300 K. Calculate the pressure in the vessel.
Use R=8.3J K-1 mol-1
A container of volume 50 cc contains air (mean molecular weight = 28.8 g) and is open to atmosphere where the pressure is 100 kPa. The container is kept in a bath containing melting ice (0°C). (a) Find the mass of the air in the container when thermal equilibrium is reached. (b) The container is now placed in another bath containing boiling water (100°C). Find the mass of air in the container. (c) The container is now closed and placed in the melting-ice bath. Find the pressure of the air when thermal equilibrium is reached.
Use R = 8.3 J K-1 mol-1
Is a slow process always isothermal? Is a quick process always adiabatic?
An ideal gas is kept in a long cylindrical vessel fitted with a frictionless piston of cross-sectional area 10 cm2 and weight 1 kg. The length of the gas column in the vessel is 20 cm. The atmospheric pressure is 100 kPa. The vessel is now taken into a spaceship revolving round the earth as a satellite. The air pressure in the spaceship is maintained at 100 kPa. Find the length of the gas column in the cylinder.
Use R = 8.3 J K-1 mol-1
The initial pressure and volume of a given mass of a gas (Cp/Cv = γ) are p0 and V0. The gas can exchange heat with the surrounding. (a) It is slowly compressed to a volume V0/2 and then suddenly compressed to V0/4. Find the final pressure. (b) If the gas is suddenly compressed from the volume V0 to V0/2 and then slowly compressed to V0/4, what will be the final pressure?
Three samples A, B and C of the same gas (γ = 1.5) have equal volumes and temperatures. The volume of each sample is doubled, the process being isothermal for A, adiabatic for B and isobaric for C. If the final pressures are equal for the three samples, find the ratio of the initial pressures.
The human body has an average temperature of 98°F. Assume that the vapour pressure of the blood in the veins behaves like that of pure water. Find the minimum atmospheric pressure which is necessary to prevent the blood from boiling. Use figure for the vapour pressures.
A faulty barometer contains certain amount of air and saturated water vapour. It reads 74.0 cm when the atmospheric pressure is 76.0 cm of mercury and reads 72.10 cm when the atmospheric pressure is 74.0 cm of mercury. Saturation vapour pressure at the air temperature = 1.0 cm of mercury. Find the length of the barometer tube above the mercury level in the reservoir.
The temperature and humidity of air are 27°C and 50% on a particular day. Calculate the amount of vapour that should be added to 1 cubic metre of air to saturate it. The saturation vapour pressure at 27°C = 3600 Pa.
Use R = 8.3 J K-1 mol-1
If 1022 gas molecules each of mass 10-26 kg collide with a surface (perpendicular to it) elastically per second over an area of 1 m2 with a speed of 104 m/s, the pressure exerted by the gas molecules will be of the order of ______.
