Question #e66a1

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Question #e66a1

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Answer 1 · 2015-06-14T15:35:28

Under those conditions for temperature and pressure, 0.3 moles of methane would occupy that volume.

Explanation:

You have all the information you need to solve for the number of moles of methane that would occupy 4.3 L at a temperature of 400 K and a pressure of 2 atm.

Your tool of choice will be the ideal gas law equation

$P V = n R T$ $PV = nRT$ , where

$P$ $P$ - pressure;
$V$ $V$ - the volume the gas occupies;
$n$ $n$ - the number of moles of gas;
$R$ $R$ - the ideal gas constant, equal to $0.082 \frac{atm \cdot L}{mol \cdot L}$ $0.082("atm" * "L")/("mol" * "L")$
$T$ $T$ - the temperature of the gas.

Plug your values into the equation and solve for $n$ $n$

$P V = n R T \Rightarrow n = \frac{P V}{R T}$ $PV = nRT => n = (PV)/(RT)$

$n = (2cancel("atm") * 4.3cancel("L"))/(0.082(cancel("atm") * cancel("L"))/("mol" * cancel("K")) * 400cancel("K"))$

$n = "0.262 moles"$

Rounded to one sig fig, the number of sig figs you gave for the temperature of the gas, the answer will be

$n = color(green)("0.3 moles")$

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Question #e66a1

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