Draw the Lewis structure of phosgene, COCl2, which was used as a chemical weapon during World War I.
Select the correct answer below:
a) A Lewis structure contains one C atom, one O atom, and two C l atoms. The C atom is in the middle. It is single-bonded to each of the two Cl atoms and double-bonded to the O atom. Each of the C l atoms has three lone pairs of electrons, and the O atom has two lone pairs.
b) A central C has 2 single bonded C l atoms to the left and a single-bonded O to the right. The 2 C l atoms show 3 lone electron pairs. The O shows 3 lone electron pairs.
c) Two C l atoms are single bonded to a central C. An O atom is double bonded to the C. There are three lone pairs of electrons on each C l atom. There are three lone pairs of electrons on the O atom.

The percent yield for the reaction is  99.79%.

The balanced equation for the reaction is:

C₃H₆ + HNO → C₃H₃N + H₂O

We need to find the theoretical yield of C₃H₃N first:

1 mole of C₃H₆ produces 1 mole of C₃H₃N

Moles of C₃H₆ = 180 g / 42.09 g/mol = 4.28 mol

Moles of C₃H₃N = 105 g / 53.07 g/mol = 1.98 mol

Therefore, C₃H₃N is the limiting reactant, and the theoretical yield is 1.98 mol.

To calculate the percent yield, we need to divide the actual yield by the theoretical yield and multiply by 100:

Percent yield = (actual yield / theoretical yield) x 100

Actual yield = 105 g

Theoretical yield = 1.98 mol x 53.07 g/mol = 105.22 g

Percent yield = (105 g / 105.22 g) x 100 = 99.79%

Therefore, the percent yield of the reaction is approximately 99.79%.

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The particle’s position determines the potential energy available to a system because this potential energy depends on the height of the particle and therefore it alters the ability to perform work.

The importance of the height of particles in potential energy is major since it determined the amount of saved energy that can be used to perform work when required.

Therefore, with this data, we can see that  the height of particles increases the amount of potential energy to make the work.

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Minerals are distributed unevenly across Earth's surface.

The distribution of minerals on Earth's surface is influenced by a variety of factors, including geological processes, the history of the Earth's formation, and the movement of tectonic plates. As a result, minerals are not distributed evenly across the planet.

Certain regions of the Earth, such as areas with active volcanoes or those that have experienced geological events like mountain-building, may have higher concentrations of certain minerals than other regions. In addition, some minerals may be more abundant in certain types of rocks or geological formations.

Moreover, the accessibility and availability of minerals can also vary widely depending on factors like economic and political conditions, as well as environmental regulations. These factors can impact the profitability and viability of mining operations in different regions of the world.

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ΔH° for the reaction 2Al + Fe2O3⟶ 2Fe + Al2O3 is (c) -202.6 kcal.

To calculate the standard heat of a reaction, use Hess's law, which states that the heat of a reaction is independent of the pathway taken to get from the reactants to the products.

In other words, the heat of the formation of the products and subtract from the heat of the formation of the reactants to obtain the heat of the reaction.

The balanced equation for the given reaction is:

2Al + Fe2O3 ⟶ 2Fe + Al2O3

The heat of the formation of a compound is defined as the enthalpy change when one mole of the compound is formed from its elements in their standard states at a pressure of 1 atm and a specified temperature (usually 25°C).

Using the given standard heat enthalpies of formation,ΔH° = ΣnΔH°f(products) - ΣnΔH°f(reactants), where Σn means the sum of the products or reactants, each multiplied by its stoichiometric coefficient.

For this reaction, the heat of the reaction is:

ΔH° = [2ΔH°f(Fe) + ΔH°f(Al2O3)] - [2ΔH°f(Al) + ΔH°f(Fe2O3)]

ΔH° = [2(0) + (-399.1 kcal/mol)] - [2(0) + (-196.5 kcal/mol)]

ΔH° = -399.1 kcal/mol + 196.5 kcal/mol

ΔH° = -202.6 kcal/mol

Therefore, the answer is (c) -202.6 kcal.

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The 14 µM standard solution, you'll need approximately 4 mL of the 35 µM stock solution.

To create a 14 µM standard solution from a 35 µM stock solution using a 10 mL volumetric flask and 1 mL and 5 mL volumetric pipets, you'll need to determine the appropriate volume of the stock solution to dilute. To do this, you can use the dilution equation:

C1V1 = C2V2

Where C1 is the concentration of the stock solution (35 µM), V1 is the volume of the stock solution needed, C2 is the desired concentration of the diluted solution (14 µM), and V2 is the final volume of the diluted solution (10 mL).

Rearrange the equation to solve for V1:

V1 = (C2V2) / C1

Plug in the values:

V1 = (14 µM × 10 mL) / 35 µM

V1 ≈ 4 mL

To create the 14 µM standard solution, you'll need approximately 4 mL of the 35 µM stock solution. Use the 5 mL volumetric pipet to measure 4 mL of the stock solution, transfer it to the 10 mL volumetric flask, and then add distilled water up to the 10 mL mark to achieve the desired 14 µM concentration. Transfer the prepared solution to a labeled beaker.

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The difference in color between the hexa aqua complex [Ni(H2O)6]2+ and the hexa ammonia complex [Ni(NH3)6]2+ can be attributed to the different arrangements of the ligands and resulting energy-level splitting of the nickel ion's d orbitals.

The color of transition metal complexes is determined by the arrangement of electrons in the metal ion's d orbitals. In an octahedral complex such as [Ni(H2O)6]2+, the d-orbitals of the nickel ion are split into two energy levels due to the presence of the six ligands.

The energy difference between these two levels corresponds to the wavelength of light absorbed by the complex, which determines its color.

In the case of [Ni(H2O)6]2+, the complex appears green because it absorbs light in the red part of the spectrum. This is due to the arrangement of the electrons in the d orbitals of the nickel ion, which results in the absorption of light with a wavelength of approximately 500-600 nm.

In contrast, the hexaammonia complex [Ni(NH3)6]2+ appears violet because it absorbs light in the yellow-green part of the spectrum. This is due to the fact that ammonia is a stronger field ligand than water, which causes a greater splitting of the nickel ion's d orbitals.

As a result, the energy difference between the two levels increases, and the complex absorbs light with a longer wavelength (approximately 400-500 nm) in the violet part of the spectrum.

Therefore, the difference in color between the hexa aqua complex [Ni(H2O)6]2+ and the hexa ammonia complex [Ni(NH3)6]2+ can be attributed to the different arrangements of the ligands and resulting energy-level splitting of the nickel ion's d orbitals.

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The equilibrium constants for the ionization of the two amino groups in proline are [tex]Kb1 = 7.41 x 10^-13 and Kb2 = 1.33 x 10^-5.[/tex]

The equilibrium constants Kbi and Kb2 represent the ionization of the two amino groups (NH2) in proline, which can be represented by the following chemical reactions:

NH₂-CH(CH₂)₂-COOH + H₂O ⇌ NH₃+ -CH(CH₂)₂-COOH + OH-    (Kb1)

NH₃+ -CH(CH₂)₂-COOH + H₂O ⇌ NH₃+ -CH(CH₂)₂-COO- + H3O+  (Kb2)

To find the values of Kb1 and Kb2, we can use the relationship between Kb and Ka (acid dissociation constant):

Kw = Ka x Kb

where Kw is the ion product constant for water (1.0 x 10^-14 at 25°C).

From this relationship, we can find Kb1 and Kb2 as follows:

Kb1 = Kw / Ka1

Kb2 = Kw / Ka2

where Ka1 and Ka2 are the acid dissociation constants for the two acidic groups in proline.

For proline, the acid dissociation constants are as follows:

Ka1 =[tex]1.35 x 10^-2[/tex]

Ka2 = [tex]7.5 x 10^-10[/tex]

Using these values, we can calculate Kb1 and Kb2:

Kb1 = Kw / Ka1 = [tex](1.0 x 10^-14) / (1.35 x 10^-2) = 7.41 x 10^-13[/tex]

Kb2 = Kw / Ka2 =[tex](1.0 x 10^-14) / (7.5 x 10^-10) = 1.33 x 10^-5[/tex]

Therefore, the equilibrium constants for the ionization of the two amino groups in proline are Kb1 = [tex]7.41 x 10^-13[/tex] and Kb2 =[tex]1.33 x 10^-5.[/tex]

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If a sample has a melting point of 133 - 137°C, it can option A: be a mixture of compounds, or option B: contains impurities.

It is probably a mixture of compounds: A sample that has a limited melting point range, such as 133-137'C, may contain several different chemicals. A pure compound usually has a single sharp melting point or a smaller range of melting points.

It might have impurities: Impurities can cause a sample's melting point to decrease and its melting point range to increase.

The melting point was measured all at once: The limited range, however, indicates that the melting point was measured precisely and thoroughly, indicating that the sample is probably pure or only includes a few impurities.

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Complete question is:

A solid sample has an MP of 133 - 137'C. What can one conclude about the sample? (multiple answers are possible)

It has mixture of compounds

The sample contains impurity

Melting point was taken at two different time

The pure compound may have multiple melting point

a. A book sitting on a shelf: Contact forces: None. Non-contact forces: Gravity, which pulls the book downwards, and the normal force from the shelf, which pushes upwards on the book to counteract gravity and keep it in place.

b. A soccer player kicking a ball; the ball soaring through the air and landing on the ground:

Contact forces: The player's foot applies a force to the ball, which propels it forward. When the ball hits the ground, there is a contact force between the ball and the ground.

Non-contact forces: Air resistance, which opposes the motion of the ball through the air.

C. A hiker in the woods reading her compass to determine which direction to go:

Contact forces: None. Non-contact forces: The Earth's magnetic field, which interacts with the compass needle to indicate the direction of magnetic north.

d. A child on a sled; first, the child is sitting at the top of the hill, waiting his turn; then, the child pushes off and slides down the hill, eventually coming to a stop:

Contact forces: Friction between the sled and the ground provides the force that propels the sled forward and eventually brings it to a stop.

Non-contact forces: Gravity provides the force that pulls the sled down the hill. Air resistance also acts on the sled as it slides down the hill.

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Acetic acid and isopropyl alcohol are soluble in water due to the presence of polar functional groups in their molecular structures, allowing them to form hydrogen bonds with water molecules. In contrast, nonpolar molecules like Freon-12 and vinyl chloride are not soluble in water.

Acetic acid and isopropyl alcohol are both water-soluble due to the presence of polar functional groups in their molecular structures. Acetic acid has a carboxylic acid functional group (-COOH) which is polar and readily forms hydrogen bonds with water molecules. Isopropyl alcohol has a hydroxyl functional group (-OH) which is also polar and forms hydrogen bonds with water molecules. These hydrogen bonds between the polar functional groups in the molecules of acetic acid and isopropyl alcohol and the water molecules allow for their solubility in water.

On the other hand, Freon-12 and vinyl chloride are not water-soluble because they are nonpolar molecules. Nonpolar molecules do not have polar functional groups and do not readily form hydrogen bonds with water molecules. Therefore, they are not soluble in water.

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To minimize the formation of a mixture of possible products when using cross or mixed aldol reagents, careful selection of the aldehyde and ketone is important. Ideally, the aldehyde and ketone should have similar reactivity and should not have multiple reactive sites.

Additionally, controlling the reaction conditions such as temperature, solvent, and catalyst can also help to minimize the formation of unwanted products. Finally, purification techniques such as column chromatography or recrystallization can be used to isolate the desired product and separate it from any remaining impurities.

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Hydrogen-bonding, Dispersion forces, Dipol-dipole interaction intermolecular forces act between an oxide anion and a nitrogen trichloride molecule.

Intermolecular forces (or IMFs) are the forces that exist between molecules. They are weaker than the intramolecular forces that hold the atoms of a molecule together, but are still strong enough to affect the physical and chemical properties of a substance. IMFs can be divided into three categories: Van der Waals forces, dipole-dipole interactions, and hydrogen bonding. Van der Waals forces are non-covalent interactions between molecules which arise due to the electrostatic attractions and repulsions between neutral molecules with an uneven distribution of electrons. Dipole-dipole interactions are created when two molecules with permanent dipoles interact, and are stronger than Van der Waals forces. Hydrogen bonding is a special type of dipole-dipole interaction that occurs when one molecule has a hydrogen atom covalently bonded to a nitrogen, oxygen, or fluorine atom, and the other molecule has a lone pair of electrons. Hydrogen bonding is the strongest IMF, and is the basis for the structure of many biomolecules such as DNA and proteins.

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The pH ranges and colors of some common acid-base indicators are:

Phenolphthalein: pH range 8.2-10, colorless (acidic) to pink (basic)

Bromothymol blue: pH range 6.0-7.6, yellow (acidic) to blue (basic)

Methyl orange: pH range 3.1-4.4, red (acidic) to yellow (basic)

Litmus: pH range 5.0-8.0, red (acidic) to blue (basic)

Thymol blue: pH range 1.2-2.8 (yellow) and 8.0-9.6 (blue)

The choice of indicator depends on the type of acid-base titration being performed. In general, the indicator should have a pH range that is close to the pH at the equivalence point of the titration, which is the point at which the moles of acid and base are equal.

For example, in the titration of a strong acid with a strong base, the equivalence point is at a pH of 7 (neutral). Phenolphthalein is a suitable indicator in this case because its pH range is slightly above 7, and it changes color from colorless (acidic) to pink (basic) in this pH range.

However, if the acid or base being titrated is weak, the equivalence point will occur at a different pH than 7. In this case, a different indicator with a pH range closer to the equivalence point may be more suitable.

For example, if acetic acid is titrated with sodium hydroxide, the equivalence point occurs at a pH of about 8.2, which is in the pH range of phenolphthalein. However, methyl orange has a pH range that is closer to the equivalence point, making it a better choice for this titration.

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There were 0.000871 moles of the diprotic acid present in the sample. It is important to note that without additional information, we cannot determine the identity of the diprotic acid present in the sample.

In order to determine the number of moles of the diprotic acid present in the sample, we need to first calculate the number of moles of NaOH that were required to neutralize the sample.

The balanced chemical equation for the reaction between NaOH and a diprotic acid is:

[tex]\mathrm{H_2A} + 2\mathrm{NaOH} \rightarrow \mathrm{Na_2A} + 2\mathrm{H_2O}[/tex]

From this equation, we can see that two moles of NaOH are required to react with one mole of the diprotic acid, [tex]H_2A[/tex]. Therefore, if 0.001742 moles of NaOH were required to neutralize the sample, we can calculate the number of moles of [tex]H_2A[/tex] the present as follows:

[tex]0.001742 \ \mathrm{mol \ NaOH} \times \dfrac{1 \ \mathrm{mol \ H_2A}}{2 \ \mathrm{mol \ NaOH}} = 0.000871 \ \mathrm{mol \ H_2A}[/tex]

Further analysis, such as titration with a different reagent or spectroscopic analysis, may be necessary to determine the identity of the acid.

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The de Broglie wavelength will have the shortest wavelength when traveling at 30 cm/s for  the answer (e) hydrogen atom

de Broglie wavelength of a particle is given by the equation:

λ = h / p

where λ is the de Broglie wavelength, h is Planck's constant, and p is the momentum of the particle.

The momentum of a particle is given by the equation:

p = mv

where m is the mass of the particle and v is its velocity.

Thus, the de Broglie wavelength depends on both the mass and velocity of the particle.

For a given velocity of 30 cm/s, the de Broglie wavelength will be shortest for the particle with the smallest mass.

Out of the given options, the hydrogen atom has the smallest mass, followed by the uranium atom, the planet, the car, and the marble. Therefore, the de Broglie wavelength of a hydrogen atom traveling at 30 cm/s will have the shortest wavelength.

So, the answer is (e) hydrogen atom.

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Answer:

Yes it’s true

Explanation:

C2H6O is the chemical formula for ethanol. carbon atoms, six moles of hydrogen atoms, and one mole of oxygen atoms.

The order of increasing acidity is: Atlantic Ocean, Rivers & Lakes, Vinegar, Stomach Acid.

The Atlantic Ocean has a pH of around 8.1, which means it has a low hydrogen ion concentration (H+). Rivers & Lakes have a pH ranging from 6.0 to 8.5, which means they have a slightly higher H+ concentration than the Atlantic Ocean. Vinegar has a pH of around 2.5, which means it has a high H+ concentration. Stomach acid has a pH of around 1.5-3.5, which means it has the highest H+ concentration among the given options. It's important to note that acidity is measured on the pH scale, which ranges from 0 to 14. A pH of 7 is considered neutral, while pH values less than 7 indicate acidity and pH values greater than 7 indicate alkalinity.

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The theoretical yield of lithium chloride produced from 20 grams of lithium hydroxide is 35.373 grams.

The balanced chemical equation for the reaction between lithium hydroxide (LiOH) and potassium chloride (KCl) is:

LiOH + KCl → LiCl + KOH

The stoichiometry of the reaction shows that one mole of lithium hydroxide reacts with one mole of potassium chloride to form one mole of lithium chloride and one mole of potassium hydroxide.

The molar mass of lithium hydroxide (LiOH) is:

1 x 6.941 (molar mass of Li) + 1 x 15.9994 (molar mass of O) + 1 x 1.0079 (molar mass of H) = 23.9483 g/mol

Using the molar mass and the given mass of lithium hydroxide, we can calculate the number of moles of lithium hydroxide:

20 g LiOH / 23.9483 g/mol = 0.835 moles LiOH

Since the reaction between lithium hydroxide and potassium chloride is a 1:1 stoichiometric ratio, the number of moles of lithium chloride produced will be the same as the number of moles of lithium hydroxide used:

0.835 moles LiCl

The molar mass of lithium chloride (LiCl) is:

1 x 6.941 (molar mass of Li) + 1 x 35.45 (molar mass of Cl) = 42.391 g/mol

Therefore, the theoretical yield of lithium chloride in grams is:

0.835 moles LiCl x 42.391 g/mol = 35.373 g LiCl

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The Henderson-Hasselbalch equation is a mathematical expression used to calculate the pH of a buffer solution. The equation is derived from the acid dissociation constant (Ka) of a weak acid and its conjugate base.

The equation is named after Lawrence Joseph Henderson and Karl Albert Hasselbalch, who developed it independently in the early 20th century. The Henderson-Hasselbalch equation states that the pH of a buffer solution can be calculated using the following formula:

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

Where pH is the measure of the acidity or basicity of a solution, pKa is the negative logarithm of the acid dissociation constant, [A-] is the concentration of the conjugate base, and [HA] is the concentration of the weak acid.

The equation is useful in determining the pH of a buffer solution, which is a solution that resists changes in pH when small amounts of acid or base are added. Buffers are important in biological systems, where maintaining a constant pH is essential for proper functioning.

Overall, the Henderson-Hasselbalch equation is a fundamental tool in chemistry and biochemistry for understanding acid-base equilibrium and buffer solutions.

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The intermolecular forces between an ammonia molecule and a hydrogen fluoride molecule are dipole-dipole forces and hydrogen bonding.

An ammonia molecule ([tex]NH_3[/tex]) and a hydrogen fluoride molecule (HF) are polar molecules with different electronegativities of their constituent atoms. Thus, the intermolecular forces that exist between them are dipole-dipole forces and hydrogen bonding.

Dipole-dipole forces arise due to the unequal sharing of electrons between the atoms in a polar covalent bond. In the case of [tex]NH_3[/tex] and HF, both molecules have polar covalent bonds, which create a positive and negative end in each molecule. As a result, the positive end of the [tex]NH_3[/tex] molecule interacts with the negative end of the HF molecule through dipole-dipole forces.

Moreover, both [tex]NH_3[/tex] and HF have hydrogen atoms bonded to highly electronegative atoms (N and F, respectively), which allows for hydrogen bonding to occur. Hydrogen bonding is a strong intermolecular force that occurs when a hydrogen atom covalently bonded to an electronegative atom (N, O, or F) in one molecule interacts with a lone pair of electrons on an electronegative atom in another molecule.

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Based on the given arterial blood gas measurement of pH 7.5, pCO2 40 mm Hg, and HCO3 34 mmol/L, the acid-base disorder shown is metabolic alkalosis.

In this scenario, the patient is suffering from gastroenteritis and dehydration, which can cause an imbalance in the body's electrolyte levels, including bicarbonate, and contribute to the development of metabolic alkalosis. The persistent vomiting has likely resulted in the loss of hydrogen ions and chloride ions, which are important components of stomach acid. This loss of acid can lead to an increase in bicarbonate levels and metabolic alkalosis.

The patient's dry mucus membranes and prolonged capillary refill time are also consistent with dehydration, which can further exacerbate the metabolic alkalosis.

Treatment of this patient's condition would involve rehydration with fluids to address the underlying dehydration and restore electrolyte balance. Correction of the metabolic alkalosis may also be necessary, depending on the severity and duration of the condition. In severe cases, intravenous bicarbonate may need to be administered to lower the HCO3 levels. It is important to address both the underlying cause of the metabolic alkalosis and the dehydration to prevent complications and restore acid-base balance in the body.

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Here is the structure of Compound A (pentane):

    H H H H H
     |   |   |   |   |
H--C-C-C-C-C--H
     |   |   |   |   |
    H H H H H

There are two types of C-H bonds in cyclopentene:

The C-H bond on the alkene carbon and the C-H bond on the saturated carbon.

The C-H bond on the saturated carbon is weaker <<< than the C-H bond on the alkene carbon.

Compound A has the molecular formula C5H12, which indicates that it is pentane, a linear alkane. When pentane undergoes monochlorination, it can produce four different constitutional isomers:

1. Chloromethane on the first carbon
2. Chloroethane on the second carbon
3. Chloropropane on the third carbon
4. Chlorobutane on the fourth carbon

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The correct order of events as equilibrium is reached is as follows, dissociation of salt into its cations and anions, hydration of cations and anions may occur simultaneously, rate of dissolution is equal to the rate of recrystallization, dissolved cations and anions begin to deposit as a solid salt.

The first event to occur is the dissociation of the salt into its cations and anions, which happens when the salt is added to water. This is followed by the hydration of the cations and anions, which is the process of water molecules surrounding and stabilizing the individual ions. At this point, the rate of dissolution is equal to the rate of recrystallization, meaning that the amount of salt dissolving in water is equal to the amount of salt that is reforming into solid particles.

This state is called dynamic equilibrium. Finally, the dissolved cations and anions begin to deposit as a solid salt, which is the process of recrystallization. This occurs when the concentration of the dissolved ions becomes too high for the water to support, and they begin to come together to form solid particles. Overall, the order of events in the attainment of equilibrium in this scenario is dissociation, hydration, dynamic equilibrium, and recrystallization.

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The number of moles of the KCl is  2.1 moles.

We know that the boling point of the solution is a colligative property and the the Vant Hoff factor of the solution in this case would be btwo because of the number of the particles that are in KCl.

We know that we can be able to use the formula;

ΔT = K m i

Given that

ΔT = 2.14°C

K = 0.512oC/m

i = 2

m = ?

Then we have that;

m = ΔT/Ki

m = 2.14/0.512 * 2

m = 2.1 m

Then

m = Moles of solute/Mass of solution

2.1 = m/1

m = 2.1 moles

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The empirical formula is [tex]Br_{2}I[/tex]. The percent composition of bromine is (319.6 / 206.8) x 100 = 154.5% and the percent composition of iodine is (253.8 / 206.8) x 100 = 122.7%. The formula of the hydrate is [tex]Al_{2}(SO_{4})3.18H_{2}O[/tex].

For the first problem, to find the empirical formula, we need to determine the moles of each element present.

From the given masses, we can calculate that there are 0.067 moles of bromine and 0.034 moles of iodine.

To get the simplest whole number ratio of the atoms in the compound, we divide each number of moles by the smallest one (0.034), which gives us a ratio of 2:1. Therefore, the empirical formula is [tex]Br_{2}I[/tex].

To find the molecular formula, we need to know the molar mass of the compound. From the given information, we know it is 206.8 g/mol. The empirical formula mass of [tex]Br_{2}I[/tex] is 321.7 g/mol.

To get from the empirical formula mass to the molecular formula mass, we need to multiply by a whole number factor. This factor is found by dividing the molecular formula mass by the empirical formula mass, which gives us 0.641.

We then multiply each subscript in the empirical formula by this factor to get the molecular formula: [tex]Br_{4}I_{2}[/tex].

To find the percent composition, we need to calculate the mass of each element in the compound and divide it by the total mass of the compound, then multiply by 100.

The mass of bromine in [tex]Br_{4}I_{2}[/tex] is 4 x 79.9 g/mol = 319.6 g/mol. The mass of iodine is 2 x 126.9 g/mol = 253.8 g/mol. The total mass of the compound is 206.8 g/mol.

Therefore, the percent composition of bromine is (319.6 / 206.8) x 100 = 154.5% and the percent composition of iodine is (253.8 / 206.8) x 100 = 122.7%. These values are greater than 100% because they were calculated using an incorrect empirical formula.

For the second problem, we can use the information provided to calculate the mass of water in the hydrate. The difference in mass between the hydrate and the anhydrous salt is 0.89 g.

This mass represents the water that was lost upon heating. To calculate the number of moles of water, we divide by the molar mass of water (18.02 g/mol), which gives us 0.0494 moles.

The formula of the hydrate can be determined by dividing the number of moles of each element by the smallest number of moles, and then multiplying by a whole number factor to get a whole number ratio of atoms. The formula of the hydrate is [tex]Al_{2}(SO_{4})3.18H_{2}O[/tex].

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The boiling point of K2SO4 is 1,069°C (1,956°F).

Potassium sulfate (K2SO4) does not have a boiling point as it decomposes before reaching its boiling point. At normal atmospheric pressure, potassium sulfate decomposes into potassium oxide (K2O) and sulfur trioxide (SO3) when heated to temperatures above 1,069°C (1,956°F).

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The mass of NH₃Cl required is approximately 5.00 g.

To calculate the mass of NH₄Cl required to prepare a buffer solution with a specific pH, we need to follow these steps:

Step 1: Write the balanced chemical equation for the reaction between NH₃ and NH₄Cl.

NH₃ + HCl ⇌ NH₄Cl

Step 2: Determine the moles of NH₃ required to achieve the desired pH.

Since the pH is given as 9.45, we can calculate the pOH:

pOH = 14 - pH = 14 - 9.45 = 4.55

Now, convert pOH to OH- concentration using the following equation:

pOH = -log[OH-]

[OH-] = [tex]10^{(-pOH)[/tex] = [tex]10^{(-4.55)[/tex]

Step 3: Calculate the concentration of NH3 required to react with OH-.

The concentration of NH3 is given as 0.375 M. We can assume that the concentration of NH4+ (from NH4Cl) will be negligible compared to NH3, so we can consider the NH3 concentration to be the concentration of OH- required.

[OH-] = [NH3] = 0.375 M

Step 4: Calculate the moles of NH3 required.

moles = concentration x volume

moles = 0.375 M x 0.250 L = 0.09375 moles

Step 5: Calculate the moles of NH4Cl required.

Since the reaction between NH3 and NH4Cl is in a 1:1 ratio, the moles of NH4Cl required will be equal to the moles of NH3.

moles of NH4Cl = 0.09375 moles

Step 6: Convert moles of NH4Cl to grams.

To convert moles to grams, we need to multiply by the molar mass of NH4Cl. The molar mass of NH4Cl is 53.49 g/mol.

mass = moles x molar mass

mass = 0.09375 moles x 53.49 g/mol ≈ 4.999 g

Therefore, rounded to two decimal places, the mass of NH4Cl required is approximately 5.00 g.

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The specific heat of C₂H₅Cl(g), The specific heat of C₂H₅Cl(l), and The enthalpy of vaporization of C₂H₅Cl(l).

Temperature is the measure of the average kinetic energy of the particles in a substance. It is a measure of the amount of heat present in a given system. Temperature can be measured in various units such as Fahrenheit, Celsius, and Kelvin. Temperature is an important indicator of the energy transfer of a system and can be used to predict changes in the system.

a) The specific heat of C₂H₅Cl(g) - Yes, because heat is transferred from the surface to the C₂H₅Cl(g) and it is necessary to know the amount of heat that is required to increase the temperature of the gas.

c) The specific heat of C₂H₅Cl(l) - Yes, because heat is transferred from the surface to the C₂H₅Cl(l) and it is necessary to know the amount of heat that is required to increase the temperature of the liquid.

d) The enthalpy of vaporization of C₂H₅Cl(l) - Yes, because the C₂H₅Cl(l) is vaporized when it is sprayed onto the surface, and it is necessary to know the amount of energy that is required for the liquid to be vaporized.

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moles of H+ = volume (in liters) x concentration (in moles per liter)

To calculate the moles of H+ neutralized by the antacid per tablet and the moles of H+ neutralized per gram of the antacid tablet, you need to follow these steps:

Step 1: Identify the balanced chemical equation for the reaction between the antacid and the H+ ions. This information should be given in your problem or can be found in a chemistry reference.

Step 2: Determine the mass (in grams) of the antacid tablet and the volume of H+ ions neutralized by the tablet. These values should be provided in the problem.

Step 3: Calculate the moles of H+ ions neutralized using the volume and concentration of H+ ions. Use the formula:

moles of H+ = volume (in liters) x concentration (in moles per liter)

Step 4: Calculate the moles of H+ neutralized per tablet. This is the moles of H+ neutralized from Step 3 divided by the number of tablets used in the experiment.

Step 5: Calculate the moles of H+ neutralized per gram of the antacid tablet by dividing the moles of H+ neutralized per tablet from Step 4 by the mass (in grams) of one tablet from Step 2.

Remember to include the appropriate units for each value in your calculations.

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The solution with the greatest buffer capacity is 0.40 M CH3COONa/0.20 M CH3COOH.

Buffer capacity is the ability of a solution to resist changes in pH upon addition of an acid or a base. It depends on the concentration of the weak acid and its conjugate base in the solution. The higher the concentration of these species, the greater the buffer capacity.
In the given options, the first two solutions have the same concentration of CH3COONa, but the concentration of CH3COOH is higher in the second option. This means that the second option has a higher concentration of the weak acid and hence, a greater buffer capacity. However, the third option has a lower concentration of CH3COONa, which decreases its buffer capacity.
Therefore, the solution with the greatest buffer capacity is the one with a higher concentration of weak acid and its conjugate base, which is 0.40 M CH3COONa/0.20 M CH3COOH.

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