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2 years ago

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Consider the following reaction at 298 K: 2H2S(g)+SO2(g)→3S(s, rhombic)+2H2O(g),ΔG∘rxn=−102 kJ Calculate ΔGrxn under these condi

tions: PH2SPSO2PH2O===2.00 atm1.50 atm0.0100 atm

1 answer:

vodka [1.7K]2 years ago

4 0

<u>Answer:</u> The $\Delta G$ for the reaction is 74.732 kJ/mol

<u>Explanation:</u>

For the given chemical reaction:

$2H_2S(g)+SO_2(g)\rightleftharpoons 3S\text{(s, rhombic)}+2H_2O(g)$

The expression of $K_p$ for the given reaction:

$K_p=\frac{(p_{H_2O})^2\times (p_{S\text{s,rhombic}})^3}{(p_{H_2S})^2\times p_{SO_2}}$

We are given:

$p_{H_2O}=0.0100atm\\p_{H_2S}=2.00atm\\p_{SO_2}=1.50atm\\p_{S\text{s, rhombic}}=1atm$

Partial pressure of solids are taken as 1.

Putting values in above equation, we get:

$K_p=\frac{(0.0100)^2}{(2.00)^2\times 1.50}\\\\K_p=1.66\times 10^{-5}$

To calculate the Gibbs free energy of the reaction, we use the equation:

$\Delta G=\Delta G^o+RT\ln K_p$

where,

$\Delta G$ = Gibbs free energy of the reaction = ?

$\Delta G^o$ = Standard Gibbs' free energy change of the reaction = 102 kJ = 102000 J (Conversion factor: 1 kJ = 1000 J)

R = Gas constant = $8.314J/K mol$

T = Temperature = 298 K

$K_p$ = equilibrium constant in terms of partial pressure = $1.66\times 10^{-5}$

Putting values in above equation, we get:

$\Delta G=102000J+(8.314J/K.mol\times 298K\times \ln(1.66\times 10^{-5}))\\\\\Delta G=74731.6J/mol=74.732kJ/mol$

Hence, the $\Delta G$ for the reaction is 74.732 kJ/mol

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Which of the following statements is true about the following reaction?

MAVERICK [17]

The correct reaction equation is:

$3NaHCO_{3} (aq) + C_{6}H_{8}O_{7} (aq) \rightarrow 3CO_{2} (g) + 3H_{2}O (l) + Na_{3}C_{6}H_{5}O_{7} (aq)$

Answer:

b) 1 mole of water is produced for every mole of carbon dioxide produced.

Explanation: <u>CONVERT EVERYTHING TO MOLES OR VOLUME, THEN COMPARE IT WITH THE COMPOUND'S STOICHIOMETRY IN CHEMICAL EQUATION.</u>

a) <u>22.4 L of $CO_{2}$ gas</u> is produced only when <u> $\frac{22.4}{3}$ L of $C_{6}H_{8}O_{7}$ </u> is reacted with 22.4 L of $NaHCO_{3}$ . So it is wrong.

b) Since in the chemical equation the stoichiometric coefficient of $CO_{2}$ and $H_{2}O$ are same so the number of moles or volume of each of them will be same whatever the amount of reactants taken. <u>Therefore it is correct option.</u>

c) $6.02\times 10^{23}$ molecules is equal 1 mole of $Na_{3}C_{6}H_{5}O_{7}$ if produced then 3 moles of $NaHCO_{3}$ is required, which is not given in the option. So it is wrong.

d) 54 g of water or 3 moles of $H_{2}O$ (<em>Molecular Weight of water is 18 g</em>) is produced when 3 moles of $NaHCO_{3}$ is used but in this option only one mole of $NaHCO_{3}$ is given. So it is wrong.

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2 years ago

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2.00 g of an unknown gas at STP fills a 500. mL flask. What is the molar mass of the gas?

otez555 [7]

Answer:

100g/mol

Explanation:

Given parameters:

Mass of unknown gas = 2g

Volume of gas in flask = 500mL = 0.5dm³

Unknown:

Molar mass of gas = ?

Solution:

Since we know the gas is at STP;

1 mole of substance occupies 22.4dm³ of space at STP

Therefore,

0.5dm³ will have 0.02mole at STP

Now;

Number of moles = $\frac{mass}{molar mass}$

Molar mass = $\frac{mass}{number of moles}$ = $\frac{2}{0.02}$ = 100g/mol

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2 years ago

A 32.5 g piece of aluminum (which has a specific heat capacity of 0.921 J/g°C) is heated to 82.4°C and dropped into a calorimete

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Answer:

The mass of water = 219.1 grams

Explanation:

Step 1: Data given

Mass of aluminium = 32.5 grams

specific heat capacity aluminium = 0.921 J/g°C

Temperature = 82.4 °C

Temperature of water = 22.3 °C

The final temperature = 24.2 °C

Step 2: Calculate the mass of water

Heat lost = heat gained

Qlost = -Qgained

Qaluminium = -Qwater

Q = m*c*ΔT

m(aluminium)*c(aluminium)*ΔT(aluminium) = -m(water)*c(water)*ΔT(water)

⇒with m(aluminium) = the mass of aluminium = 32.5 grams

⇒with c(aluminium) = the specific heat of aluminium = 0.921 J/g°C

⇒with ΔT(aluminium) = the change of temperature of aluminium = 24.2 °C - 82.4 °C = -58.2 °C

⇒with m(water) = the mass of water = TO BE DETERMINED

⇒with c(water) = 4.184 J/g°C

⇒with ΔT(water) = the change of temperature of water = 24.2 °C - 22.3 °C = 1.9 °C

32.5 * 0.921 * -58.2 = -m * 4.184 * 1.9

-1742.1 = -7.95m

m = 219.1 grams

The mass of water = 219.1 grams

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2- As for XCl3: we can deduce that the valency of chlorine is one while that of X is three

Second step is to write the required compound:
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