A gas bubble (gas density g = 2 kg / m3; bubble diameter D = 104 m) is rising vertically through water (density = 1000 kg / m3 ; viscosity = 0.001 Pa.s). Force balance on the bubble leads to the following equation, Where is the velocity of the bubble at any given time t. Assume that the volume of the rising bubble does not change. The value of g = 9.81m / s2. The terminal rising velocity of the bubble (in cm/s), rounded to 2 decimal places, is ___ cm/s.Correct answer is '0.54'. Can you explain this answer?

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A gas bubble (gas density ρ_g = 2 kg / m³; bubble diameter D = 10⁻⁴ m) is rising vertically through water (density ρ = 1000 kg / m³ ; viscosity µ = 0.001 Pa.s). Force balance on the bubble leads to the following equation,

Where ν is the velocity of the bubble at any given time t. Assume that the volume of the rising bubble does not change. The value of g = 9.81m / s². The terminal rising velocity of the bubble (in cm/s), rounded to 2 decimal places, is ___ cm/s.

Correct answer is '0.54'. Can you explain this answer?

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A gas bubble (gas density ρg = 2 kg / m3; bubble diameter D = 10−4 m) is rising vertically through water (density ρ = 1000 kg / m3 ; viscosity µ = 0.001 Pa.s). Force balance on the bubble leads to the following equation, Where ν is the velocity of the bubble at any given time t. Assume that the volume of the rising bubble does not change. The value of g = 9.81m / s2. The terminal rising velocity of the bubble (in cm/s), rounded to 2 decimal places, is ___ cm/s.Correct answer is '0.54'. Can you explain this answer?

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