One possible mechanism for the gas phase reaction of hydrogen with nitrogen monoxide is: step 1: H2(g) + 2 NO (g) → N2O (g) + H2O (g) step 2: N2O (g) + H2 (g) → N2 (g) + H2O (g) Identify the molecularity of each step in the mechanism. (1, 2, or 3) Step 1 _______ Step 2 ________

Answer: The energy of combustion of butter is 31.5 kJ/g

Explanation:

The quantity of heat required to raise the temperature of a substance by one degree Celsius is called the specific heat capacity.

[tex]Q=C\times \Delta T[/tex]

Q = Heat absorbed by calorimeter =?

C = heat capacity of calorimeter = [tex]2.67kJ/^0C[/tex]

Initial temperature of the calorimeter  = [tex]T_i[/tex] = [tex]23.5^0C[/tex]

Final temperature of the calorimeter  = [tex]T_f[/tex]  = [tex]26.1^0C[/tex]

Change in temperature ,[tex]\Delta T=T_f-T_i=(26.1-23.5)^0C=2.6^0C[/tex]

Putting in the values, we get:

[tex]Q=2.67kJ/^0C\times 2.6^0C=6.94kJ[/tex]

As heat absorbed by calorimeter is equal to heat released by combustion of butter

[tex]Q=q[/tex]

Heat released by 0.22 g of butter = 6.94 kJ

Heat released by 1g of butter = [tex]\frac{6.94}{0.22}\times 1=31.5kJ[/tex]

The energy of combustion of butter is 31.5 kJ/g

To find the energy of combustion per gram of butter, you first compute the total energy using the formula q = C*deltaT, and then divide this total energy by the mass of the butter. The calculated energy of combustion per gram of butter in this case is 31.55 kJ/g.

The energy of combustion per gram of butter is calculated by first finding the total energy produced, which is done using the formula: q = C*deltaT where q is the heat energy, C is the heat capacity, and deltaT is the change in temperature. Therefore, q = (2.67 kJ/°C) * (26.1°C - 23.5°C) = 6.94kJ

To find the energy of combustion per gram, you divide the total energy by the mass of the butter. So, Energy of combustion per gram = 6.94 kJ / 0.22 g = 31.55 kJ/g.

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Answer:

33g of CO2

Explanation:

Step 1:

The balanced equation for the reaction.

CH4 + 2O2 —> CO2 + 2H2O

Step 2:

Determination of the masses of CH4 and O2 that reacted and the mass of CO2 produced from the balanced equation.

This is illustrated below:

Molar Mass of CH4 = 12 + (4x1) = 16g/mol

Molar Mass of O2 = 16x2 = 32g/mol

Mass of O2 from the balanced equation = 2 x 32 = 64g

Molar Mass of CO2 = 12 + (2x16) = 44g/mol.

Summary:

From the balanced equation above,

16g of CH4 reacted with 64g of O2 to produce 44g of CO2.

Step 3:

Determination of limiting reactant. This is illustrated below:

From the balanced equation above,

16g of CH4 reacted with 64g of O2.

Therefore, 12g of CH4 will react with = (12 x 64)/16 = 48g of O2.

From the above illustration, a lesser mass of O2 i.e 48g than what was given i.e 133g is required to react completely with 12g of CH4.

Therefore, CH4 is the limiting reactant and O2 is the excess reactant.

Step 4:

Determination of the mass of CO2 produced from the reaction.

Here, we shall use the limiting reactant, because it will give the maximum yield of CO2 as all of it is used up in reaction.

This is illustrated as follow:

From the balanced equation above,

16g of CH4 reacted to produce 44g of CO2.

Therefore, 12g of CH4 will react to produce = (12 x 44)/16 = 33g of CO2.

From the calculations made above, 33g of CO2 will be produced from the reaction of 12g of CH4 and 133g of O2.

The bonding in BeF2 involves the promotion of a 2s electron to a 2p orbital on Be, followed by sp hybridization of the Be orbitals, and overlap with the F atom 2p orbitals to form two sigma bonds. So the correct statements are iv, iii, and i.

To explain the bonding in BeF2, we must select the appropriate statements and arrange them in a logical order. The correct sequence of statements is:

Firstly, a 2s electron in Be is promoted to a 2p orbital (Statement iv), creating two singly occupied orbitals. These orbitals then undergo hybridization to form two equivalent sp hybrid orbitals (Statement iii), which are oriented at a 180° angle to each other. Each sp hybrid orbital overlaps with a singly occupied 2p orbital on a fluorine atom to form a sigma bond (Statement i), involving the pairing up of the Be valence electrons with the unpaired electron on each F atom. This results in the formation of two identical Be-F sigma bonds, giving BeF2 a linear molecular geometry.

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Answer:

SrS<CaO<MgO

Explanation:

Lattice energy is defined as a measure of the energy contained in the crystal lattice of a compound. It can be seen as the energy that would be released if the component ions were brought together from infinity.

Lattice energy depends on size of the ions. The smaller the ions, the greater the lattice energy. When we look at all the actions in the substances listed, we will notice that the order of decrease in cation size is Sr^2+>Ca^2+>Mg^2+. The lattice energy increases in the this order.

Hence MgO will have the greatest lattice energy of all the species listed.

The order of increasing magnitude of lattice energy is; SrS < CaO < MgO

Definition:

Lattice energy is simply defined as the energy required to convert one mole of an ionic solid into gaseous ionic constituents.

Lattice energy is dependent on the size of the constituent atoms.

The greater the distance between the nucleus of the constituent atoms, the lesser is the lattice energy.

Therefore, the order of increasing magnitude of lattice energy is;

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(a) The melting point of S-hydroxybenzoic should be 140°C.

(b) The Racemic mixture must have a diverse melting point in comparison to the pure enantiomers.

(a) When The melting point of S, S-hydroxybenzoic should be 140°C. Since S, S-hydrozoan, and also R, R-hydroxybenzoic is enantiomeric pair their melting point and then boiling point should be the same.

(b) The different melting points,

When The racemic mixture must have a different melting point in comparison to the pure enantiomers.

considering a racemic mixture, a particular enantiomer possesses a greater affinity for its variety of molecules than for those of the different enantiomer

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Final answer:

The pure S,S-hydrobenzoin is expected to have a melting point similar to the R,R-hydrobenzoin at 148°C. Racemic mixtures containing both enantiomers typically have different and lower melting points compared to the pure enantiomers because they disrupt the crystal lattice.

Explanation:

Enantiomers and Melting Points

The melting point of the pure R,R-hydrobenzoin is 148°C. For the pure S,S-hydrobenzoin, which is the enantiomer of R,R-hydrobenzoin, we would expect the melting point to be very similar, if not identical, because enantiomers typically have the same physical properties including melting points.

Racemic Mixtures and Melting Points

When it comes to racemic mixtures, which contain equal amounts of both enantiomers, they often have melting points that are different, and usually lower, than those of the pure enantiomers. This is because the presence of both enantiomers in a racemic mixture can disrupt the crystal lattice, leading to a less orderly structure that requires less energy (heat) to disrupt.

Answer:

120g

Explanation:

We'll begin by writing the balanced equation for the reaction. This is given below:

Sn + 2HF —> SnF2 + H2

Next, we shall determine the number of mole of HF needed to react with 3 moles of Sn.

From the balanced equation above, 1 mole of Sn reacted with 2 moles of HF.

Therefore, 3 moles of Sn will react with = 3 x 2 = 6 moles of HF.

Finally, we shall convert 6moles of HF to grams

This is illustrated below:

Number of mole of HF = 6moles

Molar Mass of HF = 1 + 19 = 20g/mol

Mass of HF =..?

Mass = number of mole x molar Mass

Mass of HF = 6 x 20

Mass of HF = 120g

Therefore, 120g of HF is needed to react with 3 moles of Sn

Answer:

Fe(OH)2

Explanation:

Iron hydroxides are chemical compounds that appear as precipitates after alkalizing solutions containing iron salts, both in their valence or degree of oxidation (III) and (II).

Hydroxide, in both cases, is a gelatinous colloid of difficult filtration that can be considered a hydrated oxide, iron (II) hydroxide is whitish in color and requires more alkalinization, above 7.

Answer:

See explaination

Explanation:

Please kindly check out the attached files for the curved-arrow mechanism for the Claisen condensation of ethyl ethanoate treated with ethoxide ion.

The Claisen condensation of ethyl ethanoate with ethoxide ion involves the formation of a β-keto ester. The reaction proceeds through a step-by-step mechanism, where the ethoxide ion acts as a strong base and abstracts a proton from the α-carbon of ethyl ethanoate, leading to the formation of an enolate ion. The enolate ion then attacks the carbonyl carbon of another molecule of ethyl ethanoate, resulting in the formation of a β-keto ester.

The Claisen condensation is a reaction that involves the combination of two ester molecules in the presence of a strong base, resulting in the formation of a β-keto ester. In this specific case, the Claisen condensation involves the reaction of ethyl ethanoate (ester) with ethoxide ion (strong base). Let's go through the step-by-step mechanism of the reaction:

It is important to note that in both steps, the species involved in the reaction are the ethoxide ion and the ethyl ethanoate molecules. The formal charges and nonbonding electrons can be indicated on the atoms involved. Also, it is mentioned to omit ethanol byproducts from the drawings.

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Answer:

(1) HI is Bronsted-Lowry acid and [tex]H_{2}O[/tex] is Bronsted-Lowry base.

(2) [tex]H_{2}O[/tex] is Bronsted-Lowry acid and [tex]F^{-}[/tex] is Bronsted-Lowry base.

Explanation:

A Bronsted-Lowry acid is a species which donates proton ([tex]H^{+}[/tex]).

A Bronsted-Lowry base is a species which accepts proton ([tex]H^{+}[/tex]).

(1) [tex]HI(aq)+H_{2}O(l)\rightarrow I^{-}(aq)+H_{3}O^{+}(aq)[/tex]

Reactants: HI and [tex]H_{2}O[/tex]

Here HI donates proton and [tex]H_{2}O[/tex] accepts proton.

Hence HI is Bronsted-Lowry acid and [tex]H_{2}O[/tex] is Bronsted-Lowry base.

(2) [tex]F^{-}(aq)+H_{2}O(l)\rightleftharpoons HF(aq)+OH^{-}(aq)[/tex]

Reactants: [tex]F^{-}[/tex] and [tex]H_{2}O[/tex]

Here [tex]H_{2}O[/tex] donates proton and [tex]F^{-}[/tex] accepts proton.

Hence [tex]H_{2}O[/tex] is Bronsted-Lowry acid and [tex]F^{-}[/tex] is Bronsted-Lowry base.

Let's consider Brønsted−Lowry acid-base theory:

We have 4 equations and we want to identify which reactant is the acid or the base.

The substance(s) to the left of the arrow in a chemical equation are called reactants.

HI(aq) + H₂O(l) → I⁻(aq) + H₃O⁺(aq)

HI donates H⁺ to H₂O, so it is an acid.

HI(aq) + H₂O(l) → I−(aq) + H₃O⁺(aq)

H₂O accepts H⁺ from HI, so it is a base.

F⁻(aq) + H₂O(l) ⇌ HF(aq) + OH⁻(aq)

H₂O donates H⁺ to F⁻, so it is an acid.

F⁻(aq) + H₂O(l) ⇌ HF(aq) + OH⁻(aq)

F⁻ accepts H⁺ from H₂O, so it is a base.

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Answer:

0.3M

Explanation:

Step 1:

Data obtained from the question. This include the followingb:

Volume of acid (Va) = 90mL

Concentration of acid (Ca) = 0.2M

Volume of base (Vb) = 60mL

Concentration of base (Cb) =....?

Step 2:

The balanced equation for the reaction. This is given below:

HBr + NaOH —> NaBr + H2O

From the balanced equation above,

The mole ratio of the acid (nA) = 1

The mole ratio of the base (nB) = 1

Step 3:

Determination of the concentration of the base, NaOH.

The concentration of the base can be obtained as follow:

CaVa /CbVb = nA/nB

0.2 x 90 / Cb x 60 = 1

Cross multiply

Cb x 60 = 0.2 x 90

Divide both side by 60

Cb = 0.2 x 90 /60

Cb = 0.3M

Therefore, the concentration of the base, NaOH is 0.3M

Answer:

[tex]M_{NaOH}=0.3M[/tex]

Explanation:

Hello,

In this case, since we are talking about a neutralization reaction, the moles of acid must equal the moles of base as shown below:

[tex]n_{HBr}=n_{NaOH}[/tex]

Thus, in terms of molarities we've got:

[tex]M_{HBr}V_{HBr}=M_{NaOH}V_{NaOH}[/tex]

This is possible since HBr reacts with NaOH in a 1:1 molar ratio:

[tex]HBr+NaOH\rightarrow NaBr+H_2O[/tex]

Hence, for the given concentration and volume of hydrobromic acid and the volume of sodium hydroxide, we compute its concentration as shown below:

[tex]M_{NaOH}=\frac{M_{HBr}V_{HBr}}{V_{NaOH}} =\frac{90mL*0.2M}{60mL} \\\\M_{NaOH}=0.3M[/tex]

Best regards.

Answer:

Check the explanation

Explanation:

Kindly check the attached image below to see the step by step explanation to the question above.

To find the time it would take for 85.2% of the dimethyl ether to decompose in a first order reaction with a rate constant of 4.00e-4 s-1, we use the first order reaction equation. Substituting the known values, we solve for the time to be approximately 4142 seconds.

The question asks for the time required to decompose 85.2% of an initial amount of dimethyl ether. This is a first order reaction with the rate constant provided as 4.00e-4 s-1.

In first order reactions, we can use the following equation to determine the time:

t = -1/k × ln([A]t/[A]0)

where:

Since we’re looking for the time it takes for 85.2% of the substance to decompose, [A]t is 100% - 85.2% = 14.8% = 0.148 [A]0. Substituting the known values, we get:

t = -1/(4.00e-4 s-1) × ln(0.148) ≈ 4142 seconds

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Answer:

F2(g)/HF(aq)>Co3 (aq)/Co2 (aq)> H2O2(aq)/H2O(l)> PbO2(s)/Pb(s)>Br2(l)/Br-(aq)

Explanation:

The tendency of any specie to function as oxidizing agent is a highly dependent on the reduction potential of the couple. The more positive the value of the reduction potential of the couple, the better it does as an oxidizing agent.

This implies that we could know a good oxidizing agent by looking at their respective reduction potentials. The couple having the greatest (most positive) reduction potential is selected as the best oxidizing agent. If there are a number of couples at having different reduction potentials, the order of oxidizing ability can be obtained by arranging the species in order of decreasing positive reduction potentials just as we have done in the answer above.

Decreasing strength will be:

F₂(g)/HF(aq)>Co₃ (aq)/Co₂ (aq)> H₂O₂(aq)/H₂O(l)>PbO₂(s)/Pb(s)>Br₂(l)/Br-(aq)

The tendency of any specie to function as an oxidizing agent is highly dependent on the reduction potential of the couple. The more positive the value of the reduction potential of the couple, the better it does as an oxidizing agent.

The couple having the greatest (most positive) reduction potential is selected as the best oxidizing agent.

Thus, the decreasing strength for oxidizing agents will be:

F₂(g)/HF(aq)>Co₃ (aq)/Co₂ (aq)> H₂O₂(aq)/H₂O(l)>PbO₂(s)/Pb(s)>Br₂(l)/Br-(aq)

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Answer:

3.25

Explanation:

pH = -log[H3O+]

-log(0.000558)=3.25

Answer:

C. Al2O3

Explanation:

The empirical formula is an expression that represents the simplest proportion in which the atoms that form a chemical compound are present. It is therefore the simplest representation of a compound.

For options A, B and D the empirical formulas are as follows:

A. CH2

B. BH3

D. CH

To find the amount of methanol required to generate 665 kJ of heat, calculate the heat produced per gram of methanol burned. The balanced equation helps determine the amount needed. In this case, burning 27.9 grams of methanol will produce 665 kJ of heat.

To calculate the amount of methanol needed to produce 665 kJ of heat, we first need to determine the amount of heat produced per gram of methanol burned. From the balanced equation CH₃OH(g) + 3/2O₂(g) ⟶ CO₂(g) + 2HO(l), we see that 764 kJ of heat is released per 1 mol of methanol burned. This corresponds to 32 g of methanol. Therefore, to produce 665 kJ of heat, we would need to burn:

(665 kJ) * (32 g / 764 kJ) = 27.9 g of methanol.

So, 27.9 grams of methanol must be burned to produce 665 kJ of heat.

Answer:

5.74g of NO

Explanation:

Step 1:

The balanced equation for the reaction. This is given below:

4NH3 + 5O2 —> 4NO + 6H2O

Step 2:

Determination of the masses of NH3 and O2 that reacted and the mass of NO produced from the balanced equation. This is illustrated below:

Molar Mass of NH3 = 14 + (3x1) = 14 + 3 = 17g/mol

Mass of NH3 from the balanced equation = 4 x 17 = 68g

Molar Mass of O2 = 16x2 = 32g/mol

Mass of O2 from the balanced equation = 5 x 32 = 160g

Molar Mass of NO = 14 + 16 = 30g/mol

Mass of NO from the balanced equation = 4 x 30 = 120g

From the balanced equation above,

68g of NH3 reacted with 160g of O2 to produce 120g of NO.

Step 3:

Determination of the limiting reactant.

We need to determine the limiting because it will be used to calculate the maximum yield of the reaction. This is illustrated below:

From the balanced equation above,

68g of NH3 reacted with 160g of O2.

Therefore, 3.25g of NH3 will react with = (3.25 x 160)/68 = 7.65g of O2.

From the simple illustration above, we can see that lesser mass of O2 is needed to react with 3.25g of NH3. Therefore, NH3 is the limiting reactant while O2 is the excess reactant.

Step 4:

Determination of the mass of NO produced from the reaction.

In this case the limiting reactant will be used because all of it were used in the reaction.

The limiting reactant is NH3.

From the balanced equation above,

68g of NH3 reacted to produce 120g of NO.

Therefore, 3.25g of NH3 will react to produce = (3.25 x 120)/68 = 5.74g of NO.

From the calculations made above, 5.74g of NO is produced.

Answer:

Check the explanation

Explanation:

Kindly check the attached images below to see the step by step explanation to the question above.

Answer : The volume of water added are, 15 mL

Explanation :

Formula used :

[tex]M_1V_1=M_2V_2[/tex]

where,

[tex]M_1\text{ and }V_1[/tex] are the initial molarity and volume of HCl.

[tex]M_2\text{ and }V_2[/tex] are the final molarity and volume of water.

We are given:

[tex]M_1=12M\\V_1=50mL\\M_2=40M\\V_2=?[/tex]

Putting values in above equation, we get:

[tex]12M\times 50mL=40M\times V_2\\\\V_2=15mL[/tex]

Hence, the volume of water added are, 15 mL

Answer:

The ovaries and the testes

Explanation:

The organs responsible for the development of secondary sex characteristics would be the ovaries and the testes.

Both ovary and testes are associated with the sex organs in the body and are responsible for the synthesis of hormones such as androgen and estrogen. While the latter (estrogen) is produced by the ovary, the former (androgen) is produced by the testes.

More specifically, both androgen and estrogen are hormones responsible for the growth of hairs in areas such as the armpit and the pubic regions of the body.

The correct options are the ovaries and the testes.

Answer:  Cu

Explanation: It is Cu because the origin of the word Copper comes from the latin word "Cuprum".

Final answer:

Homogeneous mixtures and heterogeneous mixtures can be distinguished visually and their components can be separated by physical processes.

Explanation:

A. Their components can be distinguished visually.

C. Their components can be separated by physical processes.

Both homogeneous mixtures and heterogeneous mixtures can be distinguished visually and their components can be separated by physical processes. In a homogeneous mixture, the components are uniformly distributed and cannot be visually distinguished. Examples of homogeneous mixtures include salt dissolved in water and air. In contrast, a heterogeneous mixture has components that are not uniform and can be visually distinguished. Examples of heterogeneous mixtures include sand and water and mixed nuts. Both types of mixtures can be separated into their individual components through physical processes such as filtration or evaporation.

Answer:

Number of boxes = 4

Explanation:

Given:

Mass of one box of jello = 250 grams

Total quantity want to purchase = 1 kg = 1 × 1,000 gram = 1,000 grams

Find:

Number of boxes in 1,000 grams = ?

Computation:

Number of boxes = Total quantity want to purchase / Mass of one box of jello

Number of boxes = 1,000 / 250

Number of boxes = 4

Therefore, 4 boxes of jello must be purchase to get 1 kg of Jello.

Mirrors reflect light without separating it into colors, unlike prisms or water droplets which cause dispersion, leading to the formation of rainbows. Dispersion occurs when light passes through a medium that slows down colors differentially. Historical scientists like al-Farisi and Theodoric of Freiberg demonstrated this with water droplets.

The answer is no; a typical mirror reflects light without separating it into its constituent colors. This property allows a mirror to create an image with the same color composition as the original scene.

Now, the separation of white light into its constituent colors—an effect known as dispersion—occurs when light passes through a medium that causes different colors to travel at different speeds. This is how prisms or water droplets in the atmosphere create beautiful rainbows. It relies on the refraction of light, which bends the light as it moves from one medium to another, like air into water, and does so at varying degrees depending on the wavelength (color) of the light. However, while mirrors can exhibit total reflection due to refraction, they do not inherently disperse white light.

Historically, figures like Kamal al-Din al-Farisi and Theodoric of Freiberg conducted experiments which confirmed that water droplets are responsible for decomposing white light into the colors of the rainbow. Their work built on foundational optics principles from Ibn al-Haytham.

 Answer:

Delta H for endothermic reaction is positive-True. This is because an endothermic reaction absorbs heat energy, therefore more energy is retained inside the product of the reaction system than the reactants, as the value of deltaH is greater than Zero.

Delta H for an exothermic reaction is positive. This is false. Because in an exothermic reaction  heat is liberated to the  surrounding environment. therefore the value of thus the outer environment contains more energy than the internal environments, thus the enthalpy of the reactants is greater than that of the products.

when the energy is transferred as heat from system to surroundings, deltaH is negative. True . This is true because the surrounding environment gain heat energy, (positive)while  the system loses it,(negative) therefore delta H is negative.

when the energy is transferred as heat from surroundings to system, deltaH is negative.  False. This is  positive, because now the environments loses heat, (negative) while the systems gains heat,( positive) therefore delta H of the system is positive. endothermic

the evaporation of water is an exothermic process-False, This is an endothermic reaction in which water molecules need to gain heat energy from the surrounding environments to increase the average kinetic energy  of collusion to escape the intermolecular forces to escape as steam.

Combustion reaction is exothermic. True., because heat energy is transferred to the surrounding from the internal system. The energy needed for the formation  of  new bonds in the products is higher than the energy for breaking of original bonds in the reactants. Thus more heat is liberated.

Explanation:

Answer:

5.9x10^-2 M

Explanation:

Step 1:

Data obtained from the question. This includes the following:

Concentration of CO, [CO] = 0.30 M

Concentration of H2, [H2] = 0.10 M

Concentration of H2O, [H2O] = 0.020 M

Equilibrium constant, K = 3.90

Concentration of CH4, [CH4] =..?

Step 2:

The balanced equation for the reaction. This is given below:

CO(g) + 3H2(g) <=> CH4(g) + H2O(g)

Step 3:

Determination of the concentration of CH4.

The expression for equilibrium constant of the above equation is given below:

K = [CH4] [H2O] / [CO] [H2]^3

3.9 = [CH4] x 0.02/ 0.3 x (0.1)^3

Cross multiply to express in linear form

[CH4] x 0.02= 3.9 x 0.3 x (0.1)^3

Divide both side by 0.02

[CH4] = 3.9 x 0.3 x (0.1)^3 /0.02

[CH4] = 5.9x10^-2 M

Therefore, the equilibrium concentration of CH4 is 5.9x10^-2 M

Answer:

B

Explanation:

Answer:

See explaination

Explanation:

1) Pb(NO3)2 => Pb2+ + 2 NO3-

[Pb2+] = [Pb(NO3)2] = 7.56 mM = 7.56 x 10-3 M

Pb(IO3)2 <=> Pb2+ + 2 IO3-

Ksp = [Pb2+][IO3-]2 = 2.5 x 10-13

7.56 x 10-3 x [IO3-]2 = 2.5 x 10-13

[IO3-] = 5.75 x 10-6 M ≈ 5.8 x 10-6 M

(2) [Pb2+] = 1.7 x 10-6 M

Ksp = [Pb2+][IO3-]2 = 2.5 x 10-13

1.7 x 10-6 x [IO3-]2 = 2.5 x 10-13

[IO3-] = 3.83 x 10-4 M

[IO3-]from Pb(IO3)2 = 2 x [Pb2+]

= 2 x 1.7 x 10-6 = 3.4 x 10-6 M

[IO3-]from NaIO3 = [IO3-] - [IO3-]from Pb(IO3)2

= 3.83 x 10-4 - 3.4 x 10-6

= 3.80 x 10-4 M

NaIO3 => Na+ + IO3-

[NaIO3] = [IO3-]from NaIO3

= 3.80 x 10-4 M ≈ 3.8 x 10-4 M

Answer:

1) Concentration of IO−3 in a 1.65 mM Pb(NO3)2 solution:

[tex].[IO^{-3}]=1.228*10^{-5} M[/tex]

2) Concentration of NaIO3:

[tex].[NAIO3][/tex]=[tex]2*10^{-4} M[/tex]

Explanation:

1) Concentration of IO−3 in a 1.65 mM Pb(NO3)2 solution:

The reaction will be:

[tex]Pb(NO3)2[/tex] ⇒ [tex]Pb^{+2} +2NO^{-3}[/tex]

[tex]Concentration\ of\ Pb^{+2}=Pb(NO3)2=1.65*10^{-3}\ M[/tex]

Now,

[tex]Pb(IO3)2[/tex] ⇄ [tex]Pb^{+2}+2IO^{-3}[/tex]

Ksp=Concentration of [tex]Pb^{+2}[/tex] * (Concentration of [tex]2IO^{-3}[/tex])^2

[tex]Ksp=[Pb^{+2}][/tex]*[tex][2IO^{-3}]^2[/tex]

[tex]2.5*10^{-13}=1.65*10^{-3}*[IO^{-3}]^2\\.[IO^{-3}]^2=\frac{2.5*10^{-13}}{1.65*10^{-3}} \\.[IO^{-3}]^2=1.51*10^{-10} M\\.[IO^{-3}]=1.228*10^{-5} M[/tex]

2) Concentration of NaIO3:

Now,

[[tex]Pb^{+2}[/tex]]=[tex]5.60*10^{-6} M[/tex]

[tex]Ksp=[Pb^{+2}]*[2IO^{-3}]^2[/tex]

[tex]2.5*10^{-13}=5.60*10^{-6} *[IO^{-3}]^2\\.[IO^{-3}]^2=\frac{2.5*10^{-13}}{5.60*10^{-6}} \\.[IO^{-3}]^2=4.46*10^{-8} M\\.[IO^{-3}]=2.112*10^{-4} M[/tex]

Again:

[tex]Concentration\ of\ IO^{-3} from\ Pb(IO3)2 = 2* Concentration\ of\ Pb^{+2}\\.[IO^{-3}]_{From\ Pb(IO3)2}=2*5.60*10^{-6}\\.[IO^{-3}]_{From\ Pb(IO3)2}=1.12*10^{-5} M[/tex]

Calculating the concentration of  [tex]IO^{-3}[/tex] from NaIO3:

[tex]Concentration\ of\ IO^{-3}_{[From\ NaIO3}]=[IO^{-3}]-Concentration\ of\ IO^{-3}_{[From\ Pb(IO3)2}]\\Concentration\ of\ IO^{-3}_{[From\ NaIO3}]=2.112*10^{-4}-1.12*10^{-5}\\Concentration\ of\ IO^{-3}_{[From\ NaIO3}]=2*10^{-4} M[/tex]

Reaction:

[tex]NaIO3=>Na^{+}+IO^{-3}[/tex]

Concentation of NaIO3= Concentration of [tex]IO^{-3}[/tex]

[tex].[NAIO3][/tex]=[tex]2*10^{-4} M[/tex]

Answer:

8 : 1

Explanation:

The balanced equation for the reaction is given below:

C5H12 + 8O2 → 5CO2 + 6H2O

From the balanced equation above,

1 mole of C5H12 reacted with 8 moles of O2.

Thus the mole ratio of O2 to C5H12 is:

8 : 1

Answer: see the graphic