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2 years ago

Calculate the volume occupied by 56.5 g of argon gas at STP

2 answers:

5 0

Molar mass of argon = 39.95 grams
number of moles of Argon = mass / molar mass
number of moles of Argon = 56.5 / 39.95 = 1.414 moles

At STP, one mole of gas occupies 22.4 liters. To know the volume that 1.414 moles occupy, all you have to do is cross multiplication as follows:
volume = (1.414*22.4) / 1 = 31.679 liters

barxatty [35]2 years ago

3 0

<span>31.7 liters if using the pre 1982 definition of STP. 32.1 liters if using the post 1981 definition of STP. First, determine how many moles of argon you have by dividing the mass you have by the atomic weight of argon. So 56.5 g / 39.948 g/mol = 1.41433864 mol Second, determine what definition of STP you're using. the definition prior to 1982 of STP was 0Â°C with a pressure of 1 atmosphere (1.01325 X 10^5 Pascals). The definition for 1982 and later is 0Â°C with a pressure of 1 X 10^5 Pascals. There are still quite a few textbooks that use the older definition of STP so I'll be giving the results for both the old and new definitions of STP. To calculate the volume of an ideal gas, just multiply the number of moles by a constant. That constant is 22.710980 liters/mol for the 1982 and later standard and 22.414 liters/mol for the pre 1982 standard. So Pre 1982 1.414339 * 22.414 = 31.70098628 liters = 31.7 liters post 1981 1.414339 * 22.71098 = 32.12101657 liters = 32.1 liters</span>

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Answer:

Explanation:

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2 years ago

How much energy is required to melt a 500. gram block of iron? The heat of vaporization is 6090 J/g and the heat of fusion is 24

galben [10]

The mass of iron block is 500 g. The amount of energy required to melt the iron block needs to be calculated. Melting means conversion of solid to liquid thus, heat of fusion is used which is 247 J/g.

From heat of fusion, 247 J of energy is released by melting 1 g of iron block. Thus, the amount of heat released by melting 500 g of iron rod will be:

H= 247 J/g× 500 g=1.23×10^{5}

Hence, option B is correct.

3 0

2 years ago

Read 2 more answers

Suppose you are titrating vinegar, which is an acetic acid solution of unknown strength, with a sodium hydroxide solution accord

Marina CMI [18]

Answer:

$M_{acid}=0.563M$

Explanation:

Hello there!

In this case, given the neutralization of the acetic acid as a weak one with sodium hydroxide as a strong base, we can see how the moles of the both of them are the same at the equivalence point; thus, it is possible to write:

$M_{acid}V_{acid}=M_{base}V_{base}$

Thus, we solve for the molarity of the acid to obtain:

$M_{acid}=\frac{M_{base}V_{base}}{V_{acid}} \\\\ M_{acid}=\frac{33.98mL*0.1656M}{10.0mL}\\\\ M_{acid}=0.563M$

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2 years ago

Which will not appear in the equilibrium constant expression for the reaction below?

n200080 [17]

Answer:

[C] carbon solid

Explanation:

Pure solids and liquids are never included in the equilibrium constant expression because they do not affect the reactant amount at equilibrium in the reaction, thus since your equation has [C] as solid it will not be part of the equlibrium equation.

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2 years ago

Consider the reaction H2(g) + Cl2(g) → 2HCl(g)ΔH = −184.6 kJ / mol If 2.00 moles of H2 react with 2.00 moles of Cl2 to form HCl,

zalisa [80]

Answer:

ΔU=-369.2 kJ/mol.

Explanation:

We start from the equation:

Δ(H)=ΔU+Δ(PV), which is an extension of the well known relation: H=U+PV.

If Δ(PV) were calculated by ideal gas law,

PV=nRT

Δ(PV)=RTΔn.

Where Δn is the change of moles due to the reaction; but, this reaction does not give a moles change (Four moles of HCl produced from 4 moles of reactants), so Δ(PV)=0.

So, for this case, ΔH=ΔU.

The enthalpy of reaction given is for one mole of reactant, so the enthalpy of reaction for the reaction of interest must be multiplied by two:

$2 reactant moles*\frac{-184.6kJ}{mol}$

ΔU=-369.2 kJ/mol.

4 0

2 years ago