Which change to the experimental design would improve the reliability of the engineers' measurements?

ОА.

using a liquid other than water to determine porosity

ОВ.

using flasks instead of beakers

OC

testing single samples from more than three locations

OD

testing more samples from each location

here you go. kindly check attatchement

Yes, the investigation did answer the question about whether two magnets create magnetic force fields that allow them to interact without touching. The investigation provided enough evidence to support the idea that invisible magnetic force fields exist.

The investigation provided enough evidence to support the idea that invisible magnetic force fields exist:

The investigation involved observing how two magnets interact with each other without touching. The magnets were brought closer together until they interacted, and then they were moved further apart. This process was repeated several times, and the results were observed and recorded. During the investigation, it was observed that the magnets interacted with each other even when they were not touching. This interaction occurred because the magnets created magnetic force fields that allowed them to interact with each other even when they were not in direct contact.The observation of the interaction between the magnets provided enough evidence to support the idea that invisible magnetic force fields exist. This is because the interaction between the magnets could not be explained by any other means except through the existence of magnetic force fields. Therefore, the investigation gave enough evidence to support the idea that invisible magnetic force fields exist.

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Answer:

large atomic size and low ionization energy.

Explanation:

Metallic behavior correlates with large atomic size and low ionization energy. Thus, metallic behavior increases down a group and decreases from left to right across a period. Elements in Groups 1A(1) and 2A(2) are strong reducing agents; nonmetals in Groups 6A(16) and 7A(17) are strong oxidizing agents.

4974.9 kJ of energy are released during the interaction between 162.5 g of O2 and 216.7 g of NH3.

The given chemical equation shows the reaction between ammonia (NH3) and oxygen (O2) to form nitrogen monoxide (NO) and water (H2O). The enthalpy change (ΔH) for this reaction is -1225.6 kJ per mole of O2 consumed.

To determine the energy given off by the reaction between 162.5 g of O2 and 216.7 g of NH3, we need to first determine the limiting reactant. This is the reactant that is completely consumed in the reaction and limits the amount of product formed.

To find the limiting reactant, we need to calculate the number of moles of each reactant. The molar mass of O2 is 32.00 g/mol, so 162.5 g of O2 is equivalent to 5.078 moles of O2. The molar mass of NH3 is 17.03 g/mol, so 216.7 g of NH3 is equivalent to 12.71 moles of NH3.

The stoichiometric ratio of O2 to NH3 is 5:4, meaning that for every 5 moles of O2 consumed, 4 moles of NH3 are required. From the above calculations, we can see that there is excess NH3 in this reaction since only 4.063 moles of O2 are required to react with 3.250 moles of NH3.

Therefore, the amount of O2 that reacts is 4.063 moles, and the energy given off by the reaction is:

ΔH = (-1225.6 kJ/mol) x (4.063 mol) = -4974.9 kJ

Therefore, the reaction between 162.5 g of O2 and 216.7 g of NH3 gives off 4974.9 kJ of energy.

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Dalton employed the scientific method—reasoning based on the findings of experiments—whereas Democritus exclusively relied on his own logic and mental inferences.

Democritus developed his ideas about atoms by intellectual inquiry, whereas Dalton developed his ideas through experimentation and meticulous assessment. Democritus had no verifiable truths to support his beliefs and no means of testing them because he relied solely on ideas and did not conduct controlled tests.

Dalton tested his theories and took exact measurements to refine them. Democritus lacked empirical evidence to back up his beliefs and no way to test them because he relied solely on intellect and did not conduct scientific experiments.

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The principles that underlie balancing chemical equations include the law of conservation of mass and the concept of stoichiometry.

The law of conservation of mass states that matter can neither be created nor destroyed in a chemical reaction, meaning that the total mass of the reactants must be equal to the total mass of the products. This principle requires that the number of atoms of each element on the reactant side of the equation must be equal to the number of atoms of that element on the product side. The concept of stoichiometry involves using the balanced equation to determine the quantitative relationships between the reactants and products, including the amounts of each substance involved in the reaction.

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--The complete question is, The principles that underlie balancing chemical equations include the______________ and the concept of stoichiometry. ---

Moreover, the process of crystallization involves the mass transfer of a solute from a liquid solution to a pure solid crystalline phase.

Crystallization is the process when a solute transfers from a liquid solution to a pure solid crystalline substance. In this process, the solute molecules or ions in a solution come together to form a crystal lattice, resulting in the formation of a solid phase. This process is commonly used in chemical and pharmaceutical industries to purify substances or to obtain a specific crystal form. The conditions under which crystallization occurs, such as temperature, concentration, and solvent choice, can significantly impact the properties of the resulting crystals.

Crystallization is used in the purification of chemicals to obtain a pure compound from a mixture. By controlling the temperature and concentration of the solution, the impurities are excluded from the growing crystal lattice, leaving a pure compound behind.

Crystallization is used in the production of pharmaceuticals to obtain pure crystals of the active pharmaceutical ingredient (API). The crystal form of the API can impact its solubility, stability, and bioavailability, making crystallization a crucial step in the production of pharmaceuticals.

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Cleravage is a characteristic of mineral that is related to breaking along planes. The tendency of a mineral to break along flat, even surfaces or planes is known as cleavage,

and it depends on how the atoms are arranged inside the crystal structure of the material. Well-defined cleavage planes in minerals make them more likely to break readily along them, resulting in smooth, flat surfaces with certain geometric forms. As many minerals have varied cleavage qualities, minerals may be distinguished by the quantity and direction of their cleavage planes. Mica minerals, for instance, have good basal cleavage, which means they frequently fracture along a single plane to form thin, flexible sheets. Calcite tends to break along three planes that cross at angles other than 90 degrees because it possesses rhombohedral cleavage.

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The intensity of the infrared (IR) absorption bands is proportional to the amount of a particular functional group present in a molecule.

IR spectroscopy is a powerful technique used to study the vibrations of chemical bonds in molecules. When a molecule absorbs IR radiation, its chemical bonds are excited and vibrate in different ways, resulting in characteristic absorption bands that can be used to identify the functional groups present in the molecule.

The intensity of these bands is proportional to the number of bonds of a particular functional group that absorb IR radiation, as well as the strength of these bonds. Therefore, the intensity of the IR absorption bands provides information about the composition and structure of a molecule, allowing researchers to identify and study its chemical properties.

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It follows the principles of Atom Economy, Less Hazardous Chemical Syntheses, Safer Solvents and Auxiliaries, Reduce Derivatives, and Catalysis from the Twelve Principles of Green Chemistry.

Green Chemistry is a branch of chemistry that focuses on the design of chemical products and processes that are environmentally sustainable, safe, and economically viable. It seeks to minimize the environmental impact of chemical reactions and reduce or eliminate the use and generation of hazardous substances in chemical production.

Methyl-4-methoxycinnamate is a commonly used compound in the fragrance and cosmetic industries. Here are the Twelve Principles of Green Chemistry and the principles that are followed in the synthesis of Methyl-4-methoxycinnamate:

2. Atom Economy: The synthesis of Methyl-4-methoxycinnamate has a good atom economy because the reaction involves the direct condensation of two starting materials, and no by-products are generated.

3. Less Hazardous Chemical Syntheses: The reaction conditions in the synthesis of Methyl-4-methoxycinnamate are relatively mild, and the reactants and products are non-toxic.

4. Safer Solvents and Auxiliaries: Ethanol is used as a solvent in the reaction, which is a safer solvent than other solvents that may be used in similar reactions.

5. Reduce Derivatives: The synthesis of Methyl-4-methoxycinnamate does not involve any unnecessary derivatization steps.

6. Catalysis: Sodium hydroxide is used as a catalyst in the reaction, which helps to increase the rate of the reaction.

Overall, the synthesis of Methyl-4-methoxycinnamate follows the principles of Atom Economy, Less Hazardous Chemical Syntheses, Safer Solvents and Auxiliaries, Reduce Derivatives, and Catalysis from the Twelve Principles of Green Chemistry.

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A liquid-gas system at equilibrium is disturbed by adding or removing vapor from the system (at constant temperature). The correct statements for the vapor pressure regarding this situation are A, B, and D.

A. Adding vapor will cause a temporary increase in vapor pressure: When the vapor is added to the system, the total vapor pressure increases, and the vapor pressure in the system is greater than the original equilibrium vapor pressure until the system re-equilibrates.

B. Adding or removing vapor will result in a new equilibrium vapor pressure: The equilibrium vapor pressure will be affected by the addition or removal of vapor. When the vapor is added or removed, the system must reach a new equilibrium between the vapor and liquid phases before the vapor pressure returns to the original equilibrium value.

D. Removing vapor will cause a temporary increase in the rate of condensation: When the vapor is removed from the system, the total vapor pressure decreases, and the rate of condensation of the liquid phase will increase until the system re-equilibrates.

Statement C. when equilibrium is re-established after a disturbance in a liquid-gas system, the vapor pressure will be the same: is incorrect. When a system is disturbed by adding or removing vapor, the new equilibrium vapor pressure is different from the original equilibrium vapor pressure.

Therefore, the correct statements for the vapor pressure of the system are A, B, and D.

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A sense strand is the mRNA strand that is translated from a DNA strand with a same nucleotide sequence. the codons have specific functions when the mRNA sequence is translated into a protein.

The DNA sequence serves as a template for the synthesis of a complementary mRNA molecule during transcription. The nucleotide arrangement of the DNA template strand dictates the sequencing of the mRNA. The mRNA sequence is not identical to the template DNA strand; rather, it is complementary to it. RNA polymerase, which builds the mRNA molecule on the DNA template strand, adds complementary RNA nucleotides to the lengthening mRNA chain. Since RNA nucleotides have uracil (U) as a base instead of thymine (T), the mRNA sequence will have the same nucleotide sequence as the DNA template strand. The mRNA sequence is read in groups of three nucleotides called codons, and the codons have specific functions when the mRNA sequence is translated into a protein.

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MnO4- acts as an oxidizing agent, whereas SO2 acts as a reducing agent.

An oxidizing agent is a chemical species that causes oxidation in another substance by receiving electrons from it. To put it another way, it is a chemical that makes it easier for electrons to move from the object being oxidized to itself.

When an oxidation occurs, electrons are lost or the oxidation state is increased; when a reduction occurs, electrons are gained or the oxidation state is decreased.

In this equation, MnO4- + SO2 + H2O → Mn2+ + SO42- + 2H+

Because it causes SO2 to undergo oxidation (i.e., lose electrons) and goes through reduction itself, MnO4- is the oxidizing agent in this equation (i.e., gains electrons).

Due of its ability to both reduce MnO4- and oxidize itself, SO2 is the reducing agent.

Mn2+ is not an oxidizing agent because it is the end result of the reduction of MnO4-.

As SO42- is a byproduct of SO2 oxidation, it cannot act as a reducing agent.

MnO4- is therefore the oxidizing agent, whereas SO2 is the reducing agent.

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The Lewis dot structures for the polyatomic ions NH₄⁺, PO₄³⁻, NO₃⁻, CO₃²⁻ as well as the electron dot structures of the CH₂F₂ and OF₂ are shown in the attachment.

Lewis dot structures or electron dot structures are diagrams that show the bonding between atoms in a molecule and the lone pairs of electrons that may exist in the molecule.

In these structures, the symbol of each element represents its atomic nucleus and inner-shell electrons, while dots or lines surrounding the symbol represent valence electrons that participate in bonding. The structures allow us to predict the number and type of bonds in a molecule and its shape, as well as to understand its chemical reactivity.

The shape and bond angles of the molecules CH₂F₂ and OF₂ can be determined using VSEPR theory:

CH₂F₂:

The central atom, carbon (C), has four electron groups (two single bonds to hydrogen and two single bonds to fluorine).

The electron geometry is tetrahedral, and the molecular geometry is also tetrahedral.

The bond angles are approximately 109.5 degrees.

OF₂:

The central atom, oxygen (O), has two electron groups (one double bond to fluorine and two lone pairs of electrons).

The electron geometry is tetrahedral, and the molecular geometry is bent.

The bond angle is approximately 103 degrees.

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The Robinson annulation is a reaction that involves the conjugate addition of a stabilized carbanion to an alpha,beta-unsaturated ketone, followed by intramolecular aldol condensation.

The Robinson annulation reactions are in the image attached below

The reaction proceeds in two steps: in the first step, the carbanion attacks the electrophilic carbon of the alpha,beta-unsaturated ketone, forming a new carbon-carbon bond. In the second step, the newly formed double bond acts as a nucleophile and attacks the carbonyl group of the same molecule, leading to the formation of a cyclic product. The Robinson annulation is a powerful method for the synthesis of cyclic compounds, particularly those containing a six-membered ring with an alpha,beta-unsaturated ketone as a key intermediate.

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Complete question:

Draw the product obtained by heating each pair of ketones in a basic solution.

The figure is in the image attached below

To eject electrons with 2.2 x 10^-19 J of energy is 1.42 x 10^15 Hz.

what is the photon frequency needed? Chromium metal has a binding energy of 7.21 x 10^-19 J for certain electrons. So, the energy needed to eject the electrons is: Energy needed = Binding energy + Ejected electrons' energy = 7.21 x 10^-19 J + 2.2 x 10^-19 J = 9.41 x 10^-19 JNow, we know the energy needed to eject electrons is 9.41 x 10^-19 J. And we know that the energy of a photon is given by E = hν, where h is Planck's constant and ν is the frequency of the photon. To find the photon frequency needed, we can use the equation:

E = hνν = E/hν = (9.41 x 10^-19 J) / (6.63 x 10^-34 J·s)ν = 1.42 x 10^15 Hz

Hence, the photon frequency needed to eject electrons with 2.2 x 10^-19 J of energy is 1.42 x 10^15 Hz.

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Answer:

True. The limiting reagent is the reactant that is completely consumed in a chemical reaction and limits the amount of product that can be formed. The theoretical yield is the maximum amount of product that can be obtained from the limiting reagent, assuming that the reaction goes to completion and no side reactions occur. However, in practice, it is common for side reactions to occur, which can reduce the actual yield of the product. Therefore, while the limiting reagent does control the theoretical yield of a reaction, the actual yield may vary due to the presence of side reactions or other factors that can affect the efficiency of the reaction.

Explanation:

When reactants are mixed and heated and liquid collects in the sidearm of the apparatus, the process is known as condensation. This process occurs due to the conversion of a gas or vapor to a liquid state.

The process of condensation occurs as heat is lost from a vapor, which causes it to change its state from a gas to a liquid. When the vapor loses its heat and cools, the molecules slow down and come closer together, reducing the space between them, which causes them to stick together and form a liquid state. This liquid is then collected in the sidearm of the apparatus.

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Inner transition elements have the last electron added into the f-orbital. Thus, the correct option will be C.

An f-orbital is a central region of high electron probability density in an atom that may contain up to two electrons, depending on the energy and spin of the electrons. It has a more complex shape than s, p, and d orbitals.

In atoms, the f-orbital's quantum number is l = 3. It has seven orbitals in total. The 4f subshell includes the first six f-orbitals which are 4f, 4f1, 4f2, 4f3, 4f4, 4f5, while the 5f subshell includes the final seventh f-orbital (5f6). The electron configuration for an element or atom is determined by the number of electrons in each orbital.

The outermost electrons of a chemical element or atom are referred to as valence electrons. The number of valence electrons in an atom or element can be used to forecast the molecule's reactivity and the types of chemical bonds it can form.

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The molar mass of 2.000 moles of carbon is 24.02 g/mol.

Molar mass is the total mass in grams of all the atoms in one mole of a substance. The unit of molar mass is grams per mole (g/mol).

The molar mass of carbon is 12.01 g/mol.

The formula for molar mass calculation is as follows:

Molar mass = Mass of substance ÷ Amount of substance

Molar mass can also be calculated using the periodic table of elements.

To calculate the molar mass of 2.000 moles of carbon, you can use the following formula:

mass = moles x molar mass

mass = 2.000 mol x 12.01 g/mol

mass = 24.02 g

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The molarity of the diluted solution is 0.2618 M.

The molarity of the diluted solution can be calculated using the formula:

  M₁V₁ = M₂V₂,

where M₁ is the initial molarity, V₁ is the initial volume, M₂ is the new molarity, and V₂ is the new volume.

In this case:

Plug these numbers into the formula to calculate the molarity of the diluted solution (M₂):

  M₁V₁ = M₂V₂,

  1.2 * 120 = M₂ * 550

  M₂ = 0.26181...

  M₂ = 0.2618 M (rounded to four significant figures).

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Option A is correct in this case that no reaction occurs between sodium chloride and acetic acid when mixed because acetic acid is a very weak acid, and it is unable to shift the ions of the salt.

Comparatively, the molecular equation provides information on the ionic molecules that served as the reaction's ion sources whereas the entire ionic equation provides information on all of the ions that were in solution during the reaction.

Even at greater temperatures, there is little probability that acetic acid and table salt will react in any way. Acetic acid is a relatively weak acid, while sodium chloride is a salt of hydrochloric acid, a strong acid. In most cases, a weaker acid does not displace a stronger acid from the salt of the latter.

Hence, when you combine acetic acid with sodium chloride, you only obtain a uniform, transparent combination. Equilibrium is shifted to the left side of the reaction as follows:

Na⁺Cl⁻ + CH₃COOH ⇄ H⁺Cl⁻ + CH₃COO⁻Na⁺

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Correct question is:

Select the net ionic equation for the reaction that occurs when sodium chloride and acetic acid are mixed.

(Refer the image for the correct options)

The portion of the titration curve of a strong base with a strong acid is the same as the region before the endpoint is reached for a weak base titrated with a strong acid. The correct answer is Option C.

Titration refers to the process of measuring the volume of one solution required to react with a given volume of another solution completely. The titration curve is a graph that shows the change in pH during a titration.

The pH changes quickly from acidic to basic as the volume of strong base added approaches the stoichiometric point. It can be observed that the pH of the strong base solution is high, but as it is titrated with an acid, its pH decreases. The graph gradually falls as the acid is added, finally reaching a sharp rise known as the equivalence point or endpoint. As a result, the correct option is c. the portion before the endpoint is reached.

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Answer: False

Explanation:

Answer : The equilibrium constant for various solutions are - Solution 2: Kc = (1.549 x 10^-10) / (1.MNO-2.Baapea x 10^-38.5) = 1.549 x 10^28 , Solution 4: Kc = 55.0 and Solution 6: Kc = (7.17 x 10^-10) / (7.47 x 10^-20.2) = 9.536 x 10^9.9

The equilibrium constant (Kc) is a thermodynamic quantity that can be determined from the concentrations of products and reactants in a chemical reaction at equilibrium. To calculate the equilibrium constant for solutions 2, 4, and 6, we use the following equation: Kc = [Products]/[Reactants].

The average value for the equilibrium constant is calculated by taking the sum of the equilibrium constants and dividing by the number of solutions (in this case 3). Thus, the average equilibrium constant is 34.거 ~ 40.

The percent relative mean deviation (RMD) is used to measure the accuracy of the equilibrium constants and is calculated by taking the mean of the equilibrium constants, subtracting each value, and dividing by the mean, multiplied by 100. Thus, the RMD for this set of equilibrium constants is 6.4%.

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Answer:

a)Electron domain geometry around nitrogen-1 is tetrahedral

b)Hybridization around carbon-1 is sp2

c)The ideal bond angles around oxygen-1 are 120 degrees.

d)Hybrid orbitals overlapping to form the sigma bond between oxygen-1 and nitrogen-2 is sp2 hybrid orbitals from carbon-1 and nitrogen-2

e)There are no pi bonds in the molecule.

Explanation:

a) Electron domain geometry around nitrogen-1 is tetrahedral.The molecular structure of linuron is as follows: There are three carbon atoms in a row. The terminal carbon atom is linked to a methyl group and a chlorine atom. The carbon atom next to it is linked to the nitrogen atom in the herbicide. The third carbon atom is linked to two oxygen atoms, with one of them being a hydroxyl group.

b) Hybridization around carbon-1 is sp2.The carbon atom adjacent to the nitrogen atom is known as carbon-1. This carbon atom is joined to three other atoms. It has an sp2 hybridization since it has three regions of electron density.

c) The ideal bond angles around oxygen-1 are 120 degrees.Bond angles are the angles between two adjacent lines in a Lewis structure. Because oxygen-1 is linked to two other atoms, it has a bent geometry. Its ideal bond angle is 120 degrees.

d) Hybrid orbitals overlapping to form the sigma bond between oxygen-1 and nitrogen-2 is sp2 hybrid orbitals from carbon-1 and nitrogen-2.The sigma bond is the strongest type of covalent bond. Sigma bonds are created when the overlapping orbitals are arranged in a straight line. The sigma bond between oxygen-1 and nitrogen-2 is formed by the overlap of sp2 hybrid orbitals from carbon-1 and nitrogen-2.

e) There are no pi bonds in the molecule.There are no pi bonds in the molecule because all of the bonds are sigma bonds. The molecule consists of single bonds only.

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Milk is an example of a colloid (option B).

A colloid is an intimate mixture of two substances, one of which, called the dispersed phase.

A colloid is uniformly distributed in a finely divided state throughout the second substance, called the dispersion medium (or dispersing medium).

Milk is an example of a colloidal solution, where fat is the phase and water is the medium.

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Triethylamine is a weak base and an excellent nucleophile, that is, it is very reactive to electrophilic molecules such as alkyl halides. Triethylamine is a commonly used reagent in organic synthesis to promote alkylations, acylations, and nucleophilic substitutions.Therefore, the order of increasing rate of reaction with triethylamine is as follows: Iodoethane< 1-Bromopropane< 2-Bromopropane

As we know, the rate of a reaction with the nucleophile depends on the strength of the electrophilic carbon atom, which is in turn dependent on the bond dissociation energy of the C-X bond. The lower the bond dissociation energy, the easier it is to break the bond and the more reactive the alkyl halide is towards nucleophiles.

On the other hand, 2-Bromopropane, with the highest bond dissociation energy of C-Br bond, is the least reactive towards nucleophiles Therefore, the order of increasing rate of reaction with triethylamine is as follows: Iodoethane< 1-Bromopropane< 2-Bromopropane.

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Phosphorus pentachloride decomposes to phosphorus trichloride and chlorine gas at elevated temperatures by the following reaction:

PCl5(g) PCl3(g) + Cl2(g).

If Kc = 1.8 at 250°C, the value of Kp at the same temperature is given as follows. The correct option is 65. (Option D)

Kc = {PCl3 * Cl2} / {PCl5}

At equilibrium;Kp = {PCl3} * {Cl2} / {PCl5}

Since the stoichiometry of the given chemical equation is 1:1:1, Kp = Kc. Kp = 1.8 at 250°C. Therefore the answer is 65

.According to the above data, the calculation of the value of Kp at the same temperature is as follows;

Kc = {PCl3 * Cl2} / {PCl5}1.8 = {PCl3 * Cl2} / {PCl5} (At 250°C)

Kp = {PCl3} * {Cl2} / {PCl5} (At 250°C)

Kp = KcKp = 1.8

Therefore, the correct answer is option D, which is 65.

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