The melting point of a substance is the temperature at which the particles have enough ___ energy to break free from the ___ phase and enter the ___ phase.

Answer:

The balanced chemical equation for the reaction is:

C + 2H2 → CH4

From the equation, we can see that 1 mole of carbon reacts with 2 moles of hydrogen to produce 1 mole of methane. Therefore, to produce 7.8 moles of methane, we would need:

1 mole of carbon = 1 mole of CH4 / 2 moles of H2 = 1/2 mole of CH4

7.8 moles of CH4 = 7.8 × (1/2) moles of C = 3.9 moles of C

Now, we can use the molar mass of carbon to convert moles to grams:

Atomic mass of carbon (C) = 12.01 g/mol

3.9 moles of C × 12.01 g/mol = 46.8 g of C

Therefore, we need 46.8 grams of carbon to produce 7.8 moles of methane (CH4). Rounded to the nearest tenth, the answer is 46.8 grams.

HNO3 and HBr can also be used instead of the provided acids (h2so4 and h3po4) to isolate solid copper in this experiment. Solid copper can be isolated by reacting it with acid. This is achieved in two stages: stage one, where copper reacts with sulfuric acid to produce copper sulfate and hydrogen gas, and stage two, where copper sulfate is reduced to copper using hydrogen gas.  

Therefore, in part b of the experiment, H2SO4 and H3PO4 are used. HNO3 and HBr can also be used instead of H2SO4 and H3PO4 to isolate solid copper. H2S and H2CO3 cannot be used as the acids to isolate solid copper. 'Hence, the correct options are : HNO3 and HBr Therefore, both HBr and HNO3 could be used in place of the acids (H2SO4 and H3PO4) to isolate solid copper in part b of this experiment.

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5.0 moles of O2 will form 10.0 moles of MnO. Rounded to the tenths place, the answer is: 10.0 mol MnO

10.0 mol Mn react with 5.0 mol O2.

2.5 mol O2 are needed to react with 7.0 mol Mn.

The balanced chemical equation for the reaction between Mn and O2 is:

2 Mn + O2 → 2 MnO

According to the stoichiometry of the equation, 2 moles of Mn react with 1 mole of O2 to form 2 moles of MnO. Therefore, 7.0 moles of Mn will react with:

(5.0 mol O2) / (1 mol O2/2 mol Mn) = 10.0 mol Mn

This means that there is an excess of Mn, and the limiting reactant is O2. From the balanced equation, 1 mole of O2 reacts with 2 moles of MnO to form 2 moles of MnO. Therefore, 5.0 moles of O2 will react with:

(5.0 mol O2) / (1 mol O2/2 mol MnO) = 10.0 mol MnO

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Since ascorbic acid creates a compound with 1,10-phenanthroline that can be detected and analysed using spectrophotometry, spectroscopic approaches are made possible. Hence, choice d is the right one.

A typical reducing agent found in fruits and vegetables is ascorbic acid. Its chemical makeup enables it to join forces with the substance 1,10-phenanthroline, which is frequently employed in spectrophotometry. Spectrophotometry may be used to identify and measure the very stable, colourful complex that is created when ascorbic acid and 1,10-phenanthroline react. A strong analytical method called spectrophotometry quantifies the quantity of light at a particular wavelength that is absorbed by a sample. The amount of ascorbic acid in a sample may be measured by measuring the complex's absorbance at a certain wavelength.

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Among the given options, the statement that is NOT correct is "B. An object of high temperature is placed into the calorimeter."

An object of high temperature is placed into the calorimeter is not correct. Calorimetry is a process that measures the heat released or absorbed during a chemical or physical change. It involves an insulated container holding a liquid, usually water. The temperature change of the object and the water will be equal. The heat absorbed by the water is equal to the heat lost by the object. Calorimetry is an experimental method used to measure the heat energy produced or absorbed during a chemical or physical change. Calorimetry works on the principle of heat transfer between a reaction or physical process and a heat sink or calorimeter. Calorimetry involves an insulated container holding a liquid, usually water, and a thermometer used to measure the change in temperature of the water caused by the addition of heat. When heat is added to or removed from a system, it causes a temperature change in the system. Calorimetry is used in various fields such as food and beverage, medical research, material science, and others.

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In each of the following situations, the intensity of the interaction differs for charged particles.

a. The distance between the charges increases. (decreases)

b. The size of the charge decreases. (increases)

a. The strength of the interaction between charged particles decreases as the distance between them increases. This is because the force between charged particles follows an inverse square law, which means that the force decreases with the square of the distance between the charges. Therefore, as the distance between the charges increases, the force between them decreases and the strength of the interaction decreases.

b. The strength of the interaction between charged particles increases as the size of the charge decreases. This is because the force between charged particles is directly proportional to the magnitude of the charge. Therefore, as the size of the charge decreases the force between the charged particles decreases and the strength of the interaction decreases.

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The mass (in grams) of ammonium chloride, NH₄Cl needed to produce 2.5 L of a 0.5M aqueous solution is 66.88 grams

First, we shall determine the mole of ammonium chloride, NH₄Cl. Details below:

Molarity = Mole / Volume

Cross multiply

Mole of ammonium chloride, NH₄Cl = molarity × volume

Mole of ammonium chloride, NH₄Cl = 0.5 × 2.5

Mole of ammonium chloride, NH₄Cl = 1.25 mole

Finally, we shall determine the mass of ammonium chloride, NH₄Cl needed. Details below:

Mass = Mole × molar mass

Mass of ammonium chloride, NH₄Cl = 1.25 × 53.5

Mass of ammonium chloride, NH₄Cl = 66.88 grams

Therefore,  we can conclude that the mass of ammonium chloride, NH₄Cl is 66.88 grams

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The Lewis acid is the one that accepts electrons from the donor atom. Option 'b' [tex]BCl_3[/tex] is the Lewis acid of the following options.  

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Your primary concern should be the safety of the emergency responders and the general public. You should choose a staging location that is upwind from the area of possible contamination and far enough away to protect people from any potential hazard.

The wind direction is critical in chemical emergencies because hazardous chemicals can be carried by the wind. As a result, emergency responders and those affected by a chemical release need to be aware of the direction in which the wind is blowing to avoid exposure to the chemicals.

For example, if the wind is blowing toward the emergency vehicle, it could put the emergency responders in danger. Similarly, if the wind is blowing toward a residential area, it could pose a threat to the public's health and safety.

As you approach the scene of a possible release of a chemical into the air, the primary concern in regard to the location where you stage the emergency vehicle should be the wind direction.

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Answer: carbon and hydrogen 

Explanation:

Hydrocarbons are a group of chemical organic compounds composed of carbon and hydrogen 

Atomic interactions between their subatomic particles cause bonds between them to form and break during chemical processes. The protons and neutrons that make up the positively charged nucleus of an atom are surrounded by negatively charged electrons.

The quantity and configuration of an atom's electrons determines its chemical characteristics. The electrons participate in the production or breaking of bonds during chemical processes. Two or more atoms share or exchange electrons to create a more stable electron configuration in a chemical bond. The electron configuration of the atoms involved is altered when a bond is broken because electrons are either shared or transferred to another atom.Chemical bonds are formed and broken by interactions between electrons and the protons and neutrons in the nuclei of the atoms. For instance, in a covalent bond, two atoms share a pair of electrons that are drawn to their mutually attractive positively charged nucleus.

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The resulting KCl solution in water is known as an electrolyte solution because it contains free-moving ions, which can transmit electricity.

When KCl (potassium chloride) is dissolved in water, the resulting solution is classified as an electrolyte solution. An electrolyte solution is a solution that contains dissolved ions, which can conduct an electric current. KCl is an ionic compound that dissociates in water to form potassium ions (K+) and chloride ions (Cl-), which are free to move and carry electrical charge.

The ability of KCl to dissolve and dissociate in water is due to its ionic nature, where the electrostatic attraction between oppositely charged ions is weakened by the water molecules, which surround and solvate the ions. This allows the ions to move freely in solution and interact with other ions.

The conductivity of the resulting KCl solution is dependent on the concentration of ions in the solution, which is influenced by factors such as temperature, pressure, and the presence of other ions. The resulting solution may also be classified as a strong electrolyte, as it completely dissociates into ions in water, or a weak electrolyte if only a portion of the compound dissociates.

Overall, the resulting solution of KCl in water is classified as an electrolyte solution, which can conduct electricity due to the presence of free-moving ions.

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During the formation of a water molecule, we focus on the oxygen atom. In hybridization of H2O, the oxygen atom is sp3hybridized.

In a CE run, the electroosmotic flow in a fused-silica capillary decreases as the pH of the running buffer is decreased. Hence, C is the right response. It weakens.

In capillary electrophoresis (CE), the buffer solution moves through the capillary as a result of an electric field, or electroosmotic flow (EOF). The characteristics of the buffer, notably its pH, have an effect on how quickly EOF occurs. In particular, the concentration of H+ ions in the buffer rises when the pH is dropped, which results in a decrease in the surface charge of the capillary wall. The result is a weakening of the buffer's contact with the capillary wall, which lowers electroosmotic mobility and slows down the process of the flow of electroosmosis.

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The answer to this question is D) specific heat. When determining the energy change associated with a change in temperature, specific heat is a factor that is unique to each substance.

Specific heat- Specific heat is the amount of heat that must be added or removed from a unit of mass of a substance to increase or decrease its temperature by one degree Celsius or Kelvin. The amount of heat required to alter the temperature of a material varies depending on the nature of the substance. As a result, specific heat is a factor that is unique to each substance.

D) specific heat is correct because it is the unique factor for each substance when calculating the energy change associated with a change in temperature.

In conclusion, it is important to consider that when determining the energy change associated with a change in temperature, specific heat is a factor that is unique to each substance.

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The enzyme aconitase catalyzes the isomerization of citrate followed by a dehydration reaction.

Isomerization is a process in which a molecule undergoes a structural change, but the molecular formula remains the same. In this case, citrate is converted into isocitrate, which is an important step in the citric acid cycle.

Aconitase is a member of the iron-sulfur protein family that contains a [4Fe-4S] cluster, and it is involved in catalyzing the isomerization of citrate in the citric acid cycle. This enzyme has two active sites, one of which is responsible for the isomerization reaction, and the other is responsible for the dehydration reaction.

Aconitase works by binding to the citrate molecule and causing it to undergo a structural change. This results in the formation of an intermediate molecule called cis-aconitate. The dehydration reaction is then catalyzed by the enzyme, which removes a molecule of water from the cis-aconitate to produce isocitrate.

The reaction catalyzed by aconitase is important because it helps to generate energy for the cell. The citric acid cycle is a metabolic pathway that is used by cells to generate ATP, which is the primary source of energy for cellular processes. The isomerization of citrate is a critical step in this pathway because it helps to convert the energy stored in food molecules into a form that can be used by the cell.

Therefore, the correct answer is option e) isomerization; dehydration.

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The partial pressure of carbon dioxide on Venus is approximately 86.85 atmospheres.

If the atmospheric pressure on Venus is approximately 90 times greater than the pressure on Earth, and carbon dioxide makes up 96.5% of the Venusian atmosphere, we can calculate the partial pressure of carbon dioxide on Venus.

Let's assume the pressure on Earth is 1 atmosphere (atm). Then, the atmospheric pressure on Venus would be 90 atm.

To find the partial pressure of carbon dioxide on Venus, we multiply the total atmospheric pressure by the fraction of carbon dioxide in the atmosphere:

Partial pressure of carbon dioxide on Venus = Total atmospheric pressure on Venus * Fraction of carbon dioxide in the atmosphere

Partial pressure of carbon dioxide on Venus = 90 atm * (96.5 / 100)

Partial pressure of carbon dioxide on Venus = 90 atm * 0.965

Partial pressure of carbon dioxide on Venus ≈ 86.85 atm

Therefore, the partial pressure of carbon dioxide on Venus is approximately 86.85 atmospheres.

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The actual absolute zero temperature in degrees Celsius is 273.15.

Experimental Value of Absolute Zero for Sample 1: -283.6°C

Percent Error for Sample 1: |(-283.6 - (-273.15)) / (-273.15)| x 100 = 3.8%

Experimental Value of Absolute Zero for Sample 2: -288.7°C

Percent Error for Sample 2: |(-288.7 - (-273.15)) / (-273.15)| x 100 = 5.7%

Using Sample 1:

P = 1.2 atm

V = 22.0 mL

n = (P * V) / (R * T)

n = (1.2 * 0.0220) / (0.0821 * (12+273))

n = 0.00075 mol

Using Sample 2:

P = 1.2 atm

V = 20.0 mL

n = (P * V) / (R * T)

n = (1.2 * 0.0200) / (0.0821 * (12+273))

n = 0.00069 mol

Conclusion:

The experimental absolute zero value for Sample 1 was -283.6°C with a percent error of 3.8% and for Sample 2 was -288.7°C with a percent error of 5.7%. The experimental absolute zero values were close to the accepted value of -273.15°C, with Sample 1 being closer than Sample 2. Therefore, the data supports the hypothesis that the relationship between volume and temperature of an ideal gas can be used to determine absolute zero.

Possible sources of error that could have impacted the results of this lab include experimental error in measuring the volume and temperature, as well as deviations from ideal gas behavior due to factors such as intermolecular forces.

The investigation can be explored further by testing the effects of changes in pressure and number of moles on the relationship between volume and temperature in ideal gases.

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The final temperature in the tank will be 320°C because it is equalized with the large vessel holding steam and the final mass in the tank is 0.216 Kg as determined by the Ideal Gas Law.

The final temperature in the tank will be 320°C. This is because the tank is connected to a large vessel holding steam at 15 bar and 320°C. The pressure and temperature in the tank will equalize to the pressure and temperature of the large vessel.

The final mass in the tank can be determined using the Ideal Gas Law equation:
PV = nRT
where, P = pressure (15 bar). V = volume (0.4 m³), n = number of moles of gas, R = ideal gas constant (8.314 J/mol K), and T = temperature (320°C)

n = PV/RT
n = (15 × 0.4)/(8.314 × (320+273.15))
n = 0.012 moles

The final mass in the tank will be 0.012 moles of gas × the molar mass of water (18.015 g/mol).
Therefore, the final mass in the tank will be 0.216 kg.

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The molecular geometry based on the description of bonding and lone pairs are as follows:

- Three double bonds and no lone pairs of electrons: linear

- Four single bonds and no lone pairs of electrons: tetrahedral

- Two double bonds and no lone pairs of electrons: bent/angular

- Three single bonds and one lone pair of electrons: trigonal pyramidal

- Five single bonds and no lone pairs of electrons: trigonal bipyramidal

- Six single bonds and no lone pairs of electrons: octahedral

- Two single bonds and two lone pairs of electrons: bent/angular

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A stoichiometric mixture is a mixture of reactants in the correct mole ratio for a particular chemical reaction. This means that there are exactly enough reactants present to completely react with each other, with no excess or unreacted reactants remaining.

One way to recognize a stoichiometric mixture in a chemical reaction is to calculate the mole ratio of the reactants and compare it to the balanced chemical equation for the reaction. If the mole ratio matches the coefficients in the balanced chemical equation, then it is a stoichiometric mixture.

Another way to recognize a stoichiometric mixture is to monitor the reaction as it progresses. When the reaction is complete, there should be no excess reactants present, and the amounts of the products formed should correspond exactly to the balanced chemical equation.

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The correct answer is D.  The presence of a heterogeneous catalyst will not affect the molecularity of the overall chemical equation or the molecularity of the rate-determining step.
What is a heterogeneous catalyst?

A heterogeneous catalyst is a substance that boosts the speed of a chemical reaction by providing a surface on which the reactant molecules may collide.

This increases the possibility of a chemical reaction and speeds it up. The catalyst is in a different phase than the reactants in a heterogeneous catalytic reaction.

The reaction between them happens only at the phase boundary since the reactant molecules are adsorbed onto the catalyst's surface.

There are two types of catalyst : homogeneous catalyst and Heterogeneous catalyst . homogeneous having same phase whi Heterogeneous catalyst having different phase.

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9.27 × 10⁻¹⁹ J and -2.18 × 10⁻¹⁸ J is  the average kinetic and potential energies of an electron in the ground state of a hydrogen atom.

In order to calculate the average kinetic and potential energies of an electron in the ground state of a hydrogen atom, we can use the following equations:

Kinetic energy: K = (1/2)mv²

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

Potential energy: U = -E

where E is the energy of the electron, which can be found using the equation:

E = -13.6/n²

where n is the principal quantum number for the electron in the ground state of the hydrogen atom.

So, we need to find the mass and velocity of the electron. The mass of an electron is approximately 9.11 × 10⁻³¹ kg, and the velocity can be found using the equation:

v = (Zke²/r)m

where Z is the atomic number of hydrogen (1), k is Coulomb's constant, e is the elementary charge, and r is the Bohr radius, which is equal to 0.529 Å.

Substituting these values, we get:

v = (1 × 8.99 × 10⁹ N·m²/C² × 1.60 × 10⁻¹⁹ C² / (0.529 × 10⁻¹⁰ m)) / (9.11 × 10⁻³¹ kg) = 2.18 × 10⁶ m/s

Now, we can use these values to calculate the average kinetic energy:

K = (1/2)mv² = (1/2)(9.11 × 10⁻³¹ kg)(2.18 × 10⁶ m/s)² = 9.27 × 10⁻¹⁹ J

And the potential energy:

U = -E = -(-13.6 eV) = 13.6 eV × 1.60 × 10⁻¹⁹ J/eV = -2.18 × 10⁻¹⁸ J

Therefore, the average kinetic energy is 9.27 × 10⁻¹⁹ J and the average potential energy is -2.18 × 10⁻¹⁸ J.

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A physical and mental impairment resulting from the use of alcohol is called Alcohol Use Disorder (AUD).

AUD is a chronic disease characterized by a preoccupation with alcohol, increased tolerance to it, and physical dependence on it. Symptoms include intense cravings, withdrawal, and a loss of control over drinking. Long-term effects of AUD include liver damage, poor mental and physical health, and an increased risk of developing certain types of cancer. Treatment for AUD often involves therapy and medication to help with withdrawal symptoms, cravings, and the physical and mental impairments resulting from the use of alcohol.

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Here are six processes in which materials change from one form to another:

Melting - When a solid material is heated, it may change into a liquid form.

Freezing - When a liquid material is cooled, it may change into a solid form.

Evaporation - When a liquid material is heated, it may change into a gaseous form.

Condensation - When a gaseous material is cooled, it may change into a liquid form.

Sublimation - When a solid material is heated, it may change directly into a gaseous form without going through the liquid phase.

Deposition - When a gaseous material is cooled, it may change directly into a solid form without going through the liquid phase.

In all of these processes, the chemical composition of the material remains the same, but its physical form changes. For example, ice (solid water) can melt to become liquid water, which can then evaporate to become water vapor (a gas).

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The correct Lewis structure for the OH⁻ ion consists of an oxygen atom that has two lone pairs of electrons and one bonded pair of electrons. Therefore, the correct option is C.

The OH⁻ ion is a negatively charged polyatomic ion, and it is composed of an oxygen atom (O) and a hydrogen atom (H). The valence electrons present in these two atoms are given as follows: H atom: 1 valence electron and O atom: 6 valence electrons.

Hence, the total number of valence electrons in the OH⁻ ion is: 1 + 6 + 1 = 8. Now, let's follow the below steps to draw the Lewis structure for the OH⁻ ion: Step 1: Determine the central atom. In the OH⁻ ion, the oxygen atom is the central atom.

Step 2: Connect the atoms using single bonds. In the OH⁻ ion, the hydrogen atom is connected to the oxygen atom via a single bond.

Step 3: Add lone pairs of electrons around each atom. According to the octet rule, the oxygen atom should have eight electrons around it. Out of the eight valence electrons, two electrons are in the bond, and the remaining six electrons are added as two lone pairs of electrons. The hydrogen atom has two valence electrons, and it has no electrons left to add to complete its octet. So, the final Lewis structure for the OH- ion is as follows: 

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Yes, this is a good idea as it is an efficient use of resources. Advantages include reduced costs of purchasing new drying agents and decreased wastage of materials. Disadvantages could include loss of quality of the recycled drying agent, and extra energy used to dry out the salt.

Drying agents can be collected after an experiment and the hydrated salt heated in an oven to drive off the water. The recycled drying agent can then be used again for another experiment.

What are drying agents?

In order to absorb water vapor, drying agents are added to organic solvents to make them anhydrous.

What are the advantages and disadvantages of recycling drying agents?

The recycling of drying agents has a few advantages and disadvantages:

Advantages of recycling drying agents:

Cost-effective: If the solvent used is expensive, recycling drying agents can save money. A drying agent like anhydrous magnesium sulfate is a good example since it can be reused numerous times. No pollution: The disposal of waste is reduced. If every time a new drying agent is employed, it must be disposed of properly, which is both time-consuming and costly. The amount of waste that has to be disposed of is reduced if the same drying agent is used repeatedly. Recyclable waste: Used drying agents are recyclable. It's just a matter of heating the salt to remove any water and returning it to the drying agent stock. This procedure helps to prevent waste.

Disadvantages of recycling drying agents:

Contamination: Even though the recycled drying agent is supposed to be pure, it may still contain minor quantities of impurities, which might result in contamination of the final product. Impurities: If the drying agent is not cleaned properly, impurities will be transferred from one experiment to the next. Excessive heating: Anhydrous drying agents should not be heated excessively because they may lose their effectiveness. If the salt is heated for too long, the surface area exposed to moisture will be decreased. Therefore, while recycling drying agents is a good idea, some precautions should be taken to ensure that the drying agent is pure and effective.

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The molar concentration of the hydrochloric acid (HCI) solution is 0.500 mol/dm³.

The balanced chemical equation for the reaction between hydrochloric acid (HCI) and strontium hydroxide (Sr(OH)2) is shown below:

2HCl(aq) + Sr(OH)2(aq) → SrCl2(aq) + 2H2O(l)

2 moles of HCl react with 1 mole of Sr(OH)2 to produce 1 mole of SrCl2 and 2 moles of water.

We find the  number of moles of Sr(OH)2 in the sample:

moles of Sr(OH)2 = concentration of Sr(OH)2 × volume of Sr(OH)2 solution

= 0.020 mol/dm³ × 0.2500 dm³

= 0.005 mol

The number of moles of HCl used in the titration can be calculated as:

moles of HCl = 2 × moles of Sr(OH)2

= 2 × 0.005 mol

= 0.010 mol

Calculating the molar concentration (molarity) of the HCl solution taking into account the volume of the HCl solution used in the titration is 20.0 cm³

molarity of HCl = moles of HCl / volume of HCl solution

= 0.010 mol / 0.0200 dm³

= 0.500 mol/dm³

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