what could have caused births to increase in the moon jelly population?

The balanced formula is therefore N 2 (g) + 3 H (g) 2 NH 3 (g).

In the example process, hydrogen and nitrogen combine to form ammonia. It is thus a combination reaction as it is known that this sort of reaction is referred to as a combination reaction when two molecules join to generate a new chemical.

N2 (g) + 3H2 (g) 2NH3 is the balanced chemical formula for N2 + H2 + NH3 (g). The rule of mass conservatism may be used to attain this by duplicating the atoms across the product and reaction sides.

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We need to add 300 mL of the 85% alcohol mixture to the 375 mL of the 40% alcohol mixture to obtain 675 mL of a 60% alcohol solution.

Let x be the volume (in mL) of the 85% alcohol mixture that we need to add.

To obtain a 60% alcohol solution, we need to use the following equation, which states that the amount of pure alcohol in the final mixture is equal to the sum of the amounts of pure alcohol in each of the initial mixtures:

0.40(375) + 0.85x = 0.60(375 + x)

Simplifying and solving for x, we get:

150 + 0.85x = 225 + 0.60x

0.25x = 75

x = 300

Therefore, we need to add 300 mL of the 85% alcohol mixture to the 375 mL of the 40% alcohol mixture to obtain 675 mL of a 60% alcohol solution.

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The correct answer is (d) 1.52 g, 79.5%, HCI limiting. The theoretical yield is the amount of product that can be obtained if all of the limiting reactant is completely consumed.

What is Limiting Reagent?

In a chemical reaction, the limiting reagent (also called limiting reactant) is the substance that is completely consumed when the reaction goes to completion. This means that the limiting reagent determines the amount of product that can be formed in the reaction. The other reactant(s) that are not completely consumed are said to be in excess.

To determine the limiting reactant, we need to compare the amount of product that each reactant can produce. The balanced equation tells us that 1 mole of Ca reacts with 2 moles of HCl to produce 1 mole of CaCl2 and 1 mole of H2. Using the molar masses of each substance, we can calculate the number of moles of each reactant:

1.00 g Ca x (1 mol Ca / 40.08 g Ca) = 0.0249 mol Ca

1.00 g HCl x (1 mol HCl / 36.46 g HCl) = 0.0275 mol HCl

Since the reaction requires 2 moles of HCl for every 1 mole of Ca, we can see that there is not enough HCl to completely react with all of the Ca. Therefore, HCl is the limiting reactant and Ca is in excess.

The theoretical yield is the amount of product that can be obtained if all of the limiting reactant is completely consumed. We can use the stoichiometry of the balanced equation to calculate the theoretical yield of CaCl2:

0.0275 mol HCl x (1 mol CaCl2 / 2 mol HCl) x (110.98 g CaCl2 / 1 mol CaCl2) = 1.52 g CaCl2

The actual yield is given as 1.21 g CaCl2. To calculate the percent yield, we use the formula:

percent yield = (1.21 g / 1.52 g) x 100% = 79.6%

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A 1.20 gram sample of ammonium phosphate is dissolved in 100. ml of water, the solution is poured into 50.0 ml of a 1.5 m magnesium nitrate solution. Therefore the mass (g) of solid product will be produced if the reaction runs to completion is: 6.29g

Ammonium phosphate reacts with magnesium nitrate to form magnesium phosphate and ammonium nitrate. The balanced chemical equation for the reaction is as follows:

(NH₄)₃PO₄(aq) + 3Mg(NO₃)₂(aq) → Mg₃(PO₄)₂(s) + 6NH₄NO₃(aq)

To find the mass of the solid product formed when ammonium phosphate reacts with magnesium nitrate, we must first calculate the moles of ammonium phosphate and magnesium nitrate.

Moles of ammonium phosphate = mass/molar mass = 1.20/149.09 = 0.008 moles

Moles of magnesium nitrate = concentration x volume = 1.5 x 50.0/1000 = 0.075 moles

The stoichiometric ratio of ammonium phosphate to magnesium nitrate is 1:3, so all the ammonium phosphate will react with 0.024 moles of magnesium nitrate to form 0.024 moles of magnesium phosphate. The mass of magnesium phosphate formed can be calculated as follows:

Mass of magnesium phosphate = moles x molar mass = 0.024 x 262.86 = 6.29 g

Therefore, 6.29 g of magnesium phosphate will be produced when 1.20 g of ammonium phosphate is dissolved in 100 mL of water and the solution is poured into 50.0 mL of a 1.5 M magnesium nitrate solution and the reaction runs to completion.

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This solution has a pH of 7. As hydrogen and hydroxide ions are present in equal amounts in a pH 7 solution, it is neutral.

Atoms bearing an electric charge, such the hydrogen atom with charge H+, which has a value of 1, are known as ions. Even in pure water, ions frequently appear as a result of chance occurrences (producing some H+ and OH- ions).

We use the following formula to determine the pH of the solution:

pH = -log[H+]

where [H+] represents the number of hydrogen ions present in the solution.

Substituting the given concentration [H+] = 1.0 x 10⁻⁷ mol/L into the formula, we get:

pH = -log(1.0 x 10⁻⁷)

= 7

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When we titrate a weak base with a strong acid, the pH at the equivalence point will be less than 7.

Titration is a technique used in analytical chemistry to determine the concentration of an unknown compound or element.

This involves combining a reagent of known concentration with the unknown and using indicators or instrumental analysis to determine the equivalence point. A weak base is a type of compound that has a pH greater than 7 and is capable of accepting protons.

A strong acid, on the other hand, is a type of compound that can readily donate a proton to a base. When you titrate a weak base with a strong acid, the pH at the equivalence point will be less than 7. This is because the reaction produces a salt that is acidic in nature.

The pH at the equivalence point is also dependent on the amount of acid added to the base. The more acid added to the base, the lower the pH at the equivalence point will be. The pH of the solution will also gradually decrease as the acid is added.

However, the pH change will be less dramatic than in the case of titrating a strong base with a strong acid.

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4.68L is the final volume.

The volume of a gas is inversely proportional to its temperature when pressure is held constant. This means that when the temperature of the gas is decreased, its volume will increase.

Therefore, the final volume of the 17.0 L of carbon dioxide will be greater than 17.0 L after it is cooled from 38°C to 5°C.

The equation to calculate the final volume is:

[tex]V2 = V1 * (\frac{T2}{T1})[/tex]

where T1 is the starting temperature, T2 is the ending temperature, V1 is the starting volume, and V2 is the finished volume.

Using this equation, the final volume of the carbon dioxide can be calculated as:

[tex]V2 = 17.0 L * (\frac{5\°C}{38\°C}) \\V2= 4.68 L[/tex]

Therefore ,The Final volume is 4.68L

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The given compound O=O does not have any hydrogen atoms, so it will not produce any signals in an HNMR spectrum. Therefore, the correct answer is "none of the above".

In NMR spectroscopy, signals appear as peaks in a spectrum that correspond to the resonant frequency of the hydrogen atoms in a molecule. The number of signals produced in an HNMR spectrum is determined by the number of unique sets of chemically equivalent hydrogen atoms in a molecule.

Hence, the absence of hydrogen atoms in the O=O compound means that there will be no signals produced in an HNMR spectrum.

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The correct answer is The ground-state electron configuration of copper (Cu) can be determined by following the Aufbau principle, which states that electrons occupy.

[tex]1s^2 2s^2 2p^6 3s^2 3p^6 4s^1 3d^10[/tex]Copper has an atomic number of 29, meaning it has 29 electrons distributed among its energy levels. The first two electrons occupy the 1s orbital, followed by two in the 2s orbital and six in the 2p orbital. The next two electrons fill the 3s orbital, followed by six in the 3p orbital. The last electron occupies the 4s orbital, which is one of the outermost orbitals and has a lower energy level than the 3d orbital. This is an exception to the Aufbau principle, where the 3d orbital is usually filled before the 4s orbital. The 3d orbital, which can hold up to 10 electrons, is fully occupied in copper's ground state, giving it its unique electronic configuration.

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When the "show polar molecules" inset checkbox is selected, polar molecules are highlighted in a different color from nonpolar molecules. This allows us to observe the effect of polarity on intermolecular forces between molecules.

Polar molecules have a permanent dipole moment due to the electronegativity difference between the atoms in the molecule. This means that there is an uneven distribution of electrons, with one end of the molecule being more negative (due to the presence of a lone pair of electrons or a more electronegative atom) and the other end being more positive.

The presence of these dipoles results in the formation of dipole-dipole interactions, which are stronger than the London dispersion forces that nonpolar molecules experience. The greater the polarity of a molecule, the stronger the dipole-dipole interactions will be.

Therefore, when observing the polar molecules inset, we can see that polar molecules tend to be clustered together, forming stronger intermolecular forces than nonpolar molecules. This clustering can lead to higher boiling points, increased solubility in polar solvents, higher viscosity, and higher surface tension due to the stronger intermolecular forces between molecules.

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Answer:

Explanation:

D. Vaporization occurs with liquid particles gain energy and "fly away" into a gas.

Think of when you're boiling something on the stove.

The mass of 15.0 mL SO2 at STP is 0.0375 grams.

What is Mass?

Mass is a measure of the amount of matter in an object or substance. It is usually measured in grams (g) or kilograms (kg). Mass is a scalar quantity, meaning it has only magnitude and no direction. It is different from weight, which is the force of gravity acting on an object with mass.

For both problems, we can use the ideal gas law, which states that PV = nRT, where P is pressure, V is volume, n is the number of moles of gas, R is the ideal gas constant, and T is temperature in Kelvin. At STP, pressure is 1 atm and temperature is 273 K.

For the first problem, we can use the molar volume of a gas at STP, which is 22.4 L/mol, to find the number of moles of CO2:

2.80 L CO2 x (1 mol CO2 / 22.4 L CO2) = 0.125 mol CO2

Then, we can use the molar mass of CO2, which is 44.01 g/mol, to find the mass:

0.125 mol CO2 x 44.01 g/mol = 5.50 g CO2

Therefore, the mass of 2.80 L CO2 at STP is 5.50 grams.

For the second problem, we need to convert the volume from milliliters to liters:

15.0 mL SO2 = 0.0150 L SO2

Then, we can use the ideal gas law to find the number of moles of SO2:

PV = nRT

n = (PV) / RT

n = (1 atm)(0.0150 L) / (0.0821 Latm/molK)(273 K) = 5.86 x [tex]10^{-4}[/tex]mol SO2

Finally, we can use the molar mass of SO2, which is 64.06 g/mol, to find the mass:

5.86 x [tex]10^{-4}[/tex]mol SO2 x 64.06 g/mol = 0.0375 g SO2

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When 2.3 g of octane (CH3CH2CH3) react with 6.2 g of oxygen gas (O2), the theoretical yield of water (H2O) produced is 3.32 g.

The balanced equation for this reaction is:
CH3CH2CH3 + 3 O2  -> 2 CO2 + 3 H2O

To calculate the theoretical yield of water formed, we need to know the molar mass of octane, oxygen, carbon dioxide, and water.
The molar mass of octane is (12.011 + 1.00794*2 + 15.9994*3 = 58.0966 g/mol).
The molar mass of oxygen is (2*15.9994 = 31.9988 g/mol).
The molar mass of carbon dioxide is (12.011 + 2*15.9994 = 44.0094 g/mol).
The molar mass of water is (2*1.00794 + 15.9994 = 18.01528 g/mol).

Now we can calculate the number of moles of octane and oxygen that are needed in the reaction.
2.3 g of octane is equal to (2.3/58.0966 = 0.0397 mol).
6.2 g of oxygen is equal to (6.2/31.9988 = 0.1937 mol).

The ratio of moles of octane to moles of oxygen is 0.0397:0.1937. We can use the mole ratio to calculate the moles of water formed:
0.1937 x 3 = 0.5811 mol of water

To convert from moles of water to grams of water, we multiply the number of moles of water by the molar mass of water:
0.5811 mol x 18.01528 g/mol = 3.32 g of water

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The pH of the final solution is approximately 3.87. When 23.90 mL of 0.100 M sodium hydroxide is added to 25.00 mL of 0.100 M methanoic acid with a Ka value of 1.6 x 10^-4, we can calculate the pH of the final solution by first finding the moles of acid and base:

moles of methanoic acid = 25.00 mL × 0.100 M = 2.500 mmol
moles of sodium hydroxide = 23.90 mL × 0.100 M = 2.390 mmol

Now, we can find the moles of methanoic acid remaining after the reaction:

moles of methanoic acid remaining = 2.500 mmol - 2.390 mmol = 0.110 mmol

As the reaction between methanoic acid and sodium hydroxide is a 1:1 reaction, we will have 0.110 mmol of methanoic acid and 0 mmol of sodium hydroxide remaining. Next, we can calculate the concentration of the remaining methanoic acid in the solution:

volume of solution = 25.00 mL + 23.90 mL = 48.90 mL
concentration of methanoic acid = 0.110 mmol / 48.90 mL = 0.00225 M

Now, we can use the Ka value to find the concentration of H3O+ ions in the solution:

Ka = [H3O+][A-] / [HA]
1.6 x 10^-4 = [H3O+][0.00225 - H3O+] / [0.00225]

Solving for H3O+ concentration, we get:

[H3O+] ≈ 1.35 x 10^-4 M

Finally, we can calculate the pH of the final solution using the H3O+ concentration:

pH = -log10[H3O+]
pH ≈ -log10(1.35 x 10^-4)
pH ≈ 3.87

Therefore, the pH of the final solution is approximately 3.87.

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RNA polymerase is the enzyme responsible for building the RNA chain during transcription, a process in which genetic information from DNA is converted into RNA molecules.

RNA polymerase binds to a specific region of DNA called the promoter and then moves along the DNA strand, unwinding it as it goes. The enzyme then uses one of the DNA strands as a template to synthesize a complementary RNA strand, adding nucleotides one by one to build the chain. The resulting RNA molecule is a copy of the genetic information stored in the DNA, and it can be used to direct the synthesis of proteins or perform other functions within the cell.

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At the same temperature, the ratio of helium atom to chlorine molecule velocity is roughly 2.98.

The ratio of the velocity of helium atoms to the velocity of chlorine molecules at the same temperature can be calculated using the root-mean-square (rms) velocity formula. The rms velocity is the square root of the average of the squared velocities of the particles in a gas.

The rms velocity of a gas can be calculated using the equation:

[tex]v_r_m_s[/tex] = √((3kT)/(M))

where k is the Boltzmann constant, T is the temperature in Kelvin, and M is the molar mass of the gas.

For helium, the molar mass (M) is 4.003 g/mol, and for chlorine, the molar mass is 35.45 g/mol.

Assuming both gases are at the same temperature, we can cancel out T from the equation. Thus, we have:

([tex]v_r_m_s[/tex])_He/([tex]v_r_m_s[/tex])_Cl = √(M_Cl/M_He)

Substituting the values, we get:

([tex]v_r_m_s[/tex])_He/([tex]v_r_m_s[/tex])_Cl = √(35.45 g/mol / 4.003 g/mol)

= √(8.862)

= 2.98

Therefore, the ratio of the velocity of helium atoms to the velocity of chlorine molecules at the same temperature is approximately 2.98.

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Correct option is option C, C-O σ* bond.

Let's discuss it further below.

SNAc is an acronym for substitution nucleophilic acyl cyclic mechanism. The SNAc mechanism describes a nucleophilic substitution reaction in which an acyl group is transferred between two molecules, forming a cyclic intermediate.

In this reaction, the LUMO (lowest unoccupied molecular orbital) is the antibonding molecular orbital of the C-O σ bond, represented as C-O σ*.

This is because the LUMO is the orbital that accepts electrons during the nucleophilic attack, and the C-O σ* bond is the antibonding orbital involved in the breaking of the bond between the carbonyl carbon and the oxygen of the ester. Therefore, the correct answer is option C, C-O σ* bond.

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Answer:

entropy refers randomness

since solid objects' particles have less randomness

ENTROPY would increase is the reaction

The balanced chemical equation for the reaction between N2 and F2 to produce NF3 is N2(g) + 3F2(g) → 2NF3(g). The molar mass of N2 is 28.02 g/mol. Therefore, 26 g of N2 is equal to 0.93 moles of N2.

The preceding balanced equation clearly shows that 2 moles of ammonia are created for every 1 mole of nitrogen. This indicates that the reaction's N2 to NH3 mole ratio is 1 to 2.

There are 14 moles of NH3 produced. The balanced chemical equation must first be written. Then use the unitary approach to fix the issue. Now, the mass of ammonia is determined using the following formula.

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Different forms of the same element with different numbers of neutrons are called isotopes.

Isotopes are a sort of atom, the smallest unit of matter that retains every one of the chemical properties of a component. Isotopes are forms of chemical components with specific properties.

Every component is distinguished by the number of protons, neutrons, and electrons that it possesses. The atoms of every chemical component have a characterizing same number of protons and electrons, yet - vitally - not neutrons, whose numbers can shift.

Atoms with the same number of protons yet various numbers of neutrons are called isotopes. They share almost the same chemical properties, yet contrast in mass and therefore in physical properties. There are stable isotopes, which don't emanate radiation, and there are unstable isotopes, which in all actuality do transmit radiation. The latter are called radioisotopes.

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The value of Kp for the given reaction is 12.2 atm. We can find it in the following manner.

PART A:

The hydrolysis reaction of antimony trichloride can be written as follows:

SbCl₃ + 3H₂O ⇌ Sb(OH)₃ + 3HCl

The equilibrium constant expression for this reaction can be written as:

K = [Sb(OH)₃][HCl]³ / [SbCl₃][H₂O]₃

The concentration of SbCl₃ is given as 0.046 M, and the concentration of HCl is given as 2.1 M. Assuming the volume of water used for dilution is negligible, the concentration of H2O can be considered to be 55.5 M (at 25 ˚C). The concentration of Sb(OH)₃ can be calculated using the stoichiometry of the reaction:

0.046 M SbCl3 x (1 mol Sb(OH)3 / 1 mol SbCl₃) = 0.046 M Sb(OH)₃

Substituting the given values into the equilibrium constant expression, we get:

K = (0.046 M) x (2.1 M)³ / (1)³x (55.5 M)³

K = 1.7 x 10⁻¹⁰

Therefore, the equilibrium constant, K, for the hydrolysis of antimony trichloride is 1.7 x 10⁻¹⁰.

PART B:

To calculate Kp for the given reaction, we can use the relationship between Kc and Kp, which is:

Kp = Kc(RT)^Δn

where R is the gas constant (0.0821 L atm mol⁻¹ K⁻¹), T is the temperature in Kelvin, and Δn is the difference between the total number of moles of gaseous products and the total number of moles of gaseous reactants.

In this case, Δn = (2 - 1 - 1) = 0, since the total number of moles of gaseous products (2 moles of NOBr) is equal to the total number of moles of gaseous reactants (1 mole of N2, 1 mole of O2, and 1 mole of Br2).

Substituting the given values into the equation for Kp, we get:

Kp = (448)(0.0821 L atm mol^-1 K⁻¹)(296 K)⁰

Kp = 12.2 atm

Therefore, the value of Kp for the given reaction is 12.2 atm.

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Bonding structure.

Explanation:

The carboxyl group (-COOH) has to be at the end of a hydrocarbon chain and not in the middle because of its bonding structure. The carboxyl group consists of a carbon atom double-bonded to an oxygen atom (C=O) and a single-bonded to a hydroxyl group (-OH).

When the carboxyl group is at the end of the hydrocarbon chain, it can form stable bonds with the rest of the chain through the carbon atom. In this configuration, the carbon atom is able to form a single bond with the neighboring carbon atom in the hydrocarbon chain, a double bond with the oxygen atom, and a single bond with the hydroxyl group. This satisfies the carbon atom's requirement for four bonds, resulting in a stable structure.

If the carboxyl group were to be located in the middle of the hydrocarbon chain, the carbon atom would need to form two single bonds with neighboring carbon atoms in addition to the double bond with the oxygen atom and the single bond with the hydroxyl group. This would require the carbon atom to form a total of five bonds, which is not possible as carbon can only form four bonds due to having four valence electrons. Therefore, the carboxyl group must be located at the end of the hydrocarbon chain to maintain a stable bonding configuration.

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Answer:b

Explanation:the answer is b

Hence it  will not be useful in determining the pH of the solution.

Because each indicator has a specified pH range over which it changes color, a single indicator solution is only appropriate for detecting pH over a relatively small range.

For instance, Methyl Orange changes hue from pH 3.1 to pH 4.4. The indicator won't change color and won't be useful for figuring out the pH of the solution if the pH is outside of this range. will not be useful in determining the pH of the solution.

A material that changes color when it comes into touch with an acid or a base is known as a "indicator solution". The conjugate base or acid versions of indicators, which are typically weak acids or bases, exhibit distinct hues because to variations in their absorption spectra1. We refer to these as acid-base indicators.

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The order of increasing boiling point for NH₃, CH₄, and PH₃ is (option C)NH₃ < CH₄ < PH₃. This is due to the intermolecular forces, which increase with increasing molecular weight and polarity.

The boiling point of a compound is primarily determined by its intermolecular forces, which are in turn dependent on its molecular structure and the types of atoms present. The strengths of the intermolecular forces increase with increasing molecular weight and polarity.

Among the given compounds NH₃, CH₄, and PH₃, NH₃ and PH₃ are polar, while CH₄ is nonpolar. This implies that NH₃ and PH₃ are capable of forming hydrogen bonds, which are stronger than the van der Waals forces that hold CH₄ molecules together.

Therefore, the order of increasing boiling point is:

c) NH₃ < CH₄ < PH₃

Hence, option (c) is the correct answer.

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The balanced chemical equation for the reaction is 4Na + O₂ → 2Na₂O. This means that for every 4 moles of sodium (Na) and 1 mole of oxygen (O₂) that react, 2 moles of sodium oxide (Na₂O) are produced.

To determine the correct answer, we need to use stoichiometry to calculate the theoretical yield of Na₂O based on the amount of Na and O₂ present in each scenario. We can then compare the calculated yield to the given yield of 169 g and 527 g to see which starting material (Na or O₂) produces a lower yield.

A. To calculate the theoretical yield of Na₂O based on 5.43 moles of Na:

5.43 moles Na x (2 moles Na₂O / 4 moles Na) x (62 g Na₂O / 1 mole Na₂O) = 168.78 g Na₂O

The calculated yield of Na₂O based on 5.43 moles of Na is very close to the given yield of 169 g. Therefore, we can conclude that Na is not the correct answer.

B. To calculate the theoretical yield of Na₂O based on 4.25 moles of O₂:

4.25 moles O₂ x (2 moles Na₂O / 1 mole O₂) x (62 g Na₂O / 1 mole Na₂O) = 527.25 g Na₂O

The calculated yield of Na₂O based on 4.25 moles of O₂ is very close to the given yield of 527 g. Therefore, we can conclude that O₂ is not the correct answer.

C. Since Na is not the correct answer and O₂ is not the correct answer, the only option left is C. Therefore, the correct answer is O₂ because it has the lower starting mass.

We need 1,000 mL of concentrated 0.02 M NaOH to prepare 2,000 mL of 0.01 M solution.

To calculate the volume of concentrated NaOH required to prepare 2,000 mL of 0.01 M solution, we need to use the formula:

C1V1 = C2V2

where C1 is the concentration of the concentrated NaOH, V1 is the volume of the concentrated NaOH, C2 is the desired concentration of the diluted solution (0.01 M in this case), and V2 is the final volume of the diluted solution (2,000 mL in this case).

We can rearrange the formula to solve for V1:

V1 = (C2 * V2) / C1

Plugging in the values, we get:

V1 = (0.01 M * 2,000 mL) / 0.02 M

V1 = 1,000 mL

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Answer:

5.3584 g

Explanation: