g On the basis of their respective pKa values, determine which is the stronger acid, acetic acid (pKa 5 4.7) or benzoic acid (margin; pKa 5 4.2). By what factor do their acidities differ?

Answer : The pH of the solution is, 1.88

Explanation : Given,

[tex]K_a=1.1\times 10^{-2}[/tex]

Concentration of [tex]HClO_2[/tex] = 0.35 M

Concentration of [tex]NaClO_2[/tex] = 0.29 M

First we have to calculate the value of [tex]pK_a[/tex].

The expression used for the calculation of [tex]pK_a[/tex] is,

[tex]pK_a=-\log [K_a][/tex]

Now put the value of [tex]K_a[/tex] in this expression, we get:

[tex]pK_a=-\log (1.1\times 1-^{-2})[/tex]

[tex]pK_a=2-\log (1.1)[/tex]

[tex]pK_a=1.96[/tex]

Now we have to calculate the pH of the solution.

Using Henderson Hesselbach equation :

[tex]pH=pK_a+\log \frac{[Salt]}{[Acid]}[/tex]

[tex]pH=pK_a+\log \frac{[NaClO_2]}{[HClO_2]}[/tex]

Now put all the given values in this expression, we get:

[tex]pH=1.96+\log (\frac{0.29}{0.35})[/tex]

[tex]pH=1.88[/tex]

Therefore, the pH of the solution is, 1.88

The pH of a buffer solution consisting of a weak acid and its conjugate base can be calculated using the Henderson–Hasselbalch equation, with the concentrations of the weak acid and base, and the Ka or pKa of the weak acid.

In this scenario, we are dealing with a weak acid, chlorous acid (HClO2), and the salt of its conjugate base, sodium chlorite (NaClO2). When a weak acid is in solution with the salt of its conjugate base, a buffer solution is formed. Buffer solutions resist significant changes in pH upon the addition of small quantities of acid or base. The pH of the buffer solution can be calculated using the Henderson–Hasselbalch equation:

pH = pKa + log([A-]/[HA]).

Where,

Using the given concentrations and Ka or pKa, substitute them into the formula to calculate the pH of the solution.

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Answer:

0.25 M ammonium nitrate + 0.40 M ammonia  

0.39 M hypochlorous acid + 0.25 M potassium hypochlorite

0.12 M hydrofluoric acid + 0.14 M sodium fluoride  

Explanation:

A buffer consists of a weak acid and its salt or a weak base and its salt.

NH₃ is a weak base, and HClO and HF are weak acids.

B is wrong. HNO₃ is a strong acid.

C is wrong. KOH is a strong base.

Answer:

The number of moles of CaCO3 on the bag is 112.90 moles

Explanation:

number mole (n) = mass (m) divided by molecular mass (Mm)

Mm of CaCO3 = 100.0869 g/mole

mass in grams = 11.3 Kg x (10^3 g/1 Kg) = 11300 grams

number of moles (n) = 11300 grams divided by 100.0869 grams per mole = 112.90 moles of CaCO3 in the bag.

The number of moles of CaCO3 in an 11.3 kg bag is calculated by dividing the mass of the CaCO3 by its molar mass.

First, we need to determine the molar mass of CaCO3. The molar mass of calcium (Ca) is approximately 40.08 g/mol, carbon (C) is approximately 12.01 g/mol, and oxygen (O) is approximately 16.00 g/mol. Since there is one atom of calcium, one atom of carbon, and three atoms of oxygen in CaCO3, the molar mass of CaCO3 is calculated as follows:

 Molar mass of CaCO3 = [tex](40.08 g/mol) + (12.01 g/mol) + (3 -16.00 g/mol)[/tex]

Molar mass of CaCO3 = [tex]40.08 g/mol + 12.01 g/mol + 48.00 g/mol[/tex]

Molar mass of CaCO3 = [tex]100.09 g/mol[/tex]

Now, we convert the mass of the bag from kilograms to grams because the molar mass is given in grams per mole:

[tex]11.3 kg - 1000 g/kg = 11300 g[/tex]

 Finally, we calculate the number of moles of CaCO3 in the bag:

 Number of moles = mass of CaCO3 / molar mass of CaCO3

[tex]Number of moles[/tex] =[tex]11300 g / 100.09 g/mol[/tex]

[tex]Number of moles = 113 moles[/tex]

 Therefore, the bag contains approximately 113 moles of CaCO3.

 The correct answer is [tex]\boxed{113 \text{ moles}}.[/tex]

 The answer is: [tex]113 \text{ moles}.[/tex]

Answer:

a) yes, it was an hydrate

b) the number of waters of hydration, x = 6

Explanation:

a) yes it was an hydrate because the mass decreased after the process of dehydration which means removal of water thus some water molecules were present in the sample.

b) NiCl2. xH2O

mass if dehydrated NiCl2 = 2.3921 grams

mass of water in the hydrated sample = mass of hydrated - mass of dehydrated = 4.3872 - 2.3921 = 1.9951 g which represent the mass of water that was present in the hydrated sample.

NiCl2.xH2O

mole of dehydrated NiCl2 = m/Mm = 2.3921/129.5994 = 0.01846 mole

mole of water = m/Mm = 1.9951/18.02 = 0.11072 mole

Divide both by the smallest number of mole (which is for NiCl2) to find the coefficient of each

for NiCl2 = 0.01846/0.01846 = 1

for H2O = 0.11072/0.01846 = 5.9976 = 6

thus the hydrated sample was NiCl2. 6H2O

The average atomic mass of titanium on the given planet is 46.800 amu.

In order to calculate the average atomic mass of titanium on the given planet, we multiply the mass of each isotope by its natural abundance and sum them up.

Therefore, the average atomic mass of titanium on the planet is 46.800 amu.

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Hey there!:

We are given   P = 10⁻²² N/m2 ,

Volume, V = 1 cm3= 10⁻⁶ m³ and

T= 13ºC= 13+273= 286 K

Using gas law,  P*V = n R T,  where n is number of moles and R=8.314JK⁻¹.

n = PV/(RT) =>  n = 10-12*10⁻⁶/ (8.314*286) = 4.205*10₋²² moles

Hence number of molecules = number of moles * Avogadro's number

= 4.205*10-22 moles * 6.023*1023 molecules/mole

= 253

Number of molecules = 250 (upto 2 significant figures)

Number of molecules: N = 263.31

Some of the laws regarding gas can apply to ideal gas (volume expansion does not occur when the gas is heated),:

[tex] \displaystyle P = \dfrac {1} {V} [/tex]

[tex] \displaystyle V = T [/tex]

[tex] \displaystyle V = n [/tex]

So that the three laws can be combined into a single gas equation, the ideal gas equation

In general, the gas equation can be written

[tex] \large {\boxed {\bold {PV = nRT}}} [/tex]

where

P = pressure, atm , N/m²

V = volume, liter

n = number of moles

R = gas constant = 0.082 l.atm / mol K (P= atm, v= liter),or 8,314 J/mol K (P=Pa or N/m2, v= m³)

T = temperature, Kelvin

n = N / No

n = mole

No = Avogadro number (6.02.10²³)

n = m / m

m = mass

M = relative molecular mass

Known

P = 10−12 N / m2

V = 1 cm3 = 10-6 m3

T = 2 ºC = 2 + 273 = 275 K

R = 8,314 J / mol. K

[tex]\rm n=\dfrac{PV}{RT}\\\\n=\dfrac{10^{-12}\times 10^{-6}}{8.314\times 275}\\\\n=\boxed{\bold{4.374\times 10^{-22}}}[/tex]

then the number of molecules (N):

N = n x No

N = 4,374.10⁻²² x 6.02.10²³

N = 263.31

Which equation agrees with the ideal gas law

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Which law relates to the ideal gas law

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Answer:

The statements 4 and 5 are true.

Explanation:

1. When an atom gains an electron it becomes negatively charged. This negatively charged species is called anion.

A + e⁻ →  A⁻ (anion)

Therefore, the statement 1 is false.

2.  An anion is formed when an atom gains an electron and becomes negatively charged. Therefore, an anion is a negatively charged species.

A + e⁻ →  A⁻ (anion)

Therefore, the statement 2 is false.

3. The atomic number of chlorine atom Cl is 17 and atomic number of bromine atom Br is 35.

Since, for neutral atom, the atomic number of an atom is equal to the number of electrons present in that atom.

Therefore, the number of electrons in Cl atom is 17 and the number of electrons in Br atom is 35.

When the Cl atom gains one electron it forms Cl⁻ ion and when the Br atom gains one electron it forms Br⁻ ion.

Therefore, the number of electrons in Cl⁻ ion is 17 + 1 = 18 electrons

and the number of electrons in Br⁻ ion is 35 + 1 = 36 electrons

Therefore, Cl⁻ and Br⁻ ions do not have the same number of electrons.

Therefore, the statement 3 is false.

4. When potassium atom (K) loses one electron it forms a positively charged species called potassium cation (K⁺).

K  → K⁺ + e⁻

Therefore, the statement 4 is true.

5. The atomic number of Fe atom is 26.

Since, the atomic number of an atom is equal to the number of protons present in that atom.

When the Fe atom loses two electrons to form Fe²⁺ and when the Fe atom loses three electrons to form Fe³⁺ ion, the number of protons remains the same.

Therefore, the ions Fe²⁺ and Fe³⁺ have the same number of protons.

Therefore, the statement 5 is true.

6. The atomic number of copper atom Cu is 29.

Since, for neutral atom, the atomic number of an atom is equal to the number of electrons present in that atom.

Therefore, the number of electrons in Cu atom is 29

When the Cu atom loses one electron it forms Cu⁺ ion and when the Cu atom loses two electrons it forms Cu²⁺ ion.

Cu  → Cu⁺ + e⁻                and    Cu  → Cu²⁺ + 2e⁻

Therefore, the number of electrons in Cu⁺ ion is 29 - 1 = 28 electrons

and the number of electrons in Cu²⁺ ion is 29 - 2 = 27 electrons

Therefore,  Cu⁺ ion and Cu²⁺ ion do not have the same number of electrons.

Therefore, the statement 6 is false.

Atom is the smallest constituent of any chemical species and contains protons and electrons. The true statements are, [tex]\rm K^{+}[/tex] ion is formed when a potassium atom loses one electron. The [tex]\rm Fe^{2+}[/tex] and [tex]\rm Fe^{3+}[/tex] ions have the same number of protons.

When an atom acquires electrons from some other atom then they become negatively charged and are called anions.

Cations and anions are formed when the atom loses and gains an electron from another species. When an atom acquires an electron they are called an anion and when loose electrons are called a cation.

When potassium atom (K) relinquishes an electron then a positively charged species formed is called a cation.  It can be shown as,

[tex]\rm K \rightarrow K ^{+} + e^{-}[/tex]

The atomic number of an iron atom is 26 and is equal to the number of protons. The number of protons remains the same when the iron atom relinquishes two electrons yields ferrous ions and when loses three electrons yields ferric ion. Hence, ferrous and ferric have the same number of protons.

Therefore, option 4. K+ ion is formed when a potassium atom loses one electron and option 5. ferrous and ferric ions have the same number of protons are correct.

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Answer:

[tex][H_2]_{eq}=0.0173M[/tex]

Explanation:

Hello,

In this case, for the given reaction, the law of mass action turns out:

[tex]Kc=\frac{[H_2O][CO]}{[H_2][CO_2]}[/tex]

In such a way, the reactants initial concentrations are:

[tex][CO_2]_0=[H_2]_0=\frac{0.300mol}{10.0L} =0.030M[/tex]

And considering the change [tex]x[/tex] due to the equilibrium, the law of mass action takes the following form:

[tex]Kc=\frac{(x)(x)}{(0.030M-x)(0.030M-x)} =\frac{x^2}{0.0009-0.06x+x^2} \\Kc(0.0009-0.06x+x^2)=x^2\\0.0004806-0.03204x+0.534x^2-x^2=0\\0.466x^2+0.03204x-0.0004806=0\\x_1=-0.0814M\\x_2=0.0127M[/tex]

The feasible answer is [tex]x=0.0127M[/tex]

Therefore, the hydrogen moles at equilibrium are:

[tex][H_2]_{eq}=0.030M-0.0127M=0.0173M[/tex]

Best regards.

The number of moles of H2 present at equilibrium is 0.04moles

Data;

let's find the concentration of the species in the reaction.

The concentration of CO is

[tex][CO] = \frac{0.3}{10} = 0.03M[/tex]

The concentration of H2O is

[tex][H_2O] = \frac{0.3}{10} 0.03M[/tex]

The equation of this reaction is

                H2(g) + CO2(g) ⇌ H2O(g) + CO(g)

final           -x           -x            0.03 + x     0.03 + x

The Kc i.e the equilibrium constant of this reaction is

[tex]K_c = \frac{[product]}{[reactant]}\\[/tex]

let's substitute the values and solve.

[tex]K_c = \frac{product}{reactant} \\0.534 = \frac{(0.03+x)(0.03+x)}{x * x} \\x= 0.04M[/tex]

The number of moles of H2 present at equilibrium can be calculated as

[tex]0.04 = \frac{0.04}{1}[/tex]

The number of moles of H2 present at equilibrium is 0.04moles

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Answer: 58.0 grams of sodium bicarbonate will be required.

Explanation: pH of buffer solutions is calculated using Handerson equation:

[tex]pH=pKa+log(\frac{base}{acid})[/tex]

sodium carbonate acts as a base since it has carbonate ion where as sodium bicarbonate acts as an acid since it has bicarbonate ion that has a proton.

pKa2 value will be used here since we have sodium bicarbonate and not carbonic acid. Concentration of sodium carbonate is given as 0.10 M, pH is given as 9.50 and pKa2 is given as 10.33.

Let's plug in the values in Handerson equation and calculate the concentration of sodium bicarbonate.

[tex]9.50=10.33+log(\frac{0.10}{x})[/tex]

(where [tex]x[/tex] is the concentration of sodium bicarbonate)

[tex]9.50-10.33=log(\frac{0.10}{x})[/tex]

[tex]-0.83=log(\frac{0.10}{x})[/tex]

taking antilog to both sides:

[tex]10^-^0^.^8^3=\frac{0.10}{x}[/tex]

[tex]0.145=\frac{0.10}{x}[/tex]

[tex]x=\frac{0.10}{0.145}[/tex]

[tex]x=0.69[/tex]

Concentration of sodium bicarbonate is 0.69 M. Volume of solution is given as 1.00 L. So, the moles of sodium bicarbonate will be 0.69 moles.

Molar mass of sodium bicarbonate is 84.0 gram per mol. Multiply the moles by molar mass to calculate the required grams of it.

[tex]0.69mol(\frac{84.0g}{1mol})[/tex]

= 57.96 g

So, 57.96 g which is almost 58.0 g of [tex]NaHCO_3[/tex] will be required.

The required amount of NaHCO3 required to obtain a buffer solution with pH of 9.50 will be 56.80 g

pH relationship for a buffer solution :

[tex]pH = pKa + log(\frac{base}{acid}[/tex]

[tex]9.50 = 10.33 + log(\frac{0.10}{a}[/tex]

[tex]9.50 - 10.33 = log(\frac{0.10}{a}[/tex]

[tex]-0.83 = log(\frac{0.10}{a}[/tex]

Take the inverse log of both sides

[tex] 10^{-0.83} = \frac{0.10}{a}[/tex]

[tex] 0.1479 = \frac{0.10}{a}[/tex]

[tex] a = \frac{0.10}{0.1479}[/tex]

[tex] a = 0.676 [/tex]

Concentration of NaHCO3 = 84.01 × 0.676 = 56.80 g

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Answer : The number placed in front of [tex]CuSO_4[/tex] should be, three (3).

Explanation :

Balanced chemical reaction : It is defined as the number of atoms of individual elements present on reactant side must be equal to the product side.

The given unbalanced chemical reaction is,

[tex]CaSO_4+AlCl_3\rightarrow CaCl_2+Al_2(SO_4)_3[/tex]

This chemical reaction is an unbalanced reaction because in this reaction, the number of atoms of chloride and sulfate ion are not balanced.

In order to balanced the chemical reaction, the coefficient 3 is put before the [tex]CuSO_4[/tex], the coefficient 2 is put before the [tex]AlCl_3[/tex] and the coefficient 3 is put before the [tex]CaCl_2[/tex].

Thus, the balanced chemical reaction will be,

[tex]3CaSO_4+2AlCl_3\rightarrow 3CaCl_2+Al_2(SO_4)_3[/tex]

Therefore, the number placed in front of [tex]CuSO_4[/tex] should be, three (3).

The number which should be placed in front of CaSO4 to give the same total number of sulfate ions on each side of the equation is; 3.

According to the question;

The equation given is;

?CaSO4 + AlCl3 → CaCl2 + Al2(SO4)3

There are 3 moles of SO4 on the right hand side of the equation and as such, there should be the same number of SO4 on the left too.

In essence, the number that should be added in front of CaSO4 is; 3.

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Answer: The speed of hydrogen molecule is [tex]7.199\times 10^3m/s[/tex]

Explanation:

The equation used to calculate the root mean square speed of a molecule is:

[tex]V_{rms}=\sqrt{\frac{3RT}{M}}[/tex]

where,

[tex]V_{rms}[/tex] = root mean square speed of the molecule = ?

R = Gas constant = 8.314 J/mol.K

T = temperature = 4200 K

M = molar mass of hydrogen molecule = [tex]2.02g=2.02\times 10^{-3}kg[/tex]   (Conversion factor:  1 kg = 1000 g)

Putting values in above equation, we get:

[tex]V_{rms}=\sqrt{\frac{3\times 8.314\times 4200}{2.02\times 10^{-3}}}\\\\V_{rms}=7.199\times 10^3m/s[/tex]

Hence, the speed of hydrogen molecule is [tex]7.199\times 10^3m/s[/tex]

Answer : The temperature and the final pressure of the gas is, 586.83 K and [tex]1.046\times 10^{9}atm[/tex] respectively.

Explanation : Given,

Initial volume of gas = [tex]261.6\times 10^{-6}m^3[/tex]

Final volume of the gas = [tex]138.2\times 10^{-6}m^3[/tex]

Heat released = -9340 J

First we have to calculate the temperature of the gas.

According to the question, this is the case of isothermal reversible compression of gas.

As per first law of thermodynamic,

[tex]\Delta U=q+w[/tex]

where,

[tex]\Delta U[/tex] = internal energy

q = heat

w = work done

As we know that, the term internal energy is the depend on the temperature and the process is isothermal that means at constant temperature.

So, at constant temperature the internal energy is equal to zero.

[tex]q=-w[/tex]

Thus, w = -q = 9340 J

The expression used for work done will be,

[tex]w=nRT\ln (\frac{V_2}{V_1})[/tex]

where,

w = work done = 9340 J

n = number of moles of gas  = 3 mole

R = gas constant = 8.314 J/mole K

T = temperature of gas  = ?

[tex]V_1[/tex] = initial volume of gas

[tex]V_2[/tex] = final volume of gas

Now put all the given values in the above formula, we get the temperature of the gas.

[tex]9340J=3mole\times 8.314J/moleK\times T\times \ln (\frac{261.6\times 10^{-6}m^3}{138.2\times 10^{-6}m^3})[/tex]

[tex]T=586.83K[/tex]

Now we have to calculate the final pressure of the gas by using ideal gas equation.

[tex]PV=nRT[/tex]

where,

P = final pressure of gas = ?

V = final volume of gas = [tex]138.2\times 10^{-6}m^3=138.2\times 10^{-9}L[/tex]

T = temperature of gas = 586.83 K

n = number of moles of gas = 3 mole

R = gas constant = 0.0821 L.atm/mole.K

Now put all the given values in the ideal gas equation, we get:

[tex]P\times (138.2\times 10^{-9}L)=3mole\times (0.0821L.atm/mole.K)\times (586.83K)[/tex]

[tex]P=1.046\times 10^{9}atm[/tex]

Therefore, the temperature and the final pressure of the gas is, 586.83 K and [tex]1.046\times 10^{9}atm[/tex] respectively.

Answer : The solubility of nitrogen in water at an atmospheric pressure will be, [tex]2.5125\times 10^{-4}mole/L[/tex]

Explanation :

First we have to calculate the partial pressure of nitrogen.

Formula used :

[tex]p_{N_2}=X_{N_2}\times P_{atm}[/tex]

where,

[tex]p_{N_2}[/tex] = partial pressure of nitrogen = ?

[tex]X_{N_2}[/tex] = mole fraction of nitrogen = [tex]7.81\times 10^{-1}[/tex]

[tex]p_{atm}[/tex] = atmospheric pressure = 0.480 atm

Now put all the given values in the above formula, we get :

[tex]p_{N_2}=7.81\times 10^{-1}\times 0.480 atm[/tex]

[tex]p_{N_2}=0.375atm[/tex]

Now we have to calculate the solubility of nitrogen in water.

Formula used :

[tex]s_{N_2}=p_{N_2}\times K_H[/tex]

where,

[tex]p_{N_2}[/tex] = partial pressure of nitrogen = 0.375 atm

[tex]s_{N_2}[/tex] = solubility of nitrogen in water = ?

[tex]K_H[/tex] = Henry's constant = [tex]6.70\times 10^{-4}mole/L.atm[/tex]

Now put all the given values in the above formula, we get :

[tex]s_{N_2}=0.375atm\times 6.70\times 10^{-4}mole/L.atm[/tex]

[tex]s_{N_2}=2.5125\times 10^{-4}mole/L[/tex]

Therefore, the solubility of nitrogen in water at an atmospheric pressure will be, [tex]2.5125\times 10^{-4}mole/L[/tex]

To calculate the solubility of nitrogen in water at an atmospheric pressure of 0.480 atm, we can use Henry's Law. Multiply the mole fraction of nitrogen by the atmospheric pressure to calculate the partial pressure. Then, multiply the Henry's Law constant for nitrogen by the partial pressure to find the solubility of nitrogen in water.

To calculate the solubility of nitrogen in water at a given atmospheric pressure, we can use Henry's Law. Henry's Law states that the solubility of a gas in a liquid is directly proportional to the partial pressure of the gas above the liquid.

The equation for Henry's Law is:

C = kH × P

where C is the concentration of the gas in the liquid, kH is the Henry's Law constant, and P is the partial pressure of the gas above the liquid.

In this case, we need to use the mole fraction of nitrogen and the Henry's Law constant for nitrogen to calculate the solubility. The mole fraction of nitrogen is 7.81 x 10^-1 and the Henry's Law constant for nitrogen is 6.70 x 10^-4 mol/(L×atm).

Therefore, the solubility of nitrogen in water at an atmospheric pressure of 0.480 atm is 2.5108 x 10^-4 mol/L.

Answer:  1.  Water freezing : [tex]\Delta S[/tex] is -ve.

2. Water evaporating : [tex]\Delta S[/tex] is +ve.

3. Crystalline urea dissolving : [tex]\Delta S[/tex] is +ve.

4. Assembly of the plasma membrane from individual lipids: [tex]\Delta S[/tex] is -ve.

5.  Assembly of a protein from individual amino acids: [tex]\Delta S[/tex] is -ve.

Explanation:

Entropy is defined as the measurement of degree of randomness in a system.

It is represented by symbol S and we can only measure a change in entropy which is given by [tex]\Delta S[/tex].

If there is decrease in randomness , the sign for [tex]\Delta S[/tex] is -ve and If there is increase in randomness , the sign for [tex]\Delta S[/tex] is +ve.

1.  Water freezing: Entropy decreases as we move from liquid state to  to solid state and thus [tex]\Delta S[/tex] is -ve.

2. Water evaporating : Entropy increases as we move from liquid state to  gaseous state and thus [tex]\Delta S[/tex] is +ve.

3. Crystalline urea dissolving : The molecules convert from solid and ordered state to aqueous phase and random state. Thus the entropy increases and thus [tex]\Delta S[/tex] is +ve.

4. Assembly of the plasma membrane from individual lipids:  random lipids are associating to form a single large polymer and thus entropy decreases and thus [tex]\Delta S[/tex] is -ve.

5. Assembly of a protein from individual amino acids: random amino acids are associating to form a single large polymer and thus entropy decreases and thus [tex]\Delta S[/tex] is -ve.

Answer:

a) Increase

b) the amount of SiCl₄ will decrease.

c) K will increases.

d)  H₂O will increase.

e)  SiCl₄ will decrease

f) HCl will decrease.

g) SiO₂ will decrease

Explanation:

The equilibrium changes are explained by Le-Chatelier's Principle.

If we apply a change to an equilibrium system then it shifts to the side where the effect of stress can be released.

a) Change : Increase in pressure

Quantity : amount of water

Change: We are increasing the pressure it will decrease the volume and hence will increase the moles per unit volume. so the system will move in the direction where the number of gaseous moles are less. It will move towards reactant side. thus the amount of water will increase.

b) Change : decrease in temperature

Quantity : amount of SiCl₄

As this is an exothermic reaction, the decrease in temperature will shift the reaction towards product side and hence the amount of SiCl₄ will decrease.

c)

Change : Increase in Temperature

Quantity: Kc

The equilibrium constant will increase as it increases with temperature.

d) Change : increase in temperature

Quantity : amount of H₂O

As this is an exothermic reaction, the increase in temperature will shift the reaction towards reactant side and hence the amount of H₂O will increase.

e) Change : Add H₂O

Quantity: Amount of SiCl₄

As we are adding reactant to the equilibrium, the equilibrium will shift towards product side thus the amount of SiCl₄ will decrease

f) Change : Add SiO₂

Quantity: Amount of HCl

As we are adding product, the equilibrium will shift in reactant side and thus there will be decrease in amount of HCl.

g) Change : Add HCl

Quantity: Amount of SiO₂

As we are adding product to the equilibrium the equilibrium will shift in reactant side and thus there will be decrease in amount of SiO₂

Answer:

For a: The number of moles of oxygen gas is 0.74375 moles.

For b: The energy transferred to oxygen as heat is [tex]2.631\times 10^3[/tex]

For c: The fraction of heat used to raise the internal energy of oxygen is 0.714.

Explanation:

To calculate the number of moles, we use the equation:

[tex]\text{Number of moles}=\frac{\text{Given mass}}{\text{Molar mass}}[/tex]

Given mass of oxygen gas = 23.8 g

Molar mass of oxygen gas = 32 g/mol

Putting values in above equation, we get:

[tex]\text{Moles of oxygen gas}=\frac{23.8g}{32g/mol}=0.74375mol[/tex]

Hence, the number of moles of oxygen gas is 0.74375 moles.

Oxygen is a diatomic gas.

To calculate the amount of heat transferred, we use the equation:

[tex]Q=nC_p\Delta T[/tex]

where,

Q = heat absorbed or released

n = number of moles of oxygen gas = 0.74375 moles

[tex]C_p[/tex] = specific heat capacity at constant pressure = [tex]\frac{7}{2}R[/tex]    (For diatomic gas)

R = gas constant = 8.314 J/mol K

[tex]\Delta T[/tex] = change in temperature = [tex](149-27.4)^oC=121.6^oC=121.6K[/tex]

Putting values in above equation, we get:

[tex]Q=0.74375mol\times (\frac{7}{2})\times 8.314J/mol.K\times 121.6K\\\\Q=2631.71J=2.631\times 10^3J[/tex]

Hence, the energy transferred to oxygen as heat is [tex]2.631\times 10^3[/tex]

To calculate the fraction of heat, we use the equation:

[tex]f=\frac{U}{Q}[/tex]

where,

U = internal energy = [tex]nC_v\Delta T[/tex]

Calculating the value of U:

n = number of moles of oxygen gas = 0.74375 moles

[tex]C_v[/tex] = specific heat capacity at constant pressure = [tex]\frac{5}{2}R[/tex]    (For diatomic gas)

R = gas constant = 8.314 J/mol K

[tex]\Delta T[/tex] = change in temperature = [tex](149-27.4)^oC=121.6^oC=121.6K[/tex]

Putting values in above equation, we get:

[tex]U=0.74375mol\times (\frac{5}{2})\times 8.314J/mol.K\times 121.6K\\\\U=1879.79J=1.879\times 10^3J[/tex]

Taking the ratio of 'U' and 'Q', we get:

[tex]f=\frac{1.879\times 10^3}{2.631\times 10^3}\\\\f=0.714[/tex]

Hence, the fraction of heat used to raise the internal energy of oxygen is 0.714.

Answer:The metal complex formed would have the following formula [Cr(NO₂)₆]³⁻. The complex has a net negative charge and hence it can only be isolated as a salt with a positive cation so the formed complex could be isolated as potassium salt. The formula for salt would be K₃[Cr(NO₂)₆].

Explanation:

The metal ion given to us is Cr³⁺ (Chromium) in +3 oxidation state.

The electronic configuration for the metal ion is  [Ar]3d³ so there are vacant 3d metal orbitals  which are available and hence 6 NO₂⁻ ligands can easily attack the metal center and form a metal complex.

The charge on the overall complex can be calculated using the oxidation states of metal and ligand which is provided.  

The (chromium ) Cr³⁺ metal has +3 charge and 6 NO₂⁻ (nitro) ligands have -6 charge and since  the ligands will be  providing a total of 6 - (negative) charge  and hence only 3- (negative ) charge can be neutralized so a net 3- negative charge would be present on the overall complex which is basically present at the metal center :

charge on the complex=+3-6=-3

Let X be the Oxidation state of Cr in complex =[Cr(NO₂)₆]³⁻

                                                          X-6=-3

                                                           X=-3+6

                                                            X=+3

so our calculated oxidation state of Cr is +3 which matches with the provided in question.

As we can see that the overall metal complex has a net negative charge and hence and only positively charged  cations can form a salt with this metal complex and hence only potassium K⁺ ions can form salt with the metal complex.

since overall charge present on the metal complex is -3 so 3 K⁺ ion would be needed to neutralize it and hence the formula of the metal salt would be K₃[Cr(NO₂)₆].

Hey there!:

To find the original sample population density, divide the conted colonies by the dilution factor and the inoculate:

= 73 / (10⁻⁴ * 0.1)

= 73*10⁵

Thus, the original sample's population density was 7.3*10⁶ or 73* 10⁵.

Hope this helps!

The population density of the original sample will be 73 × [tex]10^{5}[/tex] .

Population density would be a quantity of the type integer density; it would be a measuring of the population per unit area, even particularly per unit volume.

Calculation of population density

It is given that, counted colonies = 73

The dilution factor = 0.1 × [tex]10^{-4}[/tex]

population density = counted colonies / dilution factor = 73 /  0.1 × [tex]10^{-4}[/tex].

= 73 × [tex]10^{5}[/tex] .

Therefore, the population density will be 73 × [tex]10^{5}[/tex] .

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Answer : The correct option is, (A) [tex][H_3O^+]=[OH^-][/tex] because one of each is produced every time an [tex][H^+][/tex] transfers from one water molecule to another.

Explanation :

As we know that, when the two water molecule combine to produced hydronium ion and hydroxide ion.

The balanced reaction will be:

[tex]HOH+HOH\rightarrow H_3O^++OH^-[/tex]

Acid : It is a substance that donates hydrogen ion when dissolved in water.

Base : It is a substance that accepts hydrogen ion when dissolved in water.

From this we conclude that, the hydrogen ion are transferred from one water molecule to the another water molecule to form hydronium ion and hydroxide ion. In this reaction, one water molecule will act as a base and another water molecule will act as an acid.

Hence, the correct option is, (A)

In pure water, the concentrations of [H3O+] and [OH−] are equal because water undergoes self-ionization. The process results in equal formation of [H3O+] and [OH−] ions for every one water molecule that donates a proton.

In pure water, the concentrations of hydronium ions [H3O+] and hydroxide ions [OH−] are equal because water undergoes a process called self-ionization or auto-ionization. In this process, one water molecule donates a proton (H+) to another water molecule, forming a hydronium ion [H3O+] and a hydroxide ion [OH−]. Therefore, for every hydronium ion formed, there is a hydroxide ion formed as well, leading to equal concentrations of [H3O+] and [OH−] in pure water. This is represented by the equation 2H2O(l) ⇌ H3O+(aq) + OH−(aq).

This does not mean that all solutions should contain equal concentrations of acidic and basic particles, nor does it imply that [H3O+] and [OH−] form a conjugate acid-base pair. Additionally, although water is an amphoteric substance (meaning it can act as both an acid and a base), that is not why the concentrations of [H3O+] and [OH−] are equal in pure water.

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Answer : The volume of the sample after the reaction takes place is, 15.93 liters.

Explanation : Given,

Moles of [tex]N_2[/tex] = 0.13 mole

Moles of [tex]O_2[/tex] = 0.26 mole

Initial volume of gas = 23.9 L

First we have to calculate the moles of [tex]NO_2[/tex] gas.

The balanced chemical reaction is :

[tex]N_2(g)+2O_2(g)\rightarrow 2NO_2(g)[/tex]

From the balanced reaction, we conclude that

As, 1 mole of [tex]N_2[/tex] react with 2 moles of [tex]O_2[/tex] to give 2 moles of [tex]NO_2[/tex].

So, 0.13 mole of [tex]N_2[/tex] react with [tex]2\times 0.13=0.26[/tex] moles of [tex]O_2[/tex] to give [tex]2\times 0.13=0.26[/tex] moles of [tex]NO_2[/tex].

According to the Avogadro's Law, the volume of the gas is directly proportional to the number of moles of the gas at constant pressure and temperature.

[tex]V\propto n[/tex]

or,

[tex]\frac{V_1}{V_2}=\frac{n_1}{n_2}[/tex]

where,

[tex]V_1[/tex] = initial volume of gas = 23.9 L

[tex]V_2[/tex] = final volume of gas = ?

[tex]n_1[/tex] = initial moles of gas = 0.13 + 0.26 = 0.39 mole

[tex]n_2[/tex] = final moles of gas = 0.26 mole

Now put all the given values in the above formula, we get the final temperature of the gas.

[tex]\frac{23.9L}{V_2}=\frac{0.39mole}{0.26mole}[/tex]

[tex]V_2=15.93L[/tex]

Therefore, the volume of the sample after the reaction takes place is, 15.93 liters.

Answer:

False, we cannot made 16 muffins from 3 eggs.

Explanation:

2 cups flour + 1 egg + 3 oz blueberries → 4 muffins

According top recipe, 2 cups of flour, 1 egg and 3 oz of blueberries are made into batter to give 4 muffins.

Then 16 muffins will made from:

For each muffin we need =[tex]\frac{1}{4} egg[/tex]

Then for 16 muffins we will need:

[tex]\frac{1}{4}\times 14 eggs=4 eggs[/tex]

4 eggs will be required to make 16 muffins

From 1 egg we can made 4 muffins

Then from 3 eggs we can made = 3 × 4 muffins = 12 muffins

12 muffins will made from 3 eggs.

We cannot make 16  muffins from 3 eggs.

Answer:  [tex]0.98\times 10^{-7}m[/tex]

Explanation:

For calculating wavelength, when the electron will jump from n=4 to n= 1

Using Rydberg's Equation: for hydrogen atom

[tex]\frac{1}{\lambda}=R_H\left(\frac{1}{n_i^2}-\frac{1}{n_f^2} \right )\times Z^2[/tex]

Where,

[tex]\lambda[/tex] = Wavelength of radiation  = ?

[tex]R_H[/tex] = Rydberg's Constant  = [tex]1.097\times 1067m[/tex]

[tex]n_f[/tex] = Higher energy level = 4

[tex]n_i[/tex]= Lower energy level = 1

Z= atomic number = 1  (for hydrogen)

Putting the values, in above equation, we get

[tex]\frac{1}{\lambda}=1.097\times 10^7\left(\frac{1}{1^2}-\frac{1}{4^2} \right )\times 1^2[/tex]

[tex]\lambda=0.98\times 10^{-7}m[/tex]

Thus the wavelength of the photon emitted will be [tex]0.98\times 10^{-7}m[/tex]

Answer:The options b, c and d are True.

Explanation:

The above reaction is an example of electrophilic addition to alkenes and is  a typical reaction known as Markownikoffs addition reaction.

In the above reaction we are using Hydrogen chloride as an acid and as HCl is  a strong acid so it will provide acidic protons.

The acidic protons (H⁺) acts as electrophile and the the pi-bond in 3-methyl-1-hexene has sufficient electron density to attack the electrophilic protons. As a result of the attack hydrogen is added on one of the carbon atoms across the pi bond and a generation of carbocation takes place.

Once the carboation is formed then it rearranges into a more stable carbocation if it can and hence a stable carbocation is generated. The chloride anion can attack this stable carbocation leading to a regio-selective product.

The carbocation formed is the reaction intermediate in this case.

The statement (a) is incorrect as the above reaction involves carbocation as intermediate  and as carbocation is a planar molecule so there are two faces available for the chloride ion to attack  hence a racemic product would be formed resulting from the attack on both the sides. So the re action is not stereoselective  as not a specific isomer is formed.

The statement (b) is correct as the intermediate formed in the reaction is a carbocation.

The statement (c) is correct as carbocation is formed and we know that carbocations undergo rearrangements to form more stable carbocations so 1,2 shifts can occur in the reaction. As 1,2 shift is a way through rearrangements can occur in carbocation.

The statement (d) is correct as the reaction would lead to formation of  a stable carbocation and hence the chloride ion will only attack the stable carbocation so the reaction would be regioselective in nature.

Answer: 2.7 grams

Explanation:

According to the law of conservation of mass, mass can neither be created nor be destroyed. Thus the mass of products has to be equal to the mass of reactants. The number of atoms of each element has to be same on reactant and product side. Thus chemical equations are balanced.

[tex]NaHCO_3(aq)+CH_3COOH(aq)\rightarrow CH_3COONa(aq)+H_2O(l)+CO_2(g)[/tex]

Given: mass of sodium hydrogen carbonate = 3.4 g

mass of acetic acid = 10.9 g

Mass of reactants = mass  of sodium hydrogen carbonate+ mass of acetic acid = 3.4 + 10.9= 14.3 g

Mass of reactants = Mass of products in reaction vessel + mass of carbon dioxide (as it escapes)

Mass of  carbon dioxide = 14.3 - 11.6 =2.7 g

Thus the mass of carbon dioxide released during the reaction is 2.7 grams.

Answer:

The pH of the solution is 12.31 .

Explanation:

Initial molarity of barium hydroxide =[tex]M_1=6.5\times 10^{-2}M[/tex]

Initial volume of barium hydroxide =[tex]V_1=43.5 mL[/tex]

Final molarity of barium hydroxide =[tex]M_2[/tex]

Final volume of barium hydroxide =[tex]V_2=270.5 mL[/tex]

[tex]M_1V_1=M_2V_2[/tex]

[tex]M_2=\frac{6.5\times 10^{-2}M\times 43.5 mL}{270.5 mL}[/tex]

[tex]M_2=0.0104 M[/tex]

[tex]Ba(OH)_2\rightarrow Ba^{2+}+2OH^-[/tex]

1 mol of barium gives 2 mol of hydroxide ions.

Then 0.0104 M of barium hydroxide will give:

[tex]2\times 0.0104 M=0.0208 M[/tex] of hydroxide ions

[tex][OH^-]=0.0208 M[/tex]

[tex]pH=14-pOH=14-(-\log[OH^-])[/tex]

[tex]pH=14-(-\log[0.0208 M])=12.31[/tex]

The pH of the solution is 12.31 .

Answer:

127.28 mmHg

Explanation:

The molar fraction of oxygen in dry air at 760 mmHg is 20.9%. This molar fraction is not affected too much by the height, so it may be taken as a constant. The partial pressure of oxygen may be calculated as:

[tex]P_{O_{2}}=y_{O_{2}}*P[/tex]

So, if the total pressure is 609 mmHg,

[tex]P_{O_{2}}=0.209*609=127.28[/tex] mmHg.

Answer : The number of faradays of electricity had to pass through the solution will be, 0.596 F

Explanation :

First we have to calculate the moles of oxygen gas.

using ideal gas equation:

[tex]PV=nRT[/tex]

where,

P = pressure of gas = 755 mm Hg = 0.99 atm

conversion used : (1 atm = 760 mmHg)

V = volume of gas = 3.696 L

T = temperature of gas = [tex]25^oC=273+25=298K[/tex]

n = number of moles of gas = ?

R = gas constant = 0.0821 L.atm/mole.K

Now put all the given values in the ideal gas equation, we get the number of moles of oxygen gas.

[tex](0.99atm)\times (3.696L)=n\times (0.0821L.atm/mole.K)\times (298K)[/tex]

[tex]n=0.149mole[/tex]

Now we have to calculate the number of faradays of electricity had to pass through the solution.

The balanced half-reactions for the electrolysis of water is,

[tex]2H_2O(l)\rightarrow O_2(g)+4H^+(aq)+4e^-[/tex]

From this we conclude that,

As, 1 mole of oxygen gas require 4 mole of electrons that means 4 F (faraday) of electricity.

So, 0.149 mole of oxygen gas require [tex]0.149\times 4=0.596F[/tex] of electricity.

Therefore, the number of faradays of electricity had to pass through the solution will be, 0.596 F

Answer:

0.001341 mol/L s is the average rate from 8.0 to 20.0 seconds.

Explanation:

[tex]2 AX_2(g)\rightarrow 2 AX(g) + X_2(g)[/tex]

Average rate of the reaction =[tex]R_a[/tex]

[tex]R_a=-\frac{\Delta [x]}{\Delta T}=-\frac{x_2-x_1}{t_2-t_1}[/tex]

[tex]R_a[/tex] =Average rate of the reaction during the given time interval.

[tex]\Delta [x][/tex] = Change in concentration of reactant with respect to time.

[tex]\Delta T[/tex] = Change in time.

[tex]x_1[/tex]=Concentration of reactant at time[tex]t_1[/tex]

[tex]x_2[/tex]=Concentration of reactant at time[tex]t_2[/tex]

So, at [tex]t_1=8.0 sec[/tex] the concentration of [tex]AX_2[/tex] :

[tex]x_1=0.0249 mol/L[/tex]

And at [tex]t_2=2.0 sec[/tex] the concentration of [tex]AX_2[/tex] :

[tex]x_2=0.0088 mol/L[/tex]

The average rate of the reaction at given interval will be given as:

[tex]R_a=-\frac{x_2-x_1}{t_2-t_1}=-\frac{0.0088 mol/L-0.0249mol/L}{20.0s-8.0 s}=0.001341 mol/L s[/tex]

0.001341 mol/L s is the average rate from 8.0 to 20.0 seconds.

Answer: sodium amide undergoes an acid -base reaction

Explanation:

sodium amide is a ionic compound and basically exists as sodium cation and amide anion. Amide anion is highly basic in nature and hence as soon as  there is amide anion generated in the solution , Due to its very pronounced acidity it very quickly abstracts the slightly acidic proton available on methanol.

This leads to formation of ammonia and sodium methoxide.

Hence sodium amide reacts with methanol and abstracts its only acidic proton and form ammonia and sodium Methoxide.

Hence the 3rd statement is a corrects statement.

So we cannot use methanol for sodium amide because sodium amide itself would react with methanol and the inherent molecular natur of sodium amide would then change.

The 1st and 2nd statements both are incorrect because both the compounds methanol as well as sodium amide have dipole moments and hence are polar molecules.

The 4th statement is also incorrect as both the molecules have dipole moment and hence there would be ion-dipole forces operating between them.

The following reaction occurs:

NaNH₂+CH₃OH→NH₃+CH₃ONa

Sodium amide undergoes an acid -base reaction

Methanol is acidic in nature whereas sodium amide is a strong base so when we add or combine these two chemicals, they undergoes an acid -base reaction so that's why we can't use methanol as a solvent for sodium amide.

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Answer:

trans-4-tert-butyl-1-phenylcyclohexanol  

Explanation:

The bulky tert-butyl group will occupy the equatorial position in the cyclohexanone ring.

It will hinder approach of the Grignard reagent from the bottom side of the molecule.

The reagent will attack from the top, so the product alcohol will be

trans-4-tert-butyl-1-phenylcyclohexanol.