what is the new temperature, in degrees celsius, when the volume of the sample is changed at constant pressure and amount of gas to 1200 ml ?

In the given reaction, [tex]Fe_2O_3[/tex]is the reactant in excess, and CO is the limiting reactant. 138.2 g is the mass of the excess reactant ([tex]Fe_2O_3[/tex]) remaining after the reaction is complete.

To solve this problem, we need to determine the limiting reactant first. The balanced equation tells us that the stoichiometric ratio between [tex]Fe_2O_3[/tex] and CO is 1:3. This means that for every 1 mole of[tex]Fe_2O_3[/tex], we need 3 moles of CO to react completely.

First, we convert the given masses of [tex]Fe_2O_3[/tex]and CO into moles. The molar mass of[tex]Fe_2O_3[/tex] is 159.69 g/mol, so 169 g of [tex]Fe_2O_3[/tex] is approximately 1.058 moles. The molar mass of CO is 28.01 g/mol, so 59.4 g of CO is approximately 2.12 moles.

Since the stoichiometric ratio is 1:3, we compare the moles of CO to [tex]Fe_2O_3[/tex]. The ratio of moles is 2.12:1.058, which is approximately 2:1. This means that for every 2 moles of CO, we need 1 mole of [tex]Fe_2O_3[/tex]. Since we have less than 2 moles of CO, it is the limiting reactant.

Since CO is the limiting reactant, it will react completely, leaving some [tex]Fe_2O_3[/tex] unreacted. To calculate the mass of the excess [tex]Fe_2O_3[/tex], we subtract the mass of [tex]Fe_2O_3[/tex] consumed from the initial mass of [tex]Fe_2O_3[/tex]. The mass of Fe2O3 consumed can be calculated by multiplying the moles of CO reacted by the ratio of moles between [tex]Fe_2O_3[/tex]and CO (1:3). Finally, we express the remaining mass of [tex]Fe_2O_3[/tex]with the appropriate units.

Therefore, the mass of the excess [tex]Fe_2O_3[/tex]that remains after the reaction has gone to completion is (169 g - [2.12 mol CO * (1 mol [tex]Fe_2O_3[/tex]/ 3 mol CO) * 159.69 g/mol]) = approximately 138.2 g.

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The temperature of 1900°C is equivalent to approximately 2173.15 K, 3927.67 R, and 3452°F.

To convert the temperature from Celsius to Kelvin:

Kelvin (K): The conversion from Celsius to Kelvin is done by adding 273.15. So, to express 1900°C in Kelvin:

1900°C + 273.15 = 2173.15 K

Rankine (R): Rankine is another unit of temperature scale commonly used in engineering. The conversion from Celsius to Rankine involves multiplying by 9/5 and adding 491.67. Thus, to express 1900°C in Rankine:

(1900°C × 9/5) + 491.67 = 3927.67 R

Fahrenheit (F): The conversion from Celsius to Fahrenheit is done by multiplying by 9/5 and adding 32. So, to express 1900°C in Fahrenheit:

(1900°C × 9/5) + 32 = 3452°F

Therefore, the temperature of 1900°C is approximately 2173.15 K, 3927.67 R, and 3452°F.

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Option 2) Bromoethane and methanol is correct

The major products obtained upon treatment of ethyl methyl ether with excess HBr are Bromoethane and methanol.

What is ethyl methyl ether?

Ethyl methyl ether is a colorless gas that is used as a solvent. The IUPAC name for this compound is methoxyethane. It is a member of the ether family of compounds. When ethyl methyl ether reacts with excess HBr, it undergoes a substitution reaction and forms Bromoethane and methanol. The mechanism for this reaction is given below: Methoxyethane reacts with hydrogen bromide to produce methanol and ethyl bromide (bromoethane). Here are the products that are formed in this reaction: Bromoethane (C2H5Br) and Methanol (CH3OH)

The chemical equation for this reaction can be written as: CH3OCH2CH3 + HBr → CH3OH + CH3CH2Br [tex]\boxed{Option\ 2)}[/tex]

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A balanced chemical equation for the combustion of gaseous methanol is:2CH3OH (g) + 3O2 (g) → 2CO2 (g) + 4H2O(g).

Bond energy in C-H bonds is equal to 413 kJ/mol. Bond energy in O-H bonds is equal to 463 kJ/mol.Let us use Hess’s Law for the calculation of enthalpy of reaction.

The enthalpy of combustion of methanol can be given as follows: H = [2 × BE(C=O)] + [4 × BE(O-H)] - [2 × BE(C-H)] - [3 × BE(O=O)]Here, BE stands for bond energy. H = [2 × 799 kJ/mol] + [4 × 463 kJ/mol] - [2 × 413 kJ/mol] - [3 × 498 kJ/mol]H = -726 kJ/mol Thus, the enthalpy of combustion of methanol is -726 kJ/mol.

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The equilibrium of the reaction between hydrogen chloride and oxygen to form water and chlorine is as follows:4HCI(g) + 02(g) → 2H2O(g) + 2Cl2(g)In the table below, the following perturbations and their respective effects on the reaction have been given.

Perturbation Change in composition Shift in equilibriumThe pressure of HCI Decreases to the leftIncreases to the rightSome O2 is addedIncreases to the rightDecreases to the leftThe pressure of H2ONo effectNo effectSome Cl2 is removedDecreases to the leftIncreases to the rightThe pressure of O2No effectNo effectThe volume of the vessel is reducedIncreases to the rightDecreases to the leftThe pressure of Cl2Increases to the rightDecreases to the leftEXPLANATIONThe equilibrium of the reaction can be shifted either to the left or to the right depending on the perturbation applied to the system.

The perturbations in the table are given with their respective effects and equilibrium shifts.The table shows that the perturbation in which the pressure of HCI decreases, causes the equilibrium to shift to the left, while the increase of the pressure of HCI shifts the equilibrium to the right.

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10.63 grams of ZnO remain after the reaction is complete.

The balanced chemical equation for the reaction between zinc oxide and water is:

ZnO(s) + H2O(l) → Zn(OH)2(aq)

No. of moles of ZnO = Mass of ZnO / Molar mass of ZnO= 35.0 g / 65.38 g/mol= 0.535 moles of ZnO

The amount of water is given as 6.85 g

The molar mass of water is:H2O = 18.02 g/mol

No. of moles of H2O = Mass of H2O / Molar mass of H2O= 6.85 g / 18.02 g/mol= 0.380 moles of H2O

Now, we need to find out the limiting reagent.

.No. of moles of Zn(OH)2 formed from 0.535 moles of ZnO = 0.535 molesNo. of moles of Zn(OH)2 formed from 0.380 moles of H2O = 0.380 moles

Therefore, since the amount of ZnO (0.535 moles) is greater than the amount of H2O (0.380 moles), H2O is the limiting reagent and ZnO is the excess reagent.

The maximum amount of Zn(OH)2 that can be formed is given by the amount of ZnO that reacts with H2O, which is 0.380 moles.

No. of grams of Zn(OH)2 = No. of moles of Zn(OH)2 × Molar mass of Zn(OH)2= 0.380 mol × (97.41 g/mol)= 37.08 gThe formula for the limiting reagent is H2O. The amount of excess reagent remaining after the reaction is complete can be calculated by subtracting the amount of limiting reagent used from the initial amount of excess reagent

.Initial amount of excess reagent (ZnO) = 35.0 g

No. of moles of ZnO = Mass of ZnO / Molar mass of ZnO= 35.0 g / 65.38 g/mol= 0.535 moles of ZnO

Amount of ZnO used in the reaction = No. of moles of Zn(OH)2 formed × Ratio of ZnO to Zn(OH)2= 0.380 mol × (1 mol ZnO / 1 mol Zn(OH)2)= 0.380 moles of ZnO used

Amount of ZnO remaining after the reaction = Initial amount of ZnO − Amount of ZnO used= 35.0 g − (0.380 mol × 65.38 g/mol)= 10.63 g

Therefore, 10.63 grams of ZnO remain after the reaction is complete.

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A survey is a method of gathering information from a sample of individuals. A survey may be conducted in person, over the phone, or online. The goal of a survey is to collect data about the attitudes, beliefs, behaviors

Surveys can be used to answer a wide range of research questions, from market research to public health studies. The design of a survey includes selecting the sample size, sampling method, survey instrument, and data analysis plan.Experimental designAn experiment is a method of testing a hypothesis. The goal of an experiment is to determine the cause-and-effect relationship between two variables.

To do this, an experiment manipulates one variable (the independent variable) while holding all other variables constant. The effect of the independent variable on the dependent variable is then measured. Experimental designs can be used in a wide range of fields, including psychology, biology, and physics. The design of an experiment includes selecting the sample size, treatment groups, control group, and outcome measures.

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Given the electronegativity values of N (3.0) and O (3.5), the bond polarity in a nitrogen monoxide molecule, NO, can be illustrated using delta notation as (δ+) N–O (δ-). The correct answer is option B: (δ+) Br–F (δ-).

Explanation: Electronegativity is a term that refers to the tendency of an atom to attract electrons towards itself. Electronegativity increases across a period and decreases down a group. It is an important factor in determining the polarity of a chemical bond. In a polar bond, the electrons are shared unequally due to the difference in electronegativity between the two atoms.

This leads to the formation of partial charges (δ+ and δ-) on the atoms involved in the bond. The electronegativity values of N (3.0) and O (3.5) suggest that there is a difference in electronegativity between the two atoms. Nitrogen monoxide, NO, has a covalent bond between nitrogen and oxygen. In this bond, oxygen has a higher electronegativity than nitrogen, so it pulls the shared electrons closer to itself. This creates a partial negative charge (δ-) on the oxygen atom and a partial positive charge (δ+) on the nitrogen atom. The bond polarity can be represented as (δ+) N–O (δ-).Hence, the correct answer is option B: (δ+) N–O (δ-).

Similarly, given the electronegativity values of Br (2.8) and F (4.0), the bond polarity in a bromine monofluoride molecule, BrF, can be illustrated using delta notation as (δ+) Br–F (δ-).

Hence, the correct answer is option B: (δ+) Br–F (δ-).

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6.76 mL of 10.0 M HNO3 must be added to 1.00 L of the given buffer solution to reduce its pH to 5.15.

To reduce the pH of the given buffer solution to 5.15 using 10.0 M HNO3, we need to calculate the initial pH of the given buffer and the moles of acetic acid and sodium acetate present in it.

Then, using the Henderson-Hasselbalch equation, we can calculate the ratio of acetic acid to acetate ion required to make the buffer of pH 5.15.

Finally, using the balanced chemical equation for the reaction of acetic acid and HNO3, we can calculate the moles of HNO3 required to achieve the desired pH.
Initial pH of buffer:
pKa = 4.75
pH = pKa + log([Acetate ion]/[Acetic acid])
=> 4.75 + log([0.100]/[0.0100])
=> 4.75 + 1
=> 5.75
Moles of acetic acid and sodium acetate in 1 L of buffer solution:
Molarity of acetic acid (C2H4O2) = 0.0100 M
Molarity of sodium acetate (NaC2H3O2) = 0.100 M
Moles of acetic acid in 1 L of solution = Molarity x volume (in L)
=> 0.0100 x 1 = 0.010 mol
Moles of sodium acetate in 1 L of solution = Molarity x volume (in L)
=> 0.100 x 1 = 0.100 mol
Ratio of acetic acid to acetate ion required for pH 5.15:
pH = pKa + log([Acetate ion]/[Acetic acid])
=> 5.15 = 4.75 + log([Acetate ion]/[0.0100])
=> 0.40 = log([Acetate ion]/[0.0100])
=> [Acetate ion]/[0.0100] = 10^0.40
=> [Acetate ion]/[0.0100] = 2.51
=> [Acetic acid]/[Acetate ion] = 1/2.51
=> [Acetic acid]/[Acetate ion] = 0.397
So, we need to add acetic acid and sodium acetate in the ratio of 0.397:1 to make a buffer of pH 5.15.
Now, we can calculate the moles of HNO3 required to react with the excess acetate ion to achieve the desired pH:
Moles of acetate ion in 1 L of solution = Molarity x volume (in L)
=> 0.100 x 1 = 0.100 mol
Moles of HNO3 required = moles of acetate ion in excess = moles of acetate ion x (1/[Acetic acid]/[Acetate ion] - 1)
=> 0.100 x (1/0.397 - 1)
=> 0.0676 mol
Volume of 10.0 M HNO3 required to deliver 0.0676 mol:
Volume = moles/Concentration
=> 0.0676/10.0
=> 0.00676 L or 6.76 mL
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As an acid solution is added to neutralize a base solution, the OH- concentration of the base solution should decrease.

The concentration of OH- in the base solution should decrease as an acid solution is added to neutralise the base solution.

A proton (H+) is transferred from the acid to the base during the neutralisation reaction between an acid and a base, creating water in the process. As they interact with the hydrogen ions (H+) from the acid in this reaction to generate water molecules, the hydroxide ions (OH-) in the base solution are reduced in number.

When the acid and base are stoichiometrically balanced, the pH of the solution eventually reaches a neutral pH of 7, which is achieved by progressively lowering the pH of the solution and lowering the alkalinity of the base solution.

As a result, the amount of hydroxide ions (OH-) in the base solution drops as the acid neutralises the base.

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The balanced redox reaction in acidic solution is as follows:

2Cu+ (aq) + O2 (g) + 4H+ (aq) → 2Cu+2 (aq) + 2H2O (l)

To balance the redox reaction, we need to ensure that the number of atoms of each element is the same on both sides of the equation. First, we balance the atoms other than hydrogen and oxygen. In this case, the copper (Cu) atoms are already balanced.

Next, we balance the oxygen atoms by adding water (H2O) molecules to the right side of the equation. This introduces hydrogen atoms, so we need to balance them as well. To do this, we add protons (H+) to the left side of the equation.

Now, the hydrogen and oxygen atoms are balanced. Finally, we balance the charges by adding electrons (e-) to the left side of the equation. The total charge is now balanced, and the redox reaction is balanced in acidic solution.

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[tex]N_2(g) + O_2(g)[/tex] ↔ 2NO(g)  as the concentration of N2(g) increases, the concentration of [tex]O_2[/tex](g) will decrease . Option a) is correct.

The chemical equation [tex]N_2(g) + O_2(g)[/tex] ↔ 2NO(g) states that nitrogen ([tex]N_2[/tex] )and oxygen ([tex]O_2[/tex]) react to form nitrogen monoxide (NO).  As the concentration of nitrogen gas ([tex]N_2[/tex](g)) increases, the equilibrium will shift to the right to produce more products (NO). As a result, the concentration of oxygen gas ([tex]O_2[/tex](g)) will decrease, and the concentration of nitrogen monoxide (NO(g)) will increase.

The equilibrium constant (Kc) for this reaction can be used to determine the extent of the reaction at equilibrium. Kc is a ratio of the concentrations of the products and the reactants, and it is always expressed as the product of the product concentrations divided by the product of the reactant concentrations.

Hence, the concentration of [tex]O_2[/tex](g) will decrease. The correct answer is a).

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A chemical reaction is considered spontaneous if its Gibbs free energy is negative. Thus, the given chemical reaction is spontaneous.

The spontaneity of the given chemical reaction can be determined by using Gibbs free energy. Gibbs free energy (G) is given by the equation,

ΔG=ΔH−TΔS

Here, ΔG is the Gibbs free energy change. ΔH is the enthalpy change of the reaction, ΔS is the entropy change of the reaction, and T is the temperature in Kelvin. Since the temperature is not given, it can be assumed to be 298 K. Now substituting the values,

ΔG=ΔH−TΔS=-40.0 kJ- (298 K) (-89.5 J/K) ΔG=-40.0 kJ + 26.753 kJ ΔG=−13.247 kJ

For the given chemical reaction, ΔG is negative. Therefore, the given chemical reaction is spontaneous.A chemical reaction is considered spontaneous if its Gibbs free energy is negative. Thus, the given chemical reaction is spontaneous.

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The lowest energy chair conformation for cis-1,4-dichlorocyclohexane is shown below: Chair conformation is a shape that is often adopted by cyclohexane and its derivatives when they have a substituent on each carbon atom. Cis-1,4-dichlorocyclohexane is one of the cyclic compounds that adopt the chair conformation, where each carbon atom is surrounded by three carbon atoms and one substituent.

The lowest energy chair conformation for cis-1,4-dichlorocyclohexane is shown below:Lowest energy chair conformation for cis-1,4-dichlorocyclohexaneAs a result, the substituents on the chair conformation of cis-1,4-dichlorocyclohexane are trans to one another. The trans substituents, on the other hand, must be axial to each other.

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The order of elements according to the first ionization energy is Na < Li < K < Rb.

The first ionization energy is the minimum energy required to remove an electron from a neutral atom, thereby giving a positive ion. Arrange the elements according to first ionization energy (from lowest to highest).The ionization energy increases from left to right across a period and decreases from top to bottom within a group.

Lithium has the lowest first ionization energy because it has the largest atomic radius among these elements. Sodium has the next lowest first ionization energy since it has a smaller atomic radius than lithium and can lose an electron more easily than lithium. Potassium has a slightly higher first ionization energy than sodium because it is larger than sodium and thus holds its electrons more tightly. Rb has the highest first ionization energy of the four elements listed because it is the smallest and has the most tightly held electrons.

Therefore, The order of elements according to the first ionization energy is as follows: Na < Li < K < Rb.

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Order from most reduced to most oxidized chlorine: Naci > HCIO3 > KCIO4 > Cl2Order from most reduced to most oxidized iodine: I < HIO2 < HIO3 < IO.

In order to rank the following compounds in order from most reduced to most oxidized chlorine, we first need to identify the oxidation number of each element in each compound.NaciNa = +1Cl = -1Hence, the oxidation number of chlorine is -1. The oxidation state of sodium is +1. The more negative an oxidation state, the more reduced the element. Thus, Naci is the most reduced among the given compounds. HCIO3H = +1C = +5O = -2(3) = -6Cl = +5Thus, the oxidation number of chlorine is +5 in HCIO3.

Hence, it is more oxidized than Naci.KCIO4K = +1C = +6O = -2(4) = -8Cl = +7The oxidation number of chlorine in KCIO4 is +7. Thus, it is more oxidized than HCIO3 and Naci.Cl2Cl = 0Hence, the oxidation state of chlorine is 0. Thus, Cl2 is the most oxidized among the given compounds. Therefore, the order of compounds from most reduced to most oxidized chlorine is Naci > HCIO3 > KCIO4 > Cl2.Now, to rank the given compounds in order from most reduced to most oxidized iodine, we need to find the oxidation number of iodine in each compound.

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Buffered solutions possess the following characteristic properties:Solution is buffered by the presence of the combination of a weak acid and its conjugate base.A buffered solution is one that resists the change in its pH even when a strong acid or base is added to it.

There are a number of qualities that buffered solutions have that make them unique. Buffered solutions have a pH that is resistant to change when small amounts of an acid or base are added to it. A buffered solution consists of a weak acid and its conjugate base, which act together to resist changes in the pH of the solution.The ability of a solution to resist changes in pH is known as buffering, which is a characteristic property of buffers. A buffered solution has a greater ability to maintain a relatively constant pH, which is essential in various biological, chemical, and environmental processes.The combination of a weak acid and its conjugate base is necessary for buffering because it can absorb both H+ and OH- ions without affecting the pH of the solution. If a strong acid is added to a buffered solution, the weak acid neutralizes the H+ ions. If a strong base is added to the buffered solution, the conjugate base neutralizes the OH- ions. Hence, options (a), (d) and (e) are incorrect. Thus, the correct options are: Solution is buffered by the presence of the combination of a weak acid and its conjugate base.A buffered solution is one that resists the change in its pH even when a strong acid or base is added to it.

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The redox reaction is represented by the cell notation Cr(s) | Cr3+(aq) || F2(g) | F-(aq) | Pt. Therefore, correct option is A (F-(aq)).

The process is initiated by the oxidation of Cr(s), which results in the formation of Cr3+(aq). This reaction takes place at the anode. The Cr(s) is losing electrons and becoming positively charged.
Cr → Cr3+ + 3e-
In the meantime, reduction is happening at the cathode, which is accepting the electrons donated by the anode. F2(g) is the species undergoing reduction.
F2(g) + 2e- → 2F-(aq)
Therefore, the answer is F2(g). During the reduction half-reaction, F2 (g) gains two electrons to form F− (aq). This occurs because the oxidized species loses electrons to the reduced species in the reaction.

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The pH of HCN with KOH at the equivalence point is greater than 7. Option b. is correct.

In a titration, the equivalence point is where the moles of the added titrant are stoichiometrically equal to the moles of the titrated substance. In this case, HCN is the titrated substance, and KOH is the titrant, or the added substance. Since KOH is a strong base, it will react completely with the HCN, which is a weak acid.

[tex]HCN + KOH[/tex] → [tex]H_2O + KCN[/tex]

At the equivalence point, all the HCN will be consumed and replaced by the KCN salt and [tex]H_2O[/tex]. Since the KCN salt is the salt of a weak acid (HCN) and a strong base (KOH), it will hydrolyze in water, producing [tex]OH^-[/tex]  ions:

[tex]KCN + H_2O[/tex] →[tex]HCN + KOH[/tex]

The [tex]OH^-[/tex] ions will increase the pH of the solution, making it greater than 7. Therefore, the answer is (b) greater than 7.

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The symbol of a simple unprefixed SI unit has been left off of each measurement in the table. The missing unit symbols are as follows: the volume of water in an aquarium is 30 L the mass of a can of soda is 350 g the length of a high-school swimming pool is 2.0 m the mass of an apple is 250 g.

The International System of Units (SI) has seven base units that are used to measure physical quantities. These units are metre, kilogram, second, ampere, kelvin, mole, and candela. The symbol of a simple unprefixed SI unit has been left off of each measurement in the table. The missing unit symbols are as follows :the volume of water in an aquarium is 30 L the mass of a can of soda is 350 g the length of a high-school swimming pool is 2.0 m https://brainly.com/question/29886188the mass of an apple is 250 g

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The pH of the given solution in which [HA] = 2[A–] and the pKa of HA is 5.5 is 4.5.

The pH of the solution can be determined by using the Henderson-Hasselbalch equation as follows:pH = pKa + log([A⁻]/[HA])Given:[HA] = 2[A⁻]pKa of HA = 5.5Substituting the given values in the above formula, we get:pH = 5.5 + log(2[A⁻]/[HA])Now, we know that [HA] = 2[A⁻]

Substituting this in the above equation, we get:pH = 5.5 + log(2) – log([A⁻]) – log([A⁻])pH = 5.5 + 0.301 – 2log([A⁻])pH = 5.8 – 2log([A⁻])Therefore, the pH of the given solution is 4.5 (long answer in 100 words).

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The mass of copper that will be plated out by a current of 2.3 A applied for 25 minutes to a 0.50 M solution of copper(II) sulfate is 0.190 g.

The mass of copper can be calculated using Faraday's law as follows:

Mass of copper = n × M × z

where n is the number of moles of electrons transferred, M is the molar mass of copper, and z is the number of electrons per copper ion.

To find z, we need to know the formula of copper sulfate. Copper(II) sulfate has the formula CuSO₄. Each copper ion carries two positive charges (Cu²⁺), so z = 2.

Molar mass of CuSO₄ = 63.55 + 32.06 + 4(16.00) = 159.61 g/mol

Mass of copper = n × M × z = 0.000596 mol × 159.61 g/mol × 2 = 0.190 g

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The mass of copper that will be plated out by a current of 2.3 A applied for 25 minutes to a 0.50 m solution of copper (II) sulfate is 0.935 grams (to the nearest thousandth).

First of all, let's list down the given values;

The current, I = 2.3 A

The time of the experiment, t = 25 minutes = 1500 seconds

The concentration of copper (II) sulfate solution, C = 0.50 m

Now, let's calculate the amount of electricity that was passed through the solution;

I = Q/t,

where Q = quantity of electricity passed

.2.3 = Q/1500Q = 2.3 × 1500Q = 3450 C

The number of moles of CuSO4 in the solution can be calculated as;

C = n/V0.50 = n/1000n = 0.0005 mol

The number of moles of Cu deposited will be equal to the number of electrons that pass through the cell, which can be calculated by;

n = Q/Fn = 3450/96500n = 0.0357 moles

The number of moles of Cu deposited is 0.0357 moles and the molar mass of Cu is 63.5 g/mol.

Therefore, the mass of copper that will be plated out is;

Mass = n × Molar mass

Mass = 0.0357 × 63.5

Mass = 2.27 grams

But, this is the theoretical value, in actual experiments, due to loss of electricity due to polarization, mass is always less. A commonly observed ratio is 95% for copper electrodeposition.

So, the mass of copper that will be plated out will be 0.95 × 2.27 grams = 0.935 grams.

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We know that Calcium hydroxide reacts with Phosphoric acid to form Calcium Phosphate and Water. The answer is 0.57 g.

Ca(OH)₂ + H₃PO₄ → Ca₃(PO₄)₂ + 2 H₂OMolar mass of Ca₃(PO₄)₂= (3×40.1)+(2×30.97)+(8×16)= 310.19 g/molMolar mass of Ca(OH)₂= 74 g/molThus, the number of moles of Ca₃(PO₄)₂ is= 2.39/310.19 = 0.0077171Number of moles of Ca(OH)₂ required = Number of moles of Ca₃(PO₄)₂= 0.0077171.

Now, number of moles of Ca(OH)₂= mass of Ca(OH)₂/molar mass of Ca(OH)₂=> mass of Ca(OH)₂= number of moles of Ca(OH)₂×molar mass of Ca(OH)₂= 0.0077171×74= 0.5702986 g= 0.57 gThus, 0.57 g of Ca(OH)₂ reacts with 2.39 g of Ca₃(PO₄)₂.

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Methamphetamine and cocaine are the most widely used stimulant drugs in the world. This statement is False.

While methamphetamine and cocaine are indeed stimulant drugs, it is not accurate to say that they are the most widely used stimulant drugs in the world. The term "widely used" can have different interpretations, such as considering prevalence rates, total number of users, or global consumption patterns.In terms of prevalence rates and total number of users, substances such as caffeine and nicotine are far more widely used stimulants. Caffeine, found in coffee, tea, and various beverages, is consumed by a large portion of the global population. Nicotine, found in tobacco products, is also widely used, although efforts to reduce smoking rates have been made in many countries.It's important to note that drug use patterns can vary across regions and populations, and there may be other stimulant drugs that are more prevalent in specific areas. Therefore, it is more accurate to say that methamphetamine and cocaine are among the commonly used stimulant drugs, but not necessarily the most widely used worldwide.

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Nitrogen has a normal boiling point of 77.36K. Nitrogen is a diatomic gas that exists naturally in the air. The atomic number of nitrogen is 7, and it is represented by the symbol N.

A normal boiling point is a temperature at which a liquid boils under a pressure of 1 atmosphere. The boiling point of a liquid is determined by the pressure exerted on it by its vapor, which is in equilibrium with the liquid. The boiling point of a liquid increases as the pressure on it is raised.

The boiling point of a liquid decreases as the pressure on it is reduced.At standard pressure, nitrogen boils at 77.36K (−195.79°C or −320.42°F). This is the normal boiling point of nitrogen. Nitrogen has a normal boiling point of 77.36K. Nitrogen is a diatomic gas that exists naturally in the air. The atomic number of nitrogen is 7, and it is represented by the symbol N.

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there are 3.77 x 1022 H2O molecules in a 1.40 L sample of H2O gas at STP.

At STP, the volume of 1 mole of any gas is 22.4 L.

This means that the number of moles of gas can be calculated by dividing the volume of the gas by 22.4 L. The number of moles of H2O gas in a 1.40 L sample can be calculated as follows:

1.40 L ÷ 22.4 L/mol = 0.0625 mol H2O

To find the number of H2O molecules in 0.0625 moles of H2O, we can use Avogadro's number, which is 6.02 x 1023 molecules per mole.

This gives us:

Number of H2O molecules = 0.0625 mol

H2O x 6.02 x 1023 molecules/mol = 3.77 x 1022 H2O molecules

Therefore, there are 3.77 x 1022 H2O molecules in a 1.40 L sample of H2O gas at STP.

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Including cyclic compounds, there are 5 possible isomers for C4H8.

The chemical formula for four-carbon aliphatic hydrocarbons is C4H8. C4H8 can exist in a variety of isomers, including acyclic (open-chain) and cyclic molecules. Let's run through the various options:

1. Butane: N-butane, which contains a straight chain of four carbon atoms, is the simplest acyclic isomer.

2. Isobutane has a branching structure with a methyl (CH3) group linked to the second carbon atom of the main chain. This isomer is also referred to as 2-methylpropane.

3. Cyclobutane, an isomer with four carbon atoms arranged in a ring.

4. Methylcyclopropane: This cyclic isomer has a methyl group linked to one of the three carbon atoms in the cyclopropane ring.

5. Ethylcyclopropane: This cyclic isomer, which also has a cyclopropane ring, one of the carbon atoms has an attached ethyl (C2H5) group.

There are so a total of five potential isomers for C4H8, including both acyclic and cyclic molecules.

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To balance the equation in basic solution, we add 4OH⁻ ions on the left side and 3H₂O molecules on the right side. The coefficient of hydroxide ion is 4.

To balance the given equation in basic solution:

AlH⁴⁻ (aq) + H₂CO (s) → Al³⁺ (aq) + CH₃OH (aq)

First, let's balance the atoms other than hydrogen and oxygen. We have one Al on the left and one Al on the right, so Al is balanced. Similarly, we have one C on the left and one C on the right, so C is balanced as well.

Next, let's balance the hydrogen atoms. We have four H atoms in AlH⁴⁻ on the left and only one H atom in CH₃OH on the right. To balance the hydrogen, we need to add three H₂O molecules on the right side:

AlH⁴⁻ (aq) + H₂CO (s) → Al³⁺ (aq) + CH₃OH (aq) + 3H₂O (l)

Now, let's balance the oxygen atoms. We have four O atoms in H₂CO on the left and four O atoms in the three H₂O molecules on the right, totaling eight O atoms on the right. To balance the oxygen, we need to add four OH⁻ ions on the left side:

AlH⁴⁻ (aq) + 4OH⁻ (aq) + H₂CO (s) → Al³⁺ (aq) + CH₃OH (aq) + 3H₂O (l)

Now the equation is balanced. The coefficient of hydroxide ion (OH⁻) is 4.

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The statement that is not associated with covalent catalysis by enzymes is It never involves coenzymes. The correct option is A.

Covalent catalysis is a strategy for catalysis that happens when the pace of a response is improved because of the improvement of a transient covalent connection between the impetus and the substrate or substrate-determined intermediates. The substrate's bonds are broken down or made stronger by the transient covalent bond, which speeds up the reaction rate.

The enzyme and at least one of the reaction's substrates must form a covalent bond in order to perform covalent catalysis. This frequently involves a subclass of covalent catalysis called nucleophilic catalysis.

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The statement "When charging a secondary cell, energy is stored within a dielectric material using an electric field" is False. Rechargeable batteries use chemical energy which can be stored for future use. Thus, option C is correct.

When charging a secondary cell, such as a rechargeable battery, energy is stored in a chemical form, not within a dielectric material using an electric field. Rechargeable batteries utilize chemical reactions to convert electrical energy into chemical potential energy, which can be stored and later converted back into electrical energy during discharge.

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