An ideal gas at 484 K has a pressure of 103 kPa and a volume of 2.15m^3. What is the root mean square speed of a molecule in the gas if its mass is 2 * 10 ^ - 26 kg?

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An ideal gas at 484 K has a pressure of 103 kPa and a volume of 2.15m^3. What is the root mean square speed of a molecule in the gas if its mass is 2 * 10 ^ - 26 kg?

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nearnwales · Answer 1 · 2023-01-25T10:03:25+0000

To calculate the root mean square (RMS) speed of a molecule in an ideal gas, we can use the equation:

v = √(3 * k * T / m)

Where: v is the RMS speed of the molecule. k is the Boltzmann constant (1.38 * 10^-23 J/K). T is the temperature in Kelvin. m is the mass of the molecule.

Let's plug in the given values:

T = 484 K m = 2 * 10^-26 kg

v = √(3 * (1.38 * 10^-23 J/K) * (484 K) / (2 * 10^-26 kg))

Calculating this equation gives us:

v ≈ 1261 m/s

Therefore, the root mean square speed of a molecule in the gas is approximately 1261 m/s.

An ideal gas at 484 K has a pressure of 103 kPa and a volume of 2.15m^3. What is the root mean square speed of a molecule in the gas if its mass is 2 * 10 ^ - 26 kg?

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