Which of the following pairs is mismatched? Select one: a. synthesis reaction - two reactants combine to form a larger product b. decomposition reaction - large reactant broken into smaller products c. oxidation - gain of electrons d. dehydration reaction - water is a product of the reaction e. hydrolysis - water is used in decomposition reaction

To count the number of valence electrons we look at the electronic configuration and add the electrons form the electronic shell with the highest principal quantum number.

Rb: [Kr] 5s¹ - 1 valence electron

Xe: [Kr] 5s² 4d¹⁰ 5p⁶ - 8 valence electrons

Sb: [Kr] 5s² 4d¹⁰ 5p³ - 5 valence electrons

I:    [Kr] 5s² 4d¹⁰ 5p⁵ - 7 valence electrons

In:  [Kr] 5s² 4d¹⁰ 5p¹ - 3 valence electrons

Rank from most to fewest valence electrons:

Xe > I > Sb > In > Rb

Rank from most to fewest valence electrons:

Xe > I > Sb > In > Rb. Each atom in the bond contributes one valence electron.

A valence electron is a kind of electron that is part of an atom's outer shell in chemistry and physics. If the outer shell is open, the valence electron can take part in the creation of a chemical bond, forming a shared pair within a single covalent bond.We examine the electronic configuration then add the electrons from the electronic shells with the largest main quantum number to determine the amount of valence electrons.

Rb: [Kr] 5s¹ - 1 valence electron

Xe: [Kr] 5s² 4d¹⁰ 5p⁶ - 8 valence electrons

Sb: [Kr] 5s² 4d¹⁰ 5p³ - 5 valence electrons

I:    [Kr] 5s² 4d¹⁰ 5p⁵ - 7 valence electrons

In:  [Kr] 5s² 4d¹⁰ 5p¹ - 3 valence electrons

Rank from most to fewest valence electrons:

Xe > I > Sb > In > Rb

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Final answer:

To precipitate all of the Ca2+ ions in the CaBr2 solution, we need 0.280618 mL of 0.472 M Ba(OH)2.

Explanation:

To find the number of milliliters of 0.472 M Ba(OH)2 required to precipitate all of the Ca2+ ions, we first need to determine the number of moles of Ca2+ ions in the 197 mL of 0.671 M CaBr2 solution. Using the equation CaBr2(aq) + Ba(OH)2(aq) -> Ca(OH)2(s) + BaBr2(aq), we can see that the mole ratio between Ca2+ ions and Ba(OH)2 is 1:1. So if there are x moles of Ca2+ ions, we would need x moles of Ba(OH)2. Using the formula Molarity = Moles/Volume, we can calculate the moles of Ca2+ ions:

Moles of Ca2+ ions = (0.671 M CaBr2)(197 mL) = 0.132537 mol Ca2+

Since the mole ratio is 1:1, we would need 0.132537 mol of Ba(OH)2. Using the formula Moles = Molarity x Volume, we can calculate the volume of 0.472 M Ba(OH)2:

Volume of Ba(OH)2 = (0.132537 mol)/(0.472 M) = 0.280618 mL

Answer:

The correct answer is option B.

Explanation:

Concentration of a  steady-state plasma ,= 25 mg/L

Weight of the volunteer =75 kg

Rate of infusion = 7.5 mg/kg hr

Concentration of steady-state plasma in 75 kg weight body:

[tex]7.5 mg/kg hr\times 75 kg=562.5 mg/hr[/tex]

Total body clearance of this drug:

[tex]\frac{562.5 mg/hr}{25 mg/L}=22.5 L/hr[/tex]

The total body clearance of this drug is 22.5 L/hr.

Answer:

the 4th choice.

Explanation:

the fish can't swim through the aquarium

the fish can't swim in the air

Answer:

B.Example 1 represents a liquid and example 2 represents a gas

Explanation:

Solid : It is that states of matter in which atom or molecules very close to each other. The distance between atoms or molecules is negligible. The atom or molecules can't escape out of solids.

Liquid: It is that states of matter in which atoms or molecules are close to each other but not very close as in solid.The distance between atoms or molecules is small.

Gas: It is that states of matter in which atoms or molecules are very far to each other .The distances between atoms or molecules are very large. The two two atoms can not come closer to each other at normal condition.

We are given that Zoe used two examples to represent two different states of matter

1.Example :Fish swimming around one another in an aquarium

It means fish can not escape out of aquarium. Hence, it represent the liquid states of matter.

2.Example: Fish swimming away one another in the ocean .

When fish swimming away one another ,Then they can'not come close to each other .Hence, it represents gas states of matter.

Therefore, option D is true.

Answer:Example 1 represents a solid and example 2 represents a gas

Answer: 6.7 g

Explanation:

As the relative lowering of vapor pressure is directly proportional to the amount of dissolved solute.

The formula for relative lowering of vapor pressure will be,

[tex]\frac{p^o-p_s}{p^o}=\frac{w_2M_1}{w_1M_2}[/tex]

where,

[tex]p^o[/tex] = vapor pressure of pure solvent  (water) = 55.32 mmHg

[tex]p_s[/tex] = vapor pressure of solution = 54.21 mmHg

[tex]w_2[/tex] = mass of solute  (urea) = ? g

[tex]w_1[/tex] = mass of solvent  (water) = 100 g

[tex]M_1[/tex] = molar mass of solvent (water) = 18 g/mole

[tex]M_2[/tex] = molar mass of solute (urea) = 60 g/mole

Now put all the given values in this formula ,we get the vapor pressure of the solution.

[tex]\frac{55.32-54.21}{55.32}=\frac{x\times 18}{100\times 60}[/tex]

[tex]x=6.7g[/tex]

Therefore, 6.7 g of urea is needed in 100.0 g of water is needed to decrease the vapor pressure of water from 55.32 mmHg of pure water to 54.21 mmHg for the solution.

Final answer:

6.70 g of urea is required to adjust the vapor pressure of water as specified, using calculations based on Raoult's law and the relations of vapor pressures, mole fractions, and molar masses.

Explanation:

To solve this problem, we can use Raoult's law, which states that the vapor pressure of a solution is directly proportional to the mole fraction of the solvent. The formula for Raoult's law is P1 = X1P10, where P1 is the vapor pressure of the solvent in the solution, X1 is the mole fraction of the solvent, and P10 is the vapor pressure of the pure solvent.

First, we calculate the change in vapor pressure: ΔP = P10 - P1 = 55.32 mmHg - 54.21 mmHg = 1.11 mmHg. We use the given vapor pressures to find the mole fraction of water in the solution.

Using the equation for Raoult's law rearranged to find the mole fraction of the solvent (water), we get: X1 = P1 / P10 = 54.21 mmHg / 55.32 mmHg = 0.9799.

Since the mole fraction of the solute (urea) and solvent (water) together is 1, the mole fraction of urea is 1 - X1 = 0.0201. To find the moles of urea, we need the moles of water, which can be calculated from its mass (100.0 g) and molar mass (18.015 g/mol).

The moles of water are 100.0 g / 18.015 g/mol = 5.55 mol. Therefore, the moles of urea required are 5.55 mol × 0.0201 = 0.1115 mol. Finally, calculating the mass of urea required: 0.1115 mol × 60.056 g/mol (molar mass of urea) = 6.70 g.

In summary, 6.70 g of urea is needed to decrease the vapor pressure of water from 55.32 mmHg to 54.21 mmHg when dissolved in 100.0 g of water, keeping the temperature constant at 40°C.

Answer:

The coefficient for the hydrochloric acid is 6.

Explanation:

Stoichiometric coefficient are the number written in front of the reactants and products in balanced chemical reaction.

When solid aluminum reacts with hydrochloric acid to give aluminum chloride and hydrogen gas.

[tex]2Al(s)+6HCl(s)\rightarrow 2AlCl_3(aq)+3H_2(g)[/tex]

The coefficient for the aluminum is 2.

The coefficient for the hydrochloric acid is 6.

The coefficient for the aluminum chloride acid is 2.

The coefficient for the hydrogen gas  is 3.

Answer:

HCl < CH₃COOH < NH₃ < NaOH

Explanation:

Given compounds:

Acetic acid: CH₃COOH

Ammonia; NH₃

Hydrochloric acid: HCl

Sodium hydroxide: NaOH

All the solutions are of the same molarity which is 0.1M. We need to see how these compounds dissociate to form solutions in order to establish their pH value:

For Acetic acid;

            CH₃COOH + H₂O ⇄ H₃O⁺ + CH₃COO⁻

   Acetic acid is a weak acid and it ionizes slightly in solutions. It would have a pH close to 7

For Ammonia;

       NH₃ + H₂O ⇄ NH₄⁺ + OH⁻

   Ammonia is a weak base and it ionizes slightly in solutions. It sets up an equilibrium in the process. It's would be slightly above 7

For HCl:

               HCl + H₂O → H₃O⁺ + Cl⁻

HCl is a strong acid and ionizes completely in solutions. It has a very low pH

For NaOH:

          NaOH → Na⁺ + OH⁻

  NaOH ionizes also completely in solutions and it breaks down into sodium and hydroxide ions. It is a strong base and it would have a high PH value.

                 HCl < CH₃COOH < NH₃ < NaOH

This is the trend of increasing pH

Answer:

Explanation:hi

Answer:

True

Explanation:

In an uncompetitive inhibition, initially the substrate [S] binds to the active site of the enzyme [E] and forms an enzyme-substrate activated complex [ES].

The inhibitor molecule then binds to the enzyme- substrate complex [ES], resulting in the formation of [ESI] complex, thereby inhibiting the reaction.

This inhibition is called uncompetitive because the inhibitor does not compete with the substrate to bind on the active site of the enzyme.

Therefore, in an uncompetitive inhibition, the inhibitor molecule can not bind on the active site of the enzyme directly. The inhibitor can only bind to the enzyme-substrate complex formed.

Answer:

As we climb a mountain to a higher altitude, we experience a pressure increase. -True

Based on the data provided, it appears that the metal M with a molar mass of 27.0 g/mol reacts with hydrochloric acid to produce hydrogen gas, indicating the metal is likely aluminum. The reaction equation would be 2Al + 6HCl → 2AlCl3 + 3H2. The oxide of aluminum is Al2O3 and the sulfate is Al2(SO4)3.

To find the equation for the reaction of the metal M with hydrochloric acid, we should first understand the typical reaction that occurs, which is a metal reacting with an acid to produce a salt and hydrogen gas:

M + 2HCl → MCl2 + H2

Given the data, we can calculate the moles of hydrogen gas (H2):

n(H2) = PV / RT

Where P is the pressure in atmospheres (741 mmHg is equivalent to 741/760 atm), V is the volume (0.303 L), R is the gas constant (0.0821 L·atm/mol·K), and T is the temperature in Kelvin (17°C = 290 K).

Once we have the moles of H2, we can find the ratio of metal M to H2 in the reaction and then use the molar mass of M to determine how many moles of M reacted, which should be half the moles of H2 produced since the metal is likely to be in Group 1 or 2. Lastly, using the molar mass of the metal (27.0 g/mol), we can confirm the stoichiometry.

For the formulas of the oxide and sulfate of M:

In summary, the molar mass given and typical valence of metals may suggest that metal M is likely aluminum (Al), hence the possible chemical reactions would be:

2Al + 6HCl → 2AlCl3 + 3H2

Formulas for aluminum compounds:

Oxide of Al: Al2O3

Sulfate of Al: Al2(SO4)3

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The metal M is aluminum (Al), and the Balanced reaction is:  [tex]2\text{Al} + 6\text{HCl} \rightarrow 2\text{AlCl}_3 + 3\text{H}_2[/tex] the Oxide is: [tex]\text{Al}_2\text{O}_3[/tex], and Sulfate is [tex]\text{Al}_2(\text{SO}_4)_3[/tex].

To determine the reaction and write the formulas for the oxide and sulfate of the metal  M , we first need to identify the metal and its valency based on the data provided.

1. Determine the number of moles of hydrogen gas liberated:

Using the ideal gas law,  PV = nRT :

-  P  is the pressure in atm. To convert from mmHg to atm:  [tex]P = \frac{741 \, \text{mmHg}}{760 \, \text{mmHg/atm}} = 0.974 \, \text{atm}[/tex].

-  V  is the volume in liters:  V = 0.303 L.

-  R  is the ideal gas constant:  R = 0.0821 L·atm/(mol·K.

-  T  is the temperature in Kelvin:  [tex]T = 17^\circ \text{C} + 273.15 = 290.15 \, \text{K}[/tex].

Now, solve for  n , the number of moles of  H₂ :

[tex]n = \frac{PV}{RT} \\\\ n = \frac{(0.974 \, \text{atm})(0.303 \, \text{L})}{(0.0821 \, \text{L\ . atm/(mol\ . K)})(290.15 \, \text{K})} \\\\ n = \frac{0.295 \, \text{L\ . atm}}{23.81 \, \text{L\ . atm/mol}} \\\\ n \approx 0.0124 \, \text{mol}[/tex]

2. Determine the number of moles of metal  M  reacted:

Given the mass of the metal and its molar mass:

[tex]\text{Moles of metal} = \frac{\text{Mass}}{\text{Molar mass}} = \frac{0.225 \, \text{g}}{27.0 \, \text{g/mol}} = 0.00833 \, \text{mol}[/tex]

3. Determine the valency of the metal  M :

From the reaction with hydrochloric acid, each mole of metal  M  produces hydrogen gas. The general reaction is:

[tex]M + xHCl \rightarrow MCl_x + \frac{x}{2}H_2[/tex]

Since 0.00833 moles of  M  produced 0.0124 moles of  H₂:

[tex]0.00833 \, \text{mol} \times \frac{x}{2} = 0.0124 \, \text{mol} \\\\ x = \frac{0.0124 \times 2}{0.00833} \\\\ x \approx 2.98 \approx 3[/tex]

So, the valency of metal  M  is 3.

4. Write the chemical reaction:

The balanced equation for the reaction is:

[tex]2M + 6HCl \rightarrow 2MCl_3 + 3H_2[/tex]

5. Write the formulas for the oxide and sulfate of  M :

- The formula for the oxide of  M :

[tex]M_2O_3[/tex]

- The formula for the sulfate of  M :

[tex]M_2(SO_4)_3[/tex]

Given that the metal has a valency of 3, and the molar mass of 27 g/mol corresponds to aluminum (Al), the formulas for the oxide and sulfate of  M  (Aluminum) are:

- Oxide:  [tex]\text{Al}_2\text{O}_3[/tex]

- Sulfate: [tex]\text{Al}_2(\text{SO}_4)_3[/tex]

Thus, the metal  M  is aluminum (Al), and the balanced reaction, oxide, and sulfate formulas are:

- Balanced reaction:

[tex]2\text{Al} + 6\text{HCl} \rightarrow 2\text{AlCl}_3 + 3\text{H}_2[/tex]

- Oxide:

[tex]\text{Al}_2\text{O}_3[/tex]

- Sulfate:

[tex]\text{Al}_2(\text{SO}_4)_3[/tex]

Answer and Explanation:

Calorie is the unit of heat energy . There are 2 units with the same name 'calorie' which is widely used.

'The amount of heat energy required to increase the temperature of 1 gram of water by mass by [tex]1^{\circ}C[/tex] or 1 K is known as small calorie or gram calorie'.

Another one is large calorie which can be defined as :

'The amount of heat energy required to make arise in temperature of water 1 kg by mass by [tex]1^{\circ}C[/tex] or 1 K is known as large calorie or  kilcalorie and is represented as Cal or kcal'.

After the adoption of SI system, thee units of the metric system cal, C or kilocal are considered deprecated or obsolete with the SI unit for heat energy as 'joule or J'

1 cal = 4.184 J

1C or 1 kilocal = 4184 J

Calorimeter constant:

Calorimeter constant, represented as '[tex]C_{cal}[/tex]' is used to quantify the heat capacity or the amount of heat of a calorimeter.

It can be calculated by ther given formula:

[tex]{\displaystyle C_{cal}}={\frac {\Delta {H}}{\Delta {T}}}}}[/tex]

where,

[tex]{\Delta {T}}[/tex] = corresponding temperature change

[tex] {\Delta {H}[/tex] = enthalpy change

Its unit is J/K or J/1^{\circ}C[/tex] which can be convertyed to cal/1^{\circ}C[/tex] by dividing the calorimeter constant by 4.184 or 4184 accordingly.

A calorie is the amount of heat energy required to raise the temperature of one gram of water by one degree Celsius, equating to 4.184 Joules. The calorimeter constant is the heat capacity of the calorimeter, calculated by dividing the amount of heat absorbed by the temperature increase during a calorimetry experiment.

A calorie is a conventional unit of heat, defined as the quantity of heat energy required to raise the temperature of one gram of water by one degree Celsius. This definition of a calorie aligns specifically to the temperature change from 14.5°C to 15.5°C.To convert calories into Joules, the SI unit of heat, a constant of 4.184 Joules equals one calorie.

The calorimeter constant (also known as the heat capacity of the calorimeter) is vital in calorimetry, the process of measuring heat energy changes in a chemical system. It is specified in units of cal/°C. To calculate the calorimeter constant for your calorimeter, you would have to know the mass of the calorimeter and the temperature change observed during an experiment. The constant is calculated by dividing the amount of heat absorbed (in calories, calculated using known quantities and specific heat values of substances involved) by the temperature increase.

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Answers:

Explanation:

1) Chemical equation (given):

2) Follow the given steps:

Step 1: Convert the mass of A to moles.

moles of A:

Step 2: Convert the number of moles of A to the number of moles of B.

        2 mol A : 3 mol B

       2 mol A / 3 mol B = 0.993 mol A / x

       ⇒ x = 0.993 mol A × 3 mol B / 2 mol A = 1.49 mol of B

Step 3: Convert the number of moles of B to molecules of B.

To find the number of molecules of substance B produced from 27.6 g of substance A, calculate the moles of A, convert those moles to moles of B using the stoichiometry of the reaction, and then convert the moles of B to molecules using Avogadro's number. This results in 8.95 × 10²³ molecules of B.

To determine the number of molecules of substance B produced when 27.6 g of substance A reacts, we need to follow three steps:

Step 1: Moles of A = mass of A / molar mass of A = 27.6 g / 27.8 g/mol = 0.992 mol A

Step 2: According to the balanced equation 2A ⟶ 3B, the mole ratio is 2 moles of A : 3 moles of B. So, moles of B = moles of A × (3 moles B / 2 moles A) = 0.992 mol A × (3/2) = 1.488 mol B

Step 3: Molecules of B = moles of B × Avogadro's number = 1.488 mol B × 6.022 × 10²³ molecules/mol = 8.95 × 10²³ molecules of B.

Answer: The molar mass of the gas is 35.87 g/mol.

Explanation:

To calculate the mass of gas, we use the equation given by ideal gas:

PV = nRT

or,

[tex]PV=\frac{m}{M}RT[/tex]

where,

P = Pressure of gas = 945 mmHg

V = Volume of the gas = 0.35 L

m = Mass of gas = 0.527 g

M = Molar mass of gas = ? g/mo

R = Gas constant = [tex]62.3637\text{ L.mmHg }mol^{-1}K^{-1}[/tex]

T = Temperature of gas =  [tex]88^oC=[88+273]=361K[/tex]

Putting values in above equation, we get:

[tex]945mmHg\times 0.35L=\frac{0.527g}{M}\times 62.3637\text{ L.mmHg }mol^{-1}K^{-1}\times 361K\\\\M=35.87g/mol[/tex]

Hence, the molar mass of the gas is 35.87 g/mol.

The equilibrium constant expression for this reaction is [tex]K_{eq} = \frac{[HOCl]^{2}}{[Cl_{2}]^{2}}[/tex]. This is an example of a heterogeneous equilibrium wherein the states of the reactants and products are different. In such a case, only the concentration of the gaseous and aqueous substances are included in the equilibrium constant expression.

Further Explanation:

The equilibrium constant expression is the ratio of the concentration of the products and the concentration of reactants.  

The guidelines in writing the equilibrium constant expressions are as follows:

Note: Pure substances (i.e. solids and liquids) are not included in the equilibrium constant expression as their concentrations are constant.

The numerical equivalent of the Keq expression is called the equilibrium constant. It has a specific value for a given temperature. The equilibrium constant provides information about the spontaneity and progress of an equilibrium reaction.

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Keywords: equilibrium constant expression, equilibrium

Answer:

14.9802 grams of estrogen must be added to 216.7 grams of benzene.

Explanation:

The relative lowering of vapor pressure of solution containing non volatile solute is equal to mole fraction of solute.

[tex]\frac{p_o-p_s}{p_o}=\frac{n_2}{n_1+n_2}[/tex]

Where:

[tex]p_o[/tex] = Vapor pressure of pure solvent

[tex]p_s[/tex] = Vapor pressure of the solution

[tex]n_1[/tex] = Number of moles of solvent

[tex]n_2[/tex] = Number of moles of solute

[tex]p_o = 73.03 mmHg[/tex]

[tex]p_s= 71.61 mmHg[/tex]

[tex]n_1=\frac{216.7 g}{78.12 g/mol}=2.7739 mol[/tex]

[tex]\frac{73.03 mmHg-71.61 mmHg}{73.03 mmHg}=\frac{n_2}{2.7739 mol+n_2}[/tex]

[tex]n_2=0.05499 mol[/tex]

Mass of 0.05499 moles of estrogen :

= 0.05499 mol × 272.4 g/mol = 14.9802 g

14.9802 grams of estrogen must be added to 216.7 grams of benzene.

 Final answer:

The answer involves using Raoult's law to calculate the mass of estradiol needed to lower the vapor pressure of benzene by a specified amount. The calculation uses the initial and final vapor pressures of benzene and the molecular weights of both compounds to solve for the mass of estradiol.

The question relates to the calculation of the amount of a nonvolatile solute (estradiol) needed to be added to a solvent (benzene) to produce a desired lowering of the vapor pressure, via Raoult's law. Given the initial vapor pressure of benzene and the final vapor pressure after the addition of estradiol, we can use Raoult's law and the molecular weights of benzene and estradiol to solve for the mass of estradiol required.

To find the mass of estradiol that must be added to 216.7 grams of benzene to reduce its vapor pressure from 73.03 mm Hg to 71.61 mm Hg, we first calculate the mole fraction of benzene in the solution (XBenzene) after the addition of estradiol. Using the initial and final vapor pressures (Pinitial and Pfinal), and recognizing that the vapor pressure of the solution is directly proportional to the mole fraction of benzene, we get:

Pfinal = XBenzene × Pinitial

Then, we can calculate the moles of benzene (nBenzene) and use this value to find the moles of estradiol (nEstradiol) that correspond to the desired vapor pressure change. The mass of estradiol can then be computed by multiplying nEstradiol by its molecular weight (MW). Since estradiol is a nonvolatile nonelectrolyte, its addition does not alter the benzene vapor pressure other than through the change in mole fraction.

Answer:

The dissociation constant of phenol from given information is [tex]9.34\times 10^{-11}[/tex].

Explanation:

The measured pH of the solution = 5.153

[tex]C_6H_5OH\rightarrow C_6H_5O^-+H^+[/tex]

Initially      c

At eq'm   c-x       x  x

The expression of dissociation constant is given as:

[tex]K_a=\frac{[C_6H_5O^-][H^+]}{[C_6H_5OOH]}[/tex]

Concentration of phenoxide ions and hydrogen ions are equal to x.

[tex]pH=-\log[x][/tex]

[tex]5.153=-\log[x][/tex]

[tex]x=7.03\times 10^{-6} M[/tex]

[tex]K_a=\frac{x\times x}{(c-x)}=\frac{x^2}{(c-x)}=\frac{(7.03\times 10^{-6} M)^2}{ 0.529 M-7.03\times 10^{-6} M}[/tex]

[tex]K_a=9.34\times 10^{-11}[/tex]

The dissociation constant of phenol from given information is [tex]9.34\times 10^{-11}[/tex].

Final answer:

The acid dissociation constant (Ka) for phenol, given its pH of 5.153 in a 0.529 M solution, is calculated to be 9.47 x 10⁻¹² M by converting pH to hydrogen ion concentration and applying the equilibrium expression for dissociation.

Explanation:

To determine the acid dissociation constant (Ka) for phenol from its pH, we use the formula pH = -log[H⁺], where [H⁺] is the concentration of hydrogen ions in the solution. First, convert the pH given (5.153) to [H+] concentration: [H⁺] = 10^-pH = 10^-5.153 = 7.08 x 10⁻⁶ M. The ionization of phenol in water can be represented as: C₆H₅OH (aq) → C₆H₅O⁻ (aq) + H⁺ (aq). At equilibrium, the concentration of C6H5O- and H+ will be equal and be 7.08 x 10-6 M, as the weak acid only partially dissociates. The initial concentration of phenol is 0.529 M, so the concentration of undissociated phenol at equilibrium is approximately 0.529 M (assuming the dissociation is minimal due to the weak acid nature). The Ka for phenol can be calculated using the expression Ka = [H⁺][C₆H₅O⁻]/[C₆H₅OH], substituting the equilibrium concentrations yields Ka = (7.08 x 10⁻⁶)2/0.529 = 9.47 x 10⁻¹² M.

Answer: The molar mass of unknown solute is 195.44 g/mol.

Explanation:

To calculate the concentration of solute, we use the equation for osmotic pressure, which is:

[tex]\pi=icRT[/tex]

where,

[tex]\pi[/tex] = osmotic pressure of the solution = 0.750 atm

i = Van't hoff factor = 1 (for non-electrolytes)

c = concentration of solute = ?

R = Gas constant = [tex]0.0820\text{ L atm }mol^{-1}K^{-1}[/tex]

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

Putting values in above equation, we get:

[tex]0.750atm=1\times c\times 0.0820\text{ L.atm }mol^{-1}K^{-1}\times 298K\\\\c=0.0307mol/L[/tex]

The concentration of solute is 0.0307 mol/L

This means that, 0.0307 moles are present in 1 L of solution.

To calculate the molecular mass of solute, we use the equation:

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

Moles of solute = 0.0307 mol

Given mass of solute = 6g

Putting values in above equation, we get:

[tex]0.0307mol=\frac{6g}{\text{Molar mass of solute}}\\\\\text{Molar mass of solute}=195.44g/mol[/tex]

Hence, the molar mass of unknown solute is 195.44 g/mol.

Final answer:

To find the molecular weight of the unknown solute in the solution, use the osmotic pressure formula by considering the given values of pressure, temperature, and weight of the solute. By applying the formula, the molecular weight of the solute is calculated to be 180 g/mol.

Explanation:

To calculate the molecular weight of the unknown solute, we use the formula for osmotic pressure: π = iMRT. Given that the osmotic pressure is 0.750 atm, temperature is 25.0°C, and the weight of the solute is 6.00 g in 1.00 L solution, we can find the molecular weight to be 180 g/mol.

Answer:

It would not affect the volume of the base needed to reach the equivalence point

Explanation:

Once the unknown acid has been prepared and placed in the conical flask ready for titration, adding water to it cannot alter how much base is needed to neutralise it. Adding water to the acid merely dilutes the acid i.e if 20 parts of acid were in say 100 parts of water now 20 parts of acid are in 300 parts of water because you added more water. You will still need the exact amount of base to neutralise the 20 particles that are still in the conical flask awaiting titration.

Adding water does not make acid particles increase or decrease, it just means the base particles will have to collide with a lot more water particles to interact with the acid particles which will slow down the reaction. So the rate of the reaction can be affected, not volume of base needed to reach equivalence point.

Answer :

(a) The rate of [tex]NO_2[/tex] formed is, 0.066 M/s

(b) The rate of [tex]O_2[/tex] formed is, 0.033 M/s

Explanation : Given,

[tex]\frac{d[NO]}{dt}[/tex] = 0.066 M/s

The balanced chemical reaction is,

[tex]2NO(g)+O_2(g)\rightarrow 2NO_2(g)[/tex]

The rate of disappearance of [tex]NO[/tex] = [tex]-\frac{1}{2}\frac{d[NO]}{dt}[/tex]

The rate of disappearance of [tex]O_2[/tex] = [tex]-\frac{d[O_2]}{dt}[/tex]

The rate of formation of [tex]NO_2[/tex] = [tex]\frac{1}{2}\frac{d[NO_2]}{dt}[/tex]

As we know that,

[tex]\frac{d[NO]}{dt}[/tex] = 0.066 M/s

(a) Now we have to determine the rate of [tex]NO_2[/tex] formed.

[tex]\frac{1}{2}\frac{d[NO_2]}{dt}=\frac{1}{2}\frac{d[NO]}{dt}[/tex]

[tex]\frac{d[NO_2]}{dt}=\frac{d[NO]}{dt}=0.066M/s[/tex]

The rate of [tex]NO_2[/tex] formed is, 0.066 M/s

(b) Now we have to determine the rate of molecular oxygen reacting.

[tex]-\frac{d[O_2]}{dt}=-\frac{1}{2}\frac{d[NO]}{dt}[/tex]

[tex]\frac{d[O_2]}{dt}=\frac{1}{2}\times 0.066M/s=0.033M/s[/tex]

The rate of [tex]O_2[/tex] formed is, 0.033 M/s

The rate of the formation is the time taken and required by the reaction to yield the product. The rate of formation of nitrogen dioxide is, 0.066 M/s and oxygen is 0.033 M/s.

The rate of formation is the time derivative of the chemical reaction. The balanced chemical reaction can be given as:

[tex]\rm 2 NO + O_{2} \rightarrow 2NO_{2}[/tex]

From the reaction:

Given,

Rate of reaction  [tex]\dfrac{d[\rm NO]}{dt}[/tex] = 0.066 M/s

Calculate the rate of formation of [tex]\rm NO_{2}[/tex] :

[tex]\begin{aligned}\dfrac{1}{2} \dfrac{d[\rm NO_{2}]}{dt} &= \dfrac{1}{2} \dfrac{d[\rm NO]}{dt} \\\\\dfrac{d[\rm NO_{2}]}{dt} &=\dfrac{d[\rm NO]}{dt}\\\\&= 0.066 \;\rm M/s\end{aligned}[/tex]

Calculate the rate for molecular oxygen:

[tex]\begin{aligned}-\dfrac{d[\rm O_{2}]}{dt} &= -\dfrac{1}{2} \dfrac{d[\rm NO]}{dt} \\\\\dfrac{d[\rm O_{2}]}{dt} &=\dfrac{1}{2} \times 0.066 \\\\&= 0.033\;\rm M/s\end{aligned}[/tex]

Therefore, the rate of formation of nitrogen dioxide is, 0.066 M/s and oxygen is 0.033 M/s.

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Answer:

The correct answer is C where K=[CO2]^2[H2O]^3/[C2H5OH][O2]^3

Explanation:

Equilibrium constant (K) is expressed as the product of all the products divided by the product of all reactants. the coefficient in front of each reactants or products are used as their exponents. Solids and liquids are considered to be 1 hence they are not shown, but in this case everything is in gaseous form thus they are all expressed in the equilibrium formula formula.

Final answer:

The equilibrium constant for the combustion of ethanol is expressed using the balanced chemical equation, providing the correct formula for K from the given options.

Explanation:

Equilibrium constant (K) for the combustion of ethanol:

Write the balanced equation: C₂H₅OH(g) + 3O₂(g) ⇌ 2CO₂(g) + 3H₂O(g).

Express the equilibrium constant: K = [CO₂]²[H₂O]³ / [C₂H₅OH][O₂]³.

Hence, the correct choice is Option C.

Answer: The equations are given below.

Explanation:

For the given options:

The molecular equation for this follows:

[tex]AgNO_3(aq.)+NaI(aq.)\rightarrow AgI(s)+NaNO_3(aq.)[/tex]

Ionic form of the above equation follows:

[tex]Ag^+(aq.)+NO_3^-(aq.)+Na^+(aq.)+I^-(aq.)\rightarrow AgI(s)+Na^+(aq.)+NO_3^-(aq.)[/tex]

As, sodium and nitrate ions are present on both the sides of the reaction. Thus, it will not be present in the net ionic equation.

The net ionic equation for the above reaction follows:

[tex]Ag^+(aq.)+I^-(aq.)\rightarrow AgI(s)[/tex]

The molecular equation for this follows:

[tex]Ba(NO_3)_2(aq.)+K_2SO_4(aq.)\rightarrow 2KNO_3(aq.)+BaSO_4(s)[/tex]

Ionic form of the above equation follows:

[tex]Ba^{2+}(aq.)+2NO_3^-(aq.)+K^+(aq.)+SO_4^{2-}(aq.)\rightarrow 2K^+(aq.)+2NO_3^-(aq.)+BaSO_4(s)[/tex]

As, potassium and nitrate ions are present on both the sides of the reaction. Thus, it will not be present in the net ionic equation.

The net ionic equation for the above reaction follows:

[tex]Ba^{2+}(aq.)+SO_4^{2-}(aq.)\rightarrow BaSO_4(s)[/tex]

The molecular equation for this follows:

[tex]2NH_4NO_3(aq.)+K_2SO_4(aq.)\rightarrow 2KNO_3(aq.)+H_2SO_4(aq.)+NH_3(g)[/tex]

Ionic form of the above equation follows:

[tex]2NH_4^+(aq.)+2NO_3^-(aq.)+2K^+(aq.)+SO_4^{2-}(aq.)\rightarrow 2NH_3(g)+2H^+(aq.)+SO_4^{2-}(aq.)+2K^+(aq.)+2NO_3^-(aq.)[/tex]

As, nitrate, potassium and sulfate ions are present on both the sides of the reaction. Thus, it will not be present in the net ionic equation.

The net ionic equation for the above reaction follows:

[tex]2NH_4^+(aq.)\rightarrow 2NH_3(g)+2H^+(aq.)[/tex]

The molecular equation for this follows:

[tex]3LiCl(aq.)+Al(NO_3)_3(aq.)\rightarrow 3LiNO_3(aq.)+AlCl_3(s)[/tex]

Ionic form of the above equation follows:

[tex]3Li^+(aq.)+3Cl^-(aq.)+Al^{3+}(aq.)+NO_3^-(aq.)\rightarrow 3Li^+(aq.)+3NO_3^-(aq.)+AlCl_3(s)[/tex]

As, lithium and nitrate ions are present on both the sides of the reaction. Thus, it will not be present in the net ionic equation.

The net ionic equation for the above reaction follows:

[tex]Al^{3+}(aq.)+3Cl^-(aq.)\rightarrow AlCl_3(s)[/tex]

Hence, the molecular and ionic equations are given above.

Answer:

Dimer of two peptide chains with 1 mole of molybdenum metal each.

Explanation:

Percentage of molybdenum in protein = 0.08%

Molecular mass of nitrate reductase = 240,000 g

Mass of molybdenum = x

[tex]0.08\%=\frac{x}{240,000 g}\times 100=192 g[/tex]

Moles of molybdenum =[tex]\frac{192 g}{95.95 g/mol}=2.00 mol[/tex]

Each peptide chain of nitrate reductase contain 1 mole of molybdenum.

This means that nitrate reductase is composed of to two peptide chains. And in each peptide there is a single mole of molybdenum metal.

Answer:

0.2886 atm is the osmotic pressure of a solution.

Explanation:

Osmotic pressure of solution =[tex]\pi[/tex]

Concentration of the solution = c

Mass of the ammonium sulfate = 1.502 g

Moles of ammonium sulfate = [tex]\frac{1.502 g}{132.16 g/mol}=0.01136 mol[/tex]

Volume of the solution = 1 L

Concentration of the solution:

[tex]=\frac{\text{Moles of ammonium sulfate}}{\text{Volume of the solution}}[/tex]

[tex]c=\frac{0.01136 mol}{1 L}=0.01136 mol/L[/tex]

Temperature of the solution ,T= 36.54°C = 309.69 K

R = universal gas constant = 0.08206 L atm/mol K

[tex]\pi=cRT[/tex]

[tex]\pi=0.01136 mol/L\times 0.08206 L atm/mol K\times 309.69 K[/tex]

[tex]\pi=0.2886 atm[/tex]

0.2886 atm is the osmotic pressure of a solution.

To find the osmotic pressure, the temperature was converted to Kelvin, the moles of (NH₄)₂SO₄ were calculated using its molar mass, and the van't Hoff factor for the dissociation of (NH₄)₂SO₄ was determined. The gas constant and these values were then used in the osmotic pressure formula to calculate a pressure of approximately 0.08452 atm.

To calculate the osmotic pressure of a solution containing 1.502 g of (NH₄)₂SO₄ in 1 L at 36.54 Degrees Celsius, we use the formula:

π = i × M × R × T
where:

π is the osmotic pressure in atm,

i is the van't Hoff factor (number of particles the solute dissociates into),

M is the molarity of the solution,

R is the gas constant (0.08206 L·atm/mol·K), and

T is the temperature in Kelvin.

First, convert the temperature to Kelvin:

T(K) = 36.54 + 273.15 = 309.69 K
Then, calculate the moles of (NH4)2SO4 using its molar mass:

Moles = {1.502 g}÷{132.16 g/mol} ≈ 0.01136 mol
Since the solution's volume is 1 L, the molarity (M) is 0.01136 M. Ammonium sulfate ((NH₄)₂SO₄) dissociates into 2NH₄⁺ and SO₄²⁻. Therefore, the van't Hoff factor (i) is 3.

Finally, substitute the values into the formula to find the osmotic pressure:

π = 3 × 0.01136 M × 0.08206 L·atm/mol·K × 309.69 K
π ≈ 0.08452 atm
The osmotic pressure of the solution is approximately 0.08452 atm.

Answer: [tex]3.5\times 10^{-5}mol^{-1}Lsec^{-1}[/tex]

Explanation:

Rate law says that rate of a reaction is directly proportional to the concentration of the reactants each raised to a stoichiometric coefficient determined experimentally called as order.

[tex]C_2H_5Br(alc)+OH^-(alc)\rightarrow C_2H_5OH(l)+Br^-(alc)[/tex]

Given: Order with respect to [tex]C_2H_5Br[/tex] = 1

Order with respect to [tex]OH^-[/tex] = 1

Thus rate law is:

[tex]Rate=k[C_2H_5Br]^1[OH^-]^1[/tex]

k= rate constant

The rate in terms of reactants is given as negative as the concentration of reactants is decreasing with time whereas the rate in terms of products is given as positive as the concentration of products is increasing with time.

[tex]Rate=-\frac{1d[C_2H_5Br]}{dt}=k[C_2H_5Br]^1[OH^-]^1[/tex]

Given: [tex]\frac{d[C_2H_5]}{dt}]=1.7\times 10^{-7}[/tex]

Putting in the values we get:

[tex]Rate=1.7\times 10^{-7}=k[0.0477]^1[0.100]^1[/tex]

[tex]k=3.5\times 10^{-5}mol^{-1}Lsec^{-1}[/tex]

Thus the value of the rate constant is [tex]3.5\times 10^{-5}mol^{-1}Lsec^{-1}[/tex]

The rate constant of the reaction is 3.6 * 10^-5.

We define the rate of reaction as how quickly or slowly that a reaction is occuring. That is, the rate of disappearance of C2H5Br and OH- or rate of appearance of  C2H5OH(l)  and Br-.

Now;

Rate of disappearance of ethyl bromide = 1.7 x 10^-7 M/s.

Concentration of  ethyl bromide =   0.0477 M

Concentration of OH- = 0.100 M

Thus;

-d[C2H5Br]/dt = k  [C2H5Br] [OH-]

1.7 x 10^-7  = k [0.0477] [0.100]

k = 1.7 x 10^-7/ [0.0477] [0.100]

k = 3.6 * 10^-5

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Answer:

a)905,89 atm of pressure will be generated at 298K.

b)The sap of tree can rise upto 9,357.84 meters.

Explanation:

a)

Effective concentration of sap = c = 37 M

Osmotic pressure generate at 298K = [tex]\pi [/tex]

Temperature ,T = 298 K

[tex]\pi =cRT[/tex]

[tex]\pi =37 mol/L\times 0.08216 atm L/mol L\times 298 K[/tex]

[tex]\pi =905.89 atm[/tex]

905,89 atm of pressure will be generated at 298K across the endodermis root membrane.

b)

Given that 1.0 at of pressure raises the volume of water upto height of 10.33 m

Then 905.89 atm of pressure will raise the height of water upto:

[tex]\frac{10.33}{1.0}\times 905.89 m=9,357.84 m[/tex]

The sap of the tree can rise upto 9,357.84 meter.

The osmotic pressure generated across the root membrane of a tree with a 37 Molar sap concentration at 298K is 903.62 atm. This pressure could theoretically raise the sap to a height of about 9334.39 meters, though such a height is unrealistic in actual tree physiology due to factors like structural limits.

To calculate the osmotic pressure generated at 298K across the endodermis root membrane for a tree sap with an effective concentration of 37 Molar, we use the formula
c = iMRT, where:

i is the vant Hoff factor (which is 1 for sugars)

M is the molarity of the solution (37 M)

R is the ideal gas constant (0.08216 L.atm/mol.K)

T is the temperature in Kelvins (298K)

Plugging in the numbers, we get:
c = (1)(37 M)(0.08216 L.atm/mol.K)(298K) = 903.62 atm

To determine how high the sap can rise given an osmotic pressure of 1.0 atm can raise a column of water 10.33 meters, we set up a proportion:
(1 atm / 10.33 m) = (903.62 atm / x m)

Solving for x gives us x = 903.62 atm * 10.33 m/atm ≈ 9334.39 meters. Therefore, theoretically, the sap could rise to a height of approximately 9334.39 meters due to the generated osmotic pressure. However, this scenario is not realistic due to limitations such as hydrostatic pressure and structural integrity of the tree.

Osmotic pressure and root pressure are essential in understanding the transport of water and nutrients in plants, particularly in how they work together with transpiration and cohesive forces in water molecules to move sap through the xylem vessels from the roots to the leaves.

Answer:

Fertilizers are chemicals that kill plants.

Explanation:

Fertilizers are not pesticides. Fertilizers helps to improve plant yield by supplying nutrients needed for plant growth and food formation. When fertilizers are applied to plants, the nutrient pool increases and plants can readily grow without any deficiency resulting from lack of one mineral or the other.

Herbicides are used to kill plants.

Answer : The number of glucose molecule are, [tex]42.55\times 10^{23}[/tex]

Explanation : Given,

Mass of [tex]C_6H_{12}O_6[/tex] = 1273 g

Molar mass of [tex]C_6H_{12}O_6[/tex] = 180.156 g/mole

First we have to calculate the moles of [tex]C_6H_{12}O_6[/tex].

[tex]\text{Moles of }C_6H_{12}O_6=\frac{\text{Mass of }C_6H_{12}O_6}{\text{Molar mass of }C_6H_{12}O_6}=\frac{1273g}{180.156g/mole}=7.066moles[/tex]

Now we have to calculate the number of molecules of glucose.

As, 1 mole of glucose contains [tex]6.022\times 10^{23}[/tex] number of glucose molecules

So, 7.066 mole of glucose contains [tex]7.066\times 6.022\times 10^{23}=42.55\times 10^{23}[/tex] number of glucose molecules

Hence, the number of glucose molecule are, [tex]42.55\times 10^{23}[/tex]

Answer:Temperature increases

Explanation: As the gas in the container is an ideal gas so it should follow the ideal gas equation, the equation of state.

We know ideal gas equation to be PV=nRT where

   P=pressure

   V=Volume

   T=Temperature

   R=Real gas constant

   n=Number of moles

since the gas is insulated such that no heat goes into or out of the system .

When we compress the ideal gas using a piston, Thermodynamically it means that work is done on the system by the surroundings.

Now as the ideal gas is been compressed so the volume of the gas would decrease and slowly a time will reach when no more gas can be compressed that is there cannot be any further decrease in volume of the gas.

From the equation PV=nRT

Once there is no further compression is possible hence volume becomes constant so pressure of the ideal gas becomes directly proportional to the temperature as n and R are constants. Also as the pressure and volume are inversely related so an decrease in volume would lead to an increase in pressure.

As the ideal  gas is compressed so the pressure of the gas would increase since the gas molecules have smaller volume available after compression hence the gas molecules would quite frequently have collisions with other gas molecules or piston and this collision would lead to increase in speed of the gas molecules and  so the pressure would increase .

The increase in pressure would lead to an increase in temperature as show by the above ideal gas equation because the pressure and temperature are directly related.

So here we can say that work done on the system by surroundings leads to increase in temperature of the system.

Final answer:

When an ideal gas in a piston is adiabatically compressed, its temperature increases due to the increased internal energy resulting from work done on the gas.

Explanation:

When an ideal gas contained in a piston is compressed and the process is adiabatic, meaning no heat flows into or out of the system, the temperature of the gas increases. This is because the work done on the gas during the compression decreases its volume but increases its internal energy.

As the particles of the gas are forced closer together, they collide more frequently and with greater energy, leading to a rise in temperature. The change in temperature during an adiabatic process can be described by the adiabatic condition, which in the case of an ideal gas relates pressure, volume, and temperature in a specific way.

Answer : The solubility at [tex]25^oC[/tex] is, 0.0658 M

Explanation :

According to the Henry's Law, the solubility of a gas in a liquid is directly proportional to the pressure of the gas.

[tex]S\propto P[/tex]

or,

[tex]\frac{S_1}{S_2}=\frac{P_1}{P_2}[/tex]

where,

[tex]S_1[/tex] = initial solubility of carbon dioxide gas = 0.0347 M

[tex]S_2[/tex] = final solubility of carbon dioxide gas = ?

[tex]P_1[/tex] = initial pressure of carbon dioxide gas = 775 torr

[tex]P_2[/tex] = final pressure of carbon dioxide gas = 1470 torr

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

[tex]\frac{0.0347M}{S_2}=\frac{775\text{ torr}}{1470\text{ torr}}[/tex]

[tex]S_2=0.0658M[/tex]

Therefore, the solubility at [tex]25^oC[/tex] is, 0.0658 M

Using Henry's Law, the solubility of carbon dioxide in water at 25 °C would double from 0.0347 M at 775 Torr to 0.0694 M at 1470 Torr.

To determine the solubility of carbon dioxide at 25 °C and 1470 Torr, we can use Henry's Law, which states that the solubility of a gas in a liquid is directly proportional to the pressure of the gas above the liquid. Given that the solubility of carbon dioxide is 0.0347 M at 775 Torr, we can calculate its solubility at 1470 Torr (which is double the initial pressure) by simply doubling the initial solubility. Therefore, at 25 °C and 1470 Torr, the solubility of carbon dioxide in water would be 0.0694 M.