what is the mass of 6.02×1022 6.02 × 10 22 atoms of argon?

The hydroxide ion concentration and the pH for a hydrochloric acid solution that has a hydronium ion concentration of [tex]1.50* 10^{3}[/tex] M are (D) [tex]6.67* 10^{11}[/tex] M, or[tex]10^{18}[/tex]

What is the hydroxide ion?

The hydrogen ion, or hydrogen oxide, is a negatively charged molecule or ion consisting of oxygen and hydrogen atoms with the formula OH. The hydroxide ion is a basic anion with many useful applications in chemistry, such as acid-base reactions and synthesis reactions.

Arrhenius acid is a chemical that donates a proton, whereas Arrhenius base is a chemical that accepts a proton.

The compound created when an acid donates a proton to a base is referred to as a conjugate base, while the compound created when a base accepts a proton from an acid is referred to as a conjugate acid.

When the concentration of H3O+ is given in a solution, it is used to calculate the pH.

The pH scale is used to measure how acidic or basic a solution is. As a result, the pH of the hydrochloric acid solution is calculated as follows:

pH = -log [H3O+] pH = -log (1.50–10) pH = 2.82

We can use the ion-product constant for water to calculate the hydroxide ion concentration.

The equilibrium constant, also known as the ion product constant for water, is equal to the product of the hydronium ion and hydroxide ion concentrations.

[OH][H3O+] = 1.00 x 1014 mol/L2. [OH] = Kw/[H3O+] [OH] = 1.00 x [tex]10^{14}[/tex]mol/L2 / 1.50  10-3 [OH−] = 6.67* 10^{11}

Therefore, the hydroxide ion concentration and the pH for a hydrochloric acid solution that has a hydronium ion concentration of 1.50  [tex]10 ^{3}[/tex]M are6.67* 10^{11} M, or 10^{18}

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In general, changes in rock formations can occur due to a variety of factors, including weathering, erosion, tectonic activity, and sedimentation.

What is Rock Formation?

Rock formation refers to the process by which rocks are created, transformed, or modified over time through various geological processes. This process involves the deposition of sediments, the consolidation and hardening of sediments into rock layers, and the metamorphism of existing rocks due to heat, pressure, and other factors.

There are three main types of rocks: igneous, sedimentary, and metamorphic. Igneous rocks form from molten magma or lava that cools and solidifies, while sedimentary rocks are formed from the accumulation of sediments, such as sand, mud, and organic material. Metamorphic rocks are formed from the transformation of existing rocks under high heat, pressure, and chemical reactions.

Weathering and erosion can cause rocks to break down and change shape over time, while tectonic activity can cause rocks to shift and deform. Sedimentation can lead to the formation of new rock layers on top of existing ones.

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According to the given statement The pH of the solution is  9.72.

Ammonia (NH3) is a substance that may be found in the air, soil, water, as well as in plants, animals, and people. Several commercial and domestic cleansers include ammonia as well. Ammonia at high concentrations can irritate and burn the eyes, mouth, throat, lungs, and skin.

This query may be addressed using the Henderson-Hasselbalch formula:

pH = pka + log [Base] /[Acid]

Base is NH₃ and acid NH₄⁺

Molarity of the compounds is:

NH₃: 0.750mol / 1.00L = 0.750M

NH₄⁺: 0.250mol / 1.00L = 0.250M

To find pka:

Ka×Kb = Kw

Ka = 1x10⁻¹⁴ / 1.77x10⁻⁵ = 5.65x10⁻¹⁰

pKa = -logKa = 9.25

Replacing:

pH = 9.25 + log [0.750] /[0.250]

pH = 9.72

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Answer:

Explanation:

It takes 487.5 J to heat 25 grams of copper from 25 °C to 75 °C. What is the specific heat in Joules/g·°C? Answer: The specific heat of copper is 0.39 J/g·°C

When translating the given conformer from the wedge-and-dash drawing into its Newman projection, there are steps to follow. These steps are explained below:

Step 1: Identify the axial and equatorial atoms in the conformer. Step 2: Determine which of the axial atoms will be in the front and which will be at the back. Step 3: Draw a circle and divide it into four sections. Step 4: Place the front axial atom in the left section of the circle.Step 5: Place the remaining axial atom in the right section of the circle. Step 6: Place the equatorial atom in the bottom section of the circle.Step 7: Rotate the back axial atom by 60 degrees so that it can point upwards.Step 8: Repeat the rotation for the equatorial atom. The final result is the Newman projection.The correct Newman projection can be seen by clicking on the "Tabs" tab. The Cl atom is in the back, while the Br atom is in the front, with the CH3 atom on the right side of the Newman projection.

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The molarity of this solution is 1.39 M.

Molarity, on the other hand, refers to the content of a substance or ion in a solution, whereas normality only refers to the molar concentration of the solution's acid or base components.

The formula is as follows:

Molarity (M) = moles of solute/liters of solution

We must first locate the copper(II) sulphate molecules. By splitting the solute's mass by its molar mass, we can determine this.

The molar mass of copper(II) sulfate is:

63.55 g/mol (for copper) + 2(32.06 g/mol) (for sulfur) + 4(16.00 g/mol) (for oxygen) = 159.61 g/mol

So, moles of copper(II) sulfate = 55.423 g / 159.61 g/mol = 0.347 moles

The volume of solution is 250.0 mL=0.250 L

Use the formula to calculate the molarity:

Molarity=0.347 moles / 0.250 L

= 1.39 M.

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The passage describes how to describe an object's position and motion, including specifying its direction and distance from a starting point. It also notes that an object is in motion when its position is changing, and that an object's displacement can be zero even if it has traveled.

How to describe an object's location and motion is covered in the paragraph. It states that it is crucial to indicate an object's direction and distance from a starting point when expressing an object's location. To achieve this, one may define the direction of the item using words like north, south, east, and west, and its distance from the beginning point using words like metres or feet. The verse also indicates that when an object's location changes, it is in motion. Both the direction and the distance from the starting location may alter as a result. Even when an item has moved, its displacement might still be zero.

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With this in mind, the product of each of these reactions.(a) NO2, (b) Cl2, and (c) Br. AlCl3 and FeCl3 are the catalysts in each case.

Nitration of Benzene, when benzene is nitrated with a mixture of nitric and sulfuric acid, the nitro group (-NO2) replaces one of the hydrogens on the benzene ring to produce nitrobenzene. When benzene is nitrated with a mixture of nitric and sulfuric acid, the nitro group (-NO2) replaces one of the hydrogens on the benzene ring to produce nitrobenzene. Chlorination of Benzene, when benzene is chlorinated, a hydrogen atom is replaced by a chlorine atom, and the product produced is chlorobenzene

When benzene is chlorinated, a hydrogen atom is replaced by a chlorine atom, and the product produced is chlorobenzene. Bromination of Benzene, bromination of benzene results in the formation of bromobenzene when iron (III) bromide is used as a catalyst. Bromination of benzene results in the formation of bromobenzene when iron (III) bromide is used as a catalyst.

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The gradient of the line passing through the points (2,3) and (5,7) is 4/3.

The gradient of a line is calculated by dividing the difference in the -coordinates by way of the distinction in the -coordinates. This might also be referred to as the trade in divided by means of the exchange in , or the vertical divided by way of the horizontal.

The gradient equation is another way we refer to the gradient of a straight line the usage of x and y coordinates. So once more the gradient equation is viewed as m = upward jab / run where m is the gradient or slope.

Finding the gradient of a straight-line graph

The gradient (also known as slope) of a line passing through two points (x1, y1) and (x2, y2) is given by:

gradient = (y2 - y1) / (x2 - x1)

Using the given points, we can calculate the gradient of the line passing through (2,3) and (5,7) as follows:

gradient = (7 - 3) / (5 - 2)

        = 4 / 3

Therefore, the gradient of the line passing through the points (2,3) and (5,7) is 4/3.

The gradient of the line = (change in y-coordinate)/(change in x-coordinate)

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Complete question:

Calculate the gradient of the line passing through the points (2,3) and (5,7).

The metals which can be oxidized with a Sn²⁺ solution but not with a Fe²⁺ solution are nickel, cadmium and copper.

The reactivity order of the metals is given below:

magnesium, aluminium, zinc, iron, nickel and tin

Generally, oxidation is defined as the loss of electrons and more reactive metals gives away electrons to less reactive metals.

So we are looking for a metal higher than tin but lower than iron.

The only metal in the rhyme is nickel. Definitely not aluminium because that is higher than iron.

Hence, the answer is Nickel and cadmium. Also copper (Cu) is one such metal, which has a reduction potential of -0.34 V. Hence, Cu can be oxidized by Sn2+ but not by Fe2+.

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The final temperature of the gold is approximately 34.7°C.

To solve this problem, we need to use the formula:
Q = m x c x ΔT

Where Q is the amount of energy absorbed by the gold, m is the mass of the gold, c is the specific heat capacity of gold, and ΔT is the change in temperature.

We are given that the mass of the gold is 4.1 g, the specific heat capacity of gold is 0.130 J/g °C, and the amount of energy absorbed by the gold is 52.2 J. We are also given the initial temperature of the gold, which is 25.0°C.

We can rearrange the formula to solve for ΔT:
ΔT = Q / (m x c)

Plugging in the values, we get:
ΔT = 52.2 J / (4.1 g x 0.130 J/g °C)

ΔT = 99.23 °C

This tells us that the gold has undergone a temperature change of 99.23°C. To find the final temperature, we add this change to the initial temperature:

Final temperature = 25.0°C + 99.23°C
Final temperature = 124.23°C

Therefore, the final temperature of the gold is 124.23°C.
To calculate the final temperature of the gold sample, you can use the formula:

Q = mcΔT
where Q is the energy (52.2 J), m is the mass (4.1 g), c is the specific heat capacity (0.130 J/g°C), and ΔT is the change in temperature (final temperature - initial temperature).

Rearrange the formula to find the final temperature:
ΔT = Q / (mc)
ΔT = 52.2 J / (4.1 g * 0.130 J/g°C)

Now, calculate ΔT:
ΔT ≈ 9.7°C

The initial temperature of the gold is 25.0°C, so the final temperature will be:
Final temperature = Initial temperature + ΔT
Final temperature ≈ 25.0°C + 9.7°C
Final temperature ≈ 34.7°C

Therefore, The gold's ultimate temperature is around 34.7°C.

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The phosphate buffer can accept 0.5 moles of hydrochloric acid before the pH of the solution begins to change drastically.

In this experiment, you have a buffer containing 0.5 moles of sodium dihydrogen phosphate (NaH2PO4) and 0.5 moles of sodium hydrogen phosphate (Na2HPO4). To determine how many moles of hydrochloric acid (HCl) this phosphate buffer can accept before the pH begins to change drastically, follow these steps:

1. Identify the conjugate acid-base pairs in the buffer system: NaH2PO4 (acid) and Na2HPO4 (base).

2. Calculate the initial moles of both the acid and base in the buffer.
  Initial moles of NaH2PO4 = 0.5 moles
  Initial moles of Na2HPO4 = 0.5 moles

3. Recognize that when HCl is added, it reacts with the base (Na2HPO4) to form the conjugate acid (NaH2PO4) and NaCl as a byproduct.
  HCl + Na2HPO4 -> NaH2PO4 + NaCl

4. Calculate the moles of HCl required to react with all the available base in the buffer.

  Since we have 0.5 moles of Na2HPO4, and the reaction occurs in a 1:1 ratio, it would require 0.5 moles of HCl to react with all the available base.

5. Determine the point at which the pH of the buffer begins to change drastically.

  This occurs when all the available base (Na2HPO4) has been consumed by the added HCl, and the buffer capacity has been exceeded. At this point, the buffer can no longer maintain a constant pH.

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Answer:

D

Explanation:

it is 2.2 ×10-3 because the avarage is between 2 and 3

The acid-base properties of EDTA (ethylenediaminetetraacetic acid) can be described as follows:

EDTA is a weak acid and can donate four protons (H⁺) from its four carboxylic acid groups. The pKa values of these acidic protons are between 1.5 and 2.0.

EDTA also has two amine groups, which can act as weak bases and accept protons (H⁺) under appropriate conditions. The pKa values of these basic groups are around 10.5.

In the presence of metal ions, EDTA can form stable coordination complexes due to its ability to chelate these metal ions with its six donor atoms (four oxygen atoms and two nitrogen atoms).

The formation of these EDTA-metal complexes is favored at higher pH values, where the EDTA molecule is deprotonated and has a higher negative charge, thus increasing its affinity for positively charged metal ions.

The acid-base properties of EDTA make it a useful chelating agent in a variety of applications, such as in analytical chemistry, industrial processes, and medicine.

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When sodium carbonate and calcium chloride are mixed, a precipitate of calcium carbonate forms.

Option B is correct.

What is a chemical reaction?

A chemical reaction is described as a process that leads to the chemical transformation of one set of chemical substances to another.

The reaction between sodium carbonate (Na2CO3) and calcium chloride (CaCl2) is a double displacement reaction, which is shown  by the following chemical equation:

Na2CO3 + CaCl2 → CaCO3 + 2NaCl

We can see that  the carbonate ion (CO32-) from sodium carbonate combines with the calcium ion (Ca2+) from calcium chloride to form solid calcium carbonate (CaCO3), which is insoluble in water and appears as a precipitate.

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The rate constant for a reaction generally increases with an increase in reaction temperature. The factor most sensitive to changes in temperature is the activation energy of the reaction.

The activation energy is the minimum energy required for a reaction to occur.

According to the Arrhenius equation, the rate constant (k) is directly proportional to the temperature (T) of the system. An increase in temperature would lead to an increase in the kinetic energy of the reactant molecules which will result in an increase in the number of effective collisions.

These effective collisions will have energy greater than the activation energy barrier, and thus they will lead to the formation of products. Hence, the rate of the reaction will increase with an increase in temperature.

Most of the reactions have a positive value of activation energy. Therefore, a slight increase in temperature can increase the rate of the reaction. However, if the temperature is increased beyond a certain limit, the rate of the reaction decreases due to the thermal denaturation of the enzyme or the inactivation of the catalysts, or the destruction of the reactants.

On increasing or decreasing the temperature the activation energy of a reaction changes drastically, either decreasing or increasing respectively.

In summary, the rate constant for a reaction is directly proportional to temperature and the activation energy is most sensitive toward temperature.

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The iodination EAS (Electrophilic Aromatic Substitution) reaction can be described as "green" because of the use of a benign solvent and the use of a less hazardous oxidant.

Therefore, the second and third option are correct.

A benign solvent is described as one that is less toxic, less flammable, and has a lower environmental impact compared to traditional solvents.

We know that in  iodination EAS reaction, green solvents like ethanol, ethyl acetate, and acetic acid are used instead of more hazardous solvents like chlorinated solvents.

In conclusion,  the use of a benign solvent and a less hazardous oxidant in the iodination EAS reaction makes it a "green" reaction.

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The Henderson-Hasselbalch equation can be used at the beginning and at the equivalence point of the titration because it relates the pH of a solution to the ratio of the concentration of the conjugate base and the weak acid of a buffer system.

At the beginning of a titration, the buffer system is intact, and the concentration ratio of the weak acid and its conjugate base remains constant. Therefore, the pH of the solution can be calculated using the Henderson-Hasselbalch equation.At the equivalence point of a titration, the moles of the acid and base in the solution are equal, and the buffer system is no longer present.

However, the Henderson-Hasselbalch equation can still be used to determine the pH of the solution because it relates the pH to the ratio of the concentration of the acid and the base. At the equivalence point, the concentration of the acid is equal to the concentration of its conjugate base, and the pH of the solution can be calculated using the Henderson-Hasselbalch equation.

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The type of bond between atoms in a compound determines the naming convention for the compound.

ionic compounds and covalent compounds. In ionic compounds, the bond between the atoms is ionic, which means that one or more electrons are transferred from one atom to another. The resulting ions are held together by electrostatic forces, which creates a strong bond. In naming ionic compounds, the cation (positively charged ion) is listed first, followed by the anion (negatively charged ion).

In covalent compounds, the bond between the atoms is covalent, which means that electrons are shared between the atoms. Covalent compounds can be further classified into polar and nonpolar compounds. In naming covalent compounds, the elements are listed in order of increasing electronegativity, and prefixes are used to indicate the number of atoms of each element in the compound.

Therefore, the type of bond in a compound determines the naming convention used to name the compound.

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Compounds with electron-deficient carbon atoms, like carbonyl compounds, are generally more reactive towards nucleophilic addition reactions. Also, compounds with less steric hindrance around the electrophilic carbon atom show increased reactivity.

Nucleophilic addition reactions involve the addition of a nucleophile (such as an anion or a neutral molecule with a lone pair of electrons) to an electrophile, resulting in the formation of a new bond. The reactivity of a compound towards this type of reaction is determined by the electronic and steric properties of the electrophilic carbon atom.

Compounds with electron-deficient carbon atoms, such as carbonyl compounds (e.g. aldehydes, ketones, and carboxylic acids), have a partially positive carbon atom that is highly susceptible to attack by a nucleophile. This is due to the polarity of the C=O bond, which creates a dipole that makes the carbon atom electron-deficient. Therefore, these compounds are generally more reactive towards nucleophilic addition reactions.

Additionally, steric hindrance around the electrophilic carbon atom can also affect its reactivity towards nucleophilic addition reactions. Compounds with bulky substituents around the electrophilic carbon atom may have hindered access to the carbon atom by nucleophiles, reducing the reaction rate. Conversely, compounds with less steric hindrance around the electrophilic carbon atom will be more reactive towards nucleophilic addition reactions.

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The value of k i.e. rate constant indicate the reaction is very fast. In this case, it is the first-order reaction.

The higher value in this case is the order of 12. The unit of k is (1/time) i.e. (1/s). The rate expression is given as follows

[tex]r_{A}=\frac{dC_{A}}{dt}=-kC_{A}..............(1)dC = -kdt..............................(2)[/tex]

If we consider the case of CA, for example, either Iodide ions as their concentration are small as compared to BrO3- and hydrogen ions, then iodide ion concentration is decreasing very fast.

Similar is the case for others. So, it increases the rate of reaction of the order of 12. The rate of disappearance of reactants mentioned in the table is almost high and it shows nearly the same value of k.

2. The rate of reaction is based on the concentration of the limiting reactant.

The rate of reaction is given by the following expression. Integrating equation(2) from initial concentration (CA0) to final concentration (CA),

[tex]\int_{C_{A0}}^{C_{A}}-\frac{dC_{A}}{C_{A}} = k\int_{0}^{t}dt-ln\frac{C_{A}}{C_{A0}}=kt[/tex]

There is no information about the initial concentration of reactants (CA0) i.e. initial volume of stock solution for each of the reactants.

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The complete question is:

Rates of Chemical Reactions: A Clock Reaction tab/-R e p o r t Name Time MTWRF Reaction # k" k, 3.68 x 10,2 Explain why values for these four reactions should all be approximately equal: Use the k above and the reactant concentrations from Part A to predict the relative rate and time (t) for reaction mixture #5 (show work): trek" relative rateprekted

The concentration of sulfate ion required to begin precipitation of BaSO₄ is [tex]1.1 x 10^{-8} M[/tex]. Any concentration of sulfate ion greater than this will result in precipitation of BaSO₄.

The solubility product constant (Ksp) is an equilibrium constant that represents the concentration of the ions in a saturated solution at a given temperature. When the concentration of any ion exceeds the Ksp, the excess ions begin to form a solid, and precipitation occurs. For BaSO₄, the Ksp value is [tex]1.1 x 10^{-10}[/tex] at 25°C.

To calculate the concentration of sulfate ion required to begin precipitation of BaSO₄, we can use the Ksp expression and the initial concentration of barium ion:

Substituting the given concentration of barium ion (0.010 M) and the Ksp value, we get:

Therefore, the concentration of sulfate ion required to begin precipitation of BaSO₄ is [tex]1.1 x 10^{-8}[/tex] M. Any concentration of sulfate ion greater than this will result in precipitation of BaSO₂.

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The pH of the given solution is 2.74 at 25°C. The pH of a solution of 0.20 M HNO2 containing 0.10 M NaNO2 at 25°C can be calculated using the Ka value of HNO2. HNO2 is a weak acid and dissociates in water to form H+ and NO2-.

The Ka expression for this reaction is Ka = [H+][NO2-]/[HNO2]. Since the concentration of NaNO2 is much larger than that of HNO2, we can assume that the concentration of HNO2 does not change significantly due to the dissociation. Therefore, we can use the initial concentration of HNO2 in the Ka expression. Substituting the given values into the expression and solving for [H+], we get [H+] = 1.8 × 10^-3 M. Taking the negative logarithm of this value gives the pH of the solution, which is approximately 2.74.

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Three items that will change the solubility of a solute into a solvent are:

1. Temperature - increasing temperature typically increases the solubility of solids in liquids, but can decrease the solubility of gases in liquids.

2. Pressure - increasing pressure can increase the solubility of gases in liquids.

3. Polarity - solutes that have similar polarity to the solvent are more likely to dissolve.

Three ways to increase the speed with which a solute dissolves are:

1. Stirring or agitating the solution to increase the surface area of the solute in contact with the solvent.

2. Increasing the temperature of the solvent, which can increase the kinetic energy of the solvent molecules and the solute particles, leading to more frequent collisions and faster dissolution.

3. Grinding or crushing the solute to decrease the particle size and increase the surface area in contact with the solvent.

Here O2 is the limiting reactant and the corresponding theoretical yield of water is 3.00 g of H_2O

Here 0.23 moles of acetic acid and 8 grams of oxygen gas are placed in a reaction vessel and a combustion reaction takes place.

To find out the limiting reactant and corresponding theoretical yield of water, we need to solve this question by following the below steps:

Step 1: Balanced chemical equation for the combustion of acetic acid.`2C2H4O2 + 6O2 → 4CO2 + 4H2O`

Step 2: Find the molar mass of each compound.`

Molar mass of C2H4O2 = (2 x 12.01) + (4 x 1.01) + (2 x 16.00) = 60.05 g/mol

Molar mass of O2 = (2 x 16.00) = 32.00 g/mol

`Step 3: Calculate the number of moles of each compound.`Moles of C2H4O2 = 0.23 mol

Moles of O2 = (8 g / 32.00 g/mol) = 0.25 mol

Step 4: Determine the limiting reactant. The limiting reactant is the reactant that is completely consumed in the reaction.

Moles of C2H4O2 = 0.23 mol

Moles of O2 = 0.25 mol

Now 2C2H4O2 + 6O2 → 4CO2 + 4H2O

Therefore, O2 is the limiting reactant.

`Step 5: Next we have to calculate the theoretical yield of water.Theoretical yield is the maximum amount of product that can be produced from the limiting reactant.`Moles of O2 = 0.25 mol

We can see that for every 6 moles of oxygen, we get 4 moles of water .So, for 0.25 moles of oxygen, we get the following amount of water:(4/6) x 0.25 = 0.1667 moles of water

Molar mass of H2O = (2 x 1.01) + 16.00 = 18.02 g/mol

Theoretical yield of water = Number of moles of water x Molar mass of water`= 0.1667 mol x 18.02 g/mol = 3.00 g of H2O`So,

The limiting reactant is O2 and the corresponding theoretical yield of water is 3.00 g of H_2O.

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The answer is Solution!

Explanation:

Solution is a homogeneous mixture

of two or more substance. In a

sugar solution, sugar gets uniformly

mixed with water

From the calculations, we can see that the number of moles of the oxygen molecules that is present is 21.2 moles.

The moles refers to the n umber of the elementary entities that we have in the substances and in this case we are dealing with the number of moles that we have in the oxygen molecule here.

We know that;

1 mole of O2 contains 6.02 * 10^23 molecules

x moles of the O2 contains 1.275 X 10^25 molecules of O₂

x = 21.2 moles

Thus what we have is about 21.2 moles of oxygen

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The molarity of the sodium bicarbonate solution is 11.2 M.

We need to know the amount of sodium bicarbonate (NaHCO₃) dissolved in a given volume of solution to calculate its molarity. Let's assume that we have dissolved 1 tsp (teaspoon) of NaHCO₃ in a solution.

According to the problem, 1 tsp = 4.9 mL. We need to convert the volume into liters:

4.9 mL = 4.9/1000 L = 0.0049 L

Now we need to know the amount of NaHCO₃ in moles that is dissolved in this volume of solution. The molar mass of NaHCO₃ will be 84.01 g/mol. Let's assume that the NaHCO₃ is pure and completely dissolved in the solution.

We can use the following formula to calculate the molarity of the solution:

Molarity (M) = moles of solute/liters of solution

moles of NaHCO₃ = mass of NaHCO₃ / molar mass of NaHCO₃

Assuming 1 tsp of NaHCO₃ is equivalent to 4.6 g (which is the approximate weight of 1 tsp of NaHCO₃), we can calculate the moles of NaHCO₃:

moles of NaHCO₃ = 4.6 g / 84.01 g/mol = 0.0548 moles

Now we substitute the values into formula for molarity:

Molarity (M) = 0.0548 moles / 0.0049 L

= 11.2 M

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