True or False: Mitochondrial ATP synthase is actually an ATPase and only catalyzes the hydrolysis of ATP

Steam distillation isolates trans-cinnamaldehyde at low temperature preventing decomposition.

Steam distillation is a method that allows the isolation of heat-sensitive compounds, such as trans-cinnamaldehyde, without subjecting them to high temperatures. In this process, steam is generated and passed through the mixture of water and the compound of interest, causing it to vaporize. The vapor containing the compound is then condensed by cooling, resulting in the isolation of the desired compound.

In the case of trans-cinnamaldehyde, steam distillation allows the compound to be isolated by vaporizing it at a temperature below its boiling point. This prevents decomposition of the compound, which can occur at high temperatures. Additionally, the use of steam as a carrier allows for more efficient extraction and separation of the compound from the mixture. Overall, steam distillation is a useful technique for isolating heat-sensitive compounds like trans-cinnamaldehyde.

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The pH of the cathode compartment solution is 2.10. Cathode compartment solution contains only [tex]Zn_2+[/tex] ions and water

What is pH?

pH is a measure of the acidity or basicity of a solution. It is defined as the negative logarithm of the concentration of hydrogen ions [H+] in a solution. The pH scale ranges from 0 to 14, with a pH of 7 being neutral, a pH less than 7 being acidic, and a pH greater than 7 being basic (or alkaline).

This problem involves a concentration cell consisting of two half-cells, one with a zinc electrode in contact with a solution containing Zn2+ ions at an unknown concentration and another with a zinc electrode in contact with a solution containing [tex]Zn_2+[/tex] ions at a known concentration of 0.100 M. The cell emf at 298 K is measured to be 0.700 V.

Since the two half-cells are identical, the reaction at each electrode must be the same, and the only difference between the two half-cells is the concentration of [tex]Zn_2+[/tex] ions. Therefore, the difference in potential between the two half-cells is proportional to the difference in concentration of [tex]Zn_2+[/tex] ions.

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In sublimation, the purification takes place when the sample goes directly from the solid phase to the vapor phase.

This process is used to purify substances that are difficult to separate using other methods, such as those with high boiling points or those that are highly reactive.

During sublimation, the sample is heated until it reaches its sublimation temperature, at which point it transitions directly from solid to vapor without passing through the liquid phase

The vapor is then collected and cooled, causing it to condense back into a solid form, which is then collected as the purified sample.

Sublimation is commonly used in the pharmaceutical, chemical, and food industries for the production of highly pure and concentrated substances.

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The pH of an aqueous solution at 25 °C that contains 3.98 x 10^-9 M hydronium ion can be calculated using the equation pH = -log[H3O+]. Substituting the given value of hydronium ion concentration into the equation, we get pH = -log(3.98 x 10^-9) = 8.4.

This means that the solution is basic, as the pH is greater than 7. At this pH, there are more hydroxide ions (OH-) present in the solution than hydronium ions (H3O+). This is because the pH scale is logarithmic, so each increase or decrease of one pH unit represents a tenfold change in acidity or basicity.

Understanding the pH of a solution is important in many fields, including chemistry, biology, and environmental science. It can affect the solubility and reactivity of substances, the function of enzymes and proteins, and the health of organisms and ecosystems. Thus, accurately measuring and controlling pH is essential for many applications, from wastewater treatment to medical diagnostics.

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The equilibrium constant for the overall reaction is K = K1 * K2.

The equilibrium constant for the overall reaction is the product of the equilibrium constants for the individual reactions, raised to the power of their respective stoichiometric coefficients in the overall reaction. In other words, if the two reactions are A + B ⇌ C (with equilibrium constant K1) and C + D ⇌ E (with equilibrium constant K2), and the overall reaction is A + B + D ⇌ E, then the equilibrium constant for the overall reaction (Keq,overall) is:

Keq,overall = (Keq,1)^1 * (Keq,2)^1/2

where the powers of the equilibrium constants are determined by the stoichiometric coefficients of the reactants and products in each reaction.

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In DMSO (dimethyl sulfoxide), the better nucleophile between CH3O- (methoxide ion) and CH3OH (methanol) is CH3O-.

Nucleophilicity is a measure of a species' ability to donate an electron pair and form a new bond with an electrophile. Factors that influence nucleophilicity include charge, electronegativity, and the solvent in which the reaction takes place.
In this case, CH3O- has a negative charge on the oxygen atom, making it a stronger nucleophile compared to CH3OH, where the oxygen atom only has a lone pair of electrons without any formal charge. The negative charge on the oxygen in CH3O- indicates a higher electron density, which increases its ability to donate electrons and form a bond with an electrophile.
Additionally, DMSO is a polar aprotic solvent, meaning it does not have any acidic protons that can participate in hydrogen bonding. Polar aprotic solvents tend to favour the nucleophilicity of anions over neutral species like CH3OH. This further supports CH3O- being the better nucleophile in DMSO compared to CH3OH.
In summary, CH3O- is a better nucleophile than CH3OH in DMSO due to its negative charge and the solvent's polar aprotic nature, which enhances the nucleophilicity of charged species.

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The equilibrium constant for reaction 2 is 1/[tex]K^{2}[/tex], where K is the equilibrium constant for reaction 1.

What is Equilibrium?

In chemistry, equilibrium refers to a state in a chemical reaction where the forward reaction rate is equal to the reverse reaction rate. At equilibrium, the concentrations of reactants and products no longer change, and the system is said to be in a steady-state.

Taking the inverse of both sides and squaring, we get:

1/[tex]K^{2}[/tex] = [tex]([SO₂][O₂]^{1/2}[/tex]/[SO₃]

Now, let's consider the second reaction. The equilibrium constant (K') for the second reaction is given as: K' = [tex][SO₂]^2[O₂]/[SO₃]^{2}[/tex]

To relate K and K', we can use the stoichiometry of the reactions. We can see that the second reaction is the reverse of the first reaction, multiplied by 2. Therefore, we can write: K' = (1/[tex]K^{2}[/tex])(1/2)

Substituting the value of 1/[tex]K^{2}[/tex], we get: K' = 1/(2K²)

So, the equilibrium constant for the second reaction is 1/[tex]K^{2}[/tex].

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When it comes to assigning stereochemistry to a stereocenter, it is important to understand the concept of priority groups. Each group attached to the stereocenter is assigned a priority based on the atomic number of the atom that it is directly bonded to.

The group with the highest priority is typically designated as the "1" group, followed by the "2" and "3" groups, with the lowest priority group being designated as the "4" group.

In cases where the lowest priority group is located at the front of the structure (on a wedge bond), it can be a bit tricky to assign stereochemistry. However, there is a simple workaround. To assign stereochemistry, you can imagine rotating the entire structure by 180 degrees so that the lowest priority group is now located at the back (on a hashed bond). Once the structure has been rotated, you can assign priorities as usual, with the newly located lowest priority group being designated as the "4" group. From there, you can determine the stereochemistry of the stereocenter using the R/S system as normal.

It is important to note that this workaround only applies when the lowest priority group is located on a wedge bond at the front of the structure. In cases where the lowest priority group is located on a hashed bond at the back of the structure, stereochemistry can be assigned using the R/S system directly without the need for any additional steps.

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Alkenes are resistant to oxidation. In the presence of an acid catalyst, however, they are prone to dehydration.

Alkenes have a double bond between two carbon atoms, which means they have fewer hydrogen atoms than their corresponding alkanes. This makes them less susceptible to oxidation reactions, which typically involve the transfer of oxygen or other electronegative atoms to the molecule.

In the presence of an acid catalyst, however, alkenes can undergo an elimination reaction called dehydration. This involves the removal of a molecule of water (H2O) from the alkene, resulting in the formation of a new double bond and a more highly unsaturated product. The acid catalyst helps to remove a proton from one of the carbon atoms adjacent to the double bond, making it more susceptible to attack by a nucleophile (such as water) that can abstract a proton and leave a new double bond behind.

Dehydration is an important reaction for the synthesis of alkenes and other unsaturated compounds in organic chemistry. By controlling the reaction conditions and choice of catalyst, chemists can selectively form specific double bonds and control the stereochemistry of the product.

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To determine the number of moles of B present at 10 s, we need to use the stoichiometry of the reaction. From the balanced equation, we know that 1 mole of A reacts to form 1 mole of B.

At the beginning of the reaction (t=0 s), we have 0.124 mol of A. At 10 s, the amount of A that has reacted is the difference between the initial amount and the amount at 10 s:

0.124 mol - 0.110 mol = 0.014 mol of A has reacted.

Since the reaction is 1:1, this means that 0.014 mol of B has been formed. Therefore, at 10 s, there are 0.014 mol of B present in the flask.

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Answer:

If the ocean is to acidic, people and plants would be negatively affected.

Explanation:

Answer:

if would be dangerous for the animals in water.

Explanation:

A substance that can act as either an acid or a base is described as amphoteric (option d).

An amphoteric substance is a molecule or ion that can act as either an acid or a base, depending on the circumstances. This means that it has the ability to donate or accept a proton, depending on the nature of the other substance it is reacting with.

For example, water is an amphoteric substance because it can act as an acid in the presence of a stronger base, such as hydroxide ions, by donating a proton.

Conversely, water can act as a base in the presence of a stronger acid, such as hydrogen ions, by accepting a proton. Other examples of amphoteric substances include amino acids, which contain both acidic and basic functional groups.

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Ester lactone macrolides are a group of organic compounds with a complex structure that includes an ester, lactone, and macrolide ring.

Ester lactone macrolides are a class of natural products that exhibit a broad range of biological activities, including antimicrobial, anticancer, and immunosuppressive properties. They are composed of three key structural elements: an ester group, a lactone ring, and a macrolide ring.

The ester group is a functional group consisting of a carbon double-bonded to an oxygen, while the lactone ring is a cyclic ester formed by the reaction of a hydroxyl group with a carboxylic acid group.

The macrolide ring is a large cyclic lactone that contains at least 12 carbon atoms, and often has additional functional groups such as ketones, alcohols, and amines. Together, these three structural elements create a unique and complex molecule with a wide range of biological activities.

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The original molarity of a solution of HCOOH (formic acid) whose pH is 3.26 at equilibrium, we need to use the relationship between pH and molarity for weak acids. Therefore, the original molarity of the HCOOH solution is 0.022 M.

To find the original molarity of the HCOOH solution at equilibrium, follow these steps:

1. Convert pH to [H+]: pH = -log10([H+]), so [H+] = 10^(-pH) = 10^(-3.26) = 5.49 x 10^(-4) M

2. Write the equilibrium expression for the dissociation of HCOOH: HCOOH ⇌ H+ + HCOO-, where Ka is the acid dissociation constant.

3. Let the original molarity of HCOOH be M. Since HCOOH loses one H+ to form HCOO-, at equilibrium, [HCOOH] = M - 5.49 x 10^(-4) M, [H+] = 5.49 x 10^(-4) M, and [HCOO-] = 5.49 x 10^(-4) M.

4. Use the Ka expression: Ka = ([H+][HCOO-])/[HCOOH]. Find the Ka value for HCOOH (formic acid) from a reference table or source, which is approximately 1.77 x 10^(-4).

5. Plug in the equilibrium concentrations: 1.77 x 10^(-4) = (5.49 x 10^(-4))^2 / (M - 5.49 x 10^(-4))
At equilibrium, we assume that the concentration of HCOO- and HCOOH are equal, so we can simplify the equation to:

pH = pKa + log(1)

which gives us:

pH = pKa

Substituting in the values for pH and pKa, we get:

3.26 = -log(1.8 x 10^-4)

Solving for [HA], we get:

[HA] = 0.022 M

6. Solve for the original molarity (M): M ≈ 0.017 M

So, the original molarity of the HCOOH solution is approximately 0.017 M.

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The principal organs that regulate the pH of the carbonic acid-bicarbonate buffer system in the blood are the lungs and the kidneys. option(b).

The lungs regulate pH by controlling the concentration of carbon dioxide (CO₂) in the blood. When CO₂ levels increase, the blood becomes more acidic, which can be corrected by exhaling CO₂. Conversely, when CO₂ levels decrease, the blood becomes more alkaline, which can be corrected by retaining CO₂.

The kidneys regulate pH by controlling the concentration of bicarbonate (HCO₃⁻) in the blood. The kidneys can either excrete or retain bicarbonate ions, depending on the pH of the blood. When the blood is too acidic, the kidneys can reabsorb bicarbonate ions to help neutralize the excess acid. When the blood is too alkaline, the kidneys can excrete bicarbonate ions to help lower the pH.

Therefore, the correct answer is b. lungs, kidneys.

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Fischer esterification is a commonly used method for the synthesis of esters, including the conversion of salicylic acid into aspirin and oil of wintergreen.

The reaction involves the reaction of salicylic acid with an alcohol (in this case, methanol for oil of wintergreen and acetic anhydride for aspirin) in the presence of an acid catalyst (usually sulfuric acid) to form the corresponding ester. Here are the equations for the conversion of salicylic acid into each of these esters using Fischer esterification:

1. Conversion of salicylic acid to oil of wintergreen (methyl salicylate)

Salicylic acid + methanol + sulfuric acid --> Methyl salicylate + water

2. Conversion of salicylic acid to aspirin (acetylsalicylic acid)

Salicylic acid + acetic anhydride + sulfuric acid --> Acetylsalicylic acid + acetic acid

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0.583 M is the concentration of 15.0 mL of an acid solution that requires 35.0 mL of 0.25M NaOH to neutralize it.

To determine the concentration of the acid solution, we need to use the equation:
Molarity (M) = moles of solute/volume of solution in litres
We know the volume of NaOH used to neutralize the acid solution, which is 35.0 mL or 0.035 L. We also know the concentration of NaOH, which is 0.25M. From this, we can calculate the number of moles of NaOH used:
moles of NaOH = concentration of NaOH x volume of NaOH used
moles of NaOH = 0.25M x 0.035 L
moles of NaOH = 0.00875 mol
Since the acid and NaOH react in a 1:1 ratio, the number of moles of acid in the solution is also 0.00875 mol. We know the volume of the acid solution used, which is 15.0 mL or 0.015 L. We can now use the equation above to calculate the concentration of the acid:
Molarity (M) = moles of solute/volume of solution in litres
Molarity (M) = 0.00875 mol / 0.015 L
Molarity (M) = 0.583 M
Therefore, the concentration of the acid solution is 0.583 M.

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Infinitesimal changes associated with reversible processes refer to small, incremental changes that occur in a system at each step of the process, while maintaining equilibrium. Irreversible processes, on the other hand, involve changes that cannot be reversed and lead to a loss of equilibrium.

In reversible processes, changes occur gradually and infinitesimally, meaning that each step is taken slowly to allow the system to continuously adjust and maintain equilibrium. These changes are typically represented using mathematical differentials, such as infinitesimal changes in temperature, pressure, or volume. Reversible processes are idealized and theoretical, serving as a benchmark for understanding system behavior. In contrast, irreversible processes occur spontaneously and rapidly, often leading to a significant loss of equilibrium.

These changes cannot be easily undone, and the system does not return to its initial state. Irreversible processes involve sudden changes, such as an explosion or mixing two substances, and are common in real-world scenarios.

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True. Green sulfur bacteria have two reaction centres arranged in tandem. These reaction centres are called P840 and P760. The P840 reaction centre absorbs light with a wavelength of 840 nanometers, while the P760 reaction centre absorbs light with a wavelength of 760 nanometers.

The arrangement of these reaction centres allows green sulfur bacteria to carry out photosynthesis in environments with low light intensity, such as the bottom of deep lakes or oceans.
In the process of photosynthesis, light energy is absorbed by the reaction centres and converted into chemical energy, which is used to produce ATP and NADPH for the synthesis of organic molecules. Green sulfur bacteria are unique in that they use sulfur compounds rather than water as electron donors in the process of photosynthesis. This allows them to survive in anoxic environments where other photosynthetic organisms cannot survive.
Overall, the arrangement of two reaction centres in tandem allows green sulfur bacteria to efficiently harvest light energy and carry out photosynthesis in low-light environments, making them an important contributor to the ecology of deep lakes and oceans.

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A species which a conjugate base is NO₂⁻(aq).

So, the correct answer is D.

In the given reaction, the acid HNO₂ donates a proton to water to form the hydronium ion (H₃O⁺) and the nitrite ion (NO₂⁻).

A conjugate base is the species that remains after an acid loses a proton.

In this case, HNO₂ donates a proton, so it is the acid and its conjugate base is the NO₂⁻ ion.

Therefore, the answer is option D) NO₂⁻(aq) is the conjugate base in the given reaction.

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3Mg + N[tex]_2[/tex] → Mg[tex]_3[/tex] N[tex]_2[/tex] is the balanced chemical equation for the given chemical reaction, Mg reacts with nitrogen upon heating to form magnesium nitride.

An equation on a chemical reaction is said to be balanced if both the reactants or the products have the same number of atoms and total charge for each component of the reaction. In other words, each side of the reaction have an equal balance of mass and charge. The products and reactants of a chemical reaction are listed in an imbalanced chemical equation, but the amounts necessary to meet the conservation of mass are not specified. 3Mg + N[tex]_2[/tex] → Mg[tex]_3[/tex] N[tex]_2[/tex] is the balanced chemical equation for the given chemical reaction, Mg reacts with nitrogen upon heating to form magnesium nitride.

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The expected product when trans-cinnamic acid is treated with hydrogen and a catalyst, under typical conditions that do not reduce aromatic rings, is cinnamaldehyde.

1. Trans-cinnamic acid has an alkene (double bond) in its structure, along with a carboxylic acid group and an aromatic ring.
2. When treated with hydrogen (H2) and a catalyst (usually palladium on carbon, Pd/C), the alkene will undergo hydrogenation, which means the double bond will be reduced to a single bond.
3. The aromatic ring remains unaffected due to the typical conditions used, which prevent its reduction.
4. Since the carboxylic acid group is also reduced, it will be converted into an aldehyde group.
5. Therefore, the product obtained is cinnamaldehyde, which has a single bond in the side chain and an aldehyde group instead of the carboxylic acid group.
Under the given conditions, hydrogenation of trans-cinnamic acid results in the formation of cinnamaldehyde, with the alkene and carboxylic acid groups being reduced while the aromatic ring remains unaffected.

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NH[tex]_3[/tex] is not a strong electrolyte. Therefore, the correct option is option D among all the given options.

A medium that contains ions and is electrically conducting due to the mobility of those ions but does not conduct electrons is called an electrolyte. This contains the majority of salts, acids, or bases that are soluble when dissolved in polar solvents like water.

The material divides into anions and cations during dissolution, which scatter evenly throughout the solvent. There are other solid-state electrolytes. The material that is dissolved is referred to as an electrolyte in medicine and occasionally in chemistry. NH[tex]_3[/tex] is not a strong electrolyte.

Therefore, the correct option is option D.

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The strongest reducing agent under standard condition is c)Ti²⁺

The strongest reducing agent under standard conditions is the ion with the most negative reduction potential (E) value. Based on the provided E data table:

E(Ti³⁺, Ti²⁺) = -0.90V
E(Zn²⁺, Zn) = -0.80V
E(Cr³⁺, Cr) = -0.744V
E(Cu²⁺, CU) = -0.42V
E(Fe³⁺, Fe²⁺) = 0.771V
E(Hg²⁺, Hg₂²⁺) = 0.908V

The most negative value is E(Ti³⁺, Ti²⁺) = -0.90V. Therefore, the strongest reducing agent under standard conditions is Ti²⁺. So, your answer is:
A reducing agent is one of the reactants of an oxidation-reduction reaction which reduces the other reactant by giving out electrons to the reactant. If the reducing agent does not pass electrons to other substances in a reaction, then the reduction process cannot occur.
The correct answer is c) Ti²⁺

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"If CO2 is removed, the reaction will shift in the forward direction to replace the lost reactant. As a result, the concentration of CO will increase, while the concentration of H2O will decrease.

Therefore, the correct answer is (a) increase.''

The given reaction is a reversible reaction, and it can be represented as:

r x n: CO2 + H2 ⇌ CO + H2O

If CO2 is removed, the reaction will shift in the forward direction to replace the lost reactant.

This is known as Le Chatelier's principle, which states that a system at equilibrium will respond to any stress by shifting in a direction that partially offsets the effect of the stress.

In this case, the removal of CO2 is a stress that will cause the equilibrium to shift in the forward direction.

As a result, the concentration of CO will increase, while the concentration of H2O will decrease.

Therefore, the correct answer is (a) increase.

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The modified amino acid derived from tyrosine that acts as a neurotransmitter is dopamine. So, the correct answer is:
d. dopamine

Neurotransmitters are chemical messengers that your body can't function without. Their job is to carry chemical signals (“messages”) from one neuron (nerve cell) to the next target cell. The next target cell can be another nerve cell, a muscle cell or a gland.

There are more than 40 neurotransmitters in the human nervous system; some of the most important are acetylcholine, norepinephrine, dopamine, gamma-aminobutyric acid (GABA), glutamate, serotonin, and histamine.

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The reaction you provided is: C2H5OH (l) → CH3OCH3 (g)

To determine the enthalpy change (ΔH) for the reaction, we can use the given standard molar enthalpies of formation (∆Hf) for the reactants and products involved.

The equation for the reaction is:

∆Hf(CH3OCH3) = ∆Hf(C2H5OH) - ∆Hf(H2O) - ∆Hf(CO2)

Substituting the given values:

∆Hf(CH3OCH3) = -1460.4 kJ/mol - (-276 kJ/mol -285.83 kJ/mol -393.52 kJ/mol)

Simplifying:

∆Hf(CH3OCH3) = -1460.4 kJ/mol + 955.35 kJ/mol

∆Hf(CH3OCH3) = -505.05 kJ/mol

Therefore, the enthalpy change (∆H) for the reaction C2H5OH (l) → CH3OCH3 (g) is -505.05 kJ/mol.

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The maximum number of product molecules we can form at the end of the final reaction is 19.5% of the starting number of reactant molecules, or 19.5 molecules.

To solve this problem, we need to find the maximum number of product molecules that can be formed at the end of the final reaction. We can do this by multiplying the number of reactant molecules at each stage by the yield percentage for that stage, and then multiplying all of the results together.

Starting with 100 molecules of the first limiting reagent, we can calculate the number of reactant molecules at each stage as follows:

- Stage 1: 100 molecules
- Stage 2: 80% yield, so 80 molecules
- Stage 3: 90% yield, so 72 molecules
- Stage 4: 65% yield, so 47 molecules
- Stage 5: 76% yield, so 36 molecules

Multiplying these results together, we get:

100 x 80% x 90% x 65% x 76% = 19.5%

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The law of mass action states that the relative concentration of reactants and products at equilibrium can be expressed in terms of an equilibrium constant . option (d).

The equilibrium constant (Kc) is defined as the product of the concentrations of the products raised to their stoichiometric coefficients divided by the product of the concentrations of the reactants raised to their stoichiometric coefficients, with each concentration term raised to a power equal to its stoichiometric coefficient.

The value of Kc depends only on the temperature of the system and is a constant at a given temperature. It provides a quantitative measure of the position of an equilibrium and can be used to predict the direction in which a reaction will proceed to reach equilibrium under different conditions.

The law of mass action states that the relative concentrations of reactants and products at equilibrium can be expressed in terms of an equilibrium constant, which is a constant at a given temperature and provides a quantitative measure of the position of an equilibrium.

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Chiralization is the use of an optically active reagent or catalyst to convert an optically inactive starting material into an optically active product.

So, the correct answer is E.

Chiralization is a process of converting an optically inactive starting material into an optically active product using an optically active reagent or catalyst.

This is achieved through asymmetric induction, which involves the transfer of chirality from the chiral reagent or catalyst to the substrate.

The chiral reagent or catalyst creates a chiral environment that selectively favors the formation of one enantiomer over the other.

Chiralization is an important technique in organic synthesis and is used to produce chiral compounds for pharmaceuticals, agrochemicals, and other industries.

It is different from racemization, which involves the conversion of a chiral compound into a racemic mixture, and optical reduction, which is the reduction of an optically active compound to an optically inactive one.

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