methane decomposes into two simpler substances, hydrogen and carbon. therefore, methane is a(n) .

The molar mass of the unknown monoprotic organic acid is 180.0 g/mol. by titration. If 6.12 ml of the naoH solution is required to neutralize the sample.

In order to determine the molar mass of the unknown monoprotic organic acid, follow the steps given below:

Step 1:

Calculate the number of moles of NaOH used in the titration by using the formula given below:

n(NaOH) = M(NaOH) × V(NaOH)

= 0.157 mol/L × 0.00612 L

= 9.62 × 10^-4 mol

Step 2:

Calculate the number of moles of the acid used in the titration by using the formula given below:

n(acid) = n(NaOH)

= 9.62 × 10^-4 mol

Step 3:

Calculate the mass of the acid used in the titration by using the formula given below:

mass(acid) = n(acid) × M(acid) = 0.173 gM(acid) = mass(acid) / n(acid)

= 0.173 g / 9.62 × 10^-4 mol

= 180.0 g/mol

Therefore, the molar mass of the unknown monoprotic organic acid is 180.0 g/mol.

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The empirical formula of the compound that produces 330 g of carbon, 69.5 g of hydrogen, and 440.4 g of oxygen upon decomposition is CHO2.

The empirical formula of a compound is the simplest whole-number ratio of atoms present in it. Follow the below steps to calculate the empirical formula of the given compound: Calculate the mass of each element present in the compound.

Calculate the mole of each element present in the compound by dividing its mass by its atomic mass. Determine the mole ratio by dividing each mole value by the smallest mole value obtained. Rearrange the ratio obtained in step 3 in the form of whole numbers. Moles of hydrogen/moles of oxygen = 69.5/27.5 = 2.53 ≈ 2.5Moles of oxygen/moles of oxygen = 27.5/27.5 = 1Therefore, the mole ratio of carbon: hydrogen: oxygen = 1: 2.5: 1Rearranging the above ratio to whole numbers, we get the mole ratio of carbon: hydrogen: oxygen as 2: 5: 2. The empirical formula of the compound is therefore CHO2.

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The combination of elements that are required for a compound to be considered organic are carbon and hydrogen. The correct answer among the given options is carbon and hydrogen.

Organic compounds are the fundamental components of life and are classified by the presence of carbon atoms, which are covalently linked to one another and to other elements such as oxygen, nitrogen, and sulfur, as well as by the lack of ionic bonding.

To summarize, an organic compound is a compound that contains carbon atoms bonded to hydrogen atoms, among other elements, in a covalent bond. The majority of organic compounds contain a carbon-carbon bond, which is the foundation of organic chemistry.

The following are some examples of organic compounds:

Methane, CH4

Ethanol, C2H5OH

Ethanoic acid, CH3COOH

Acetone, (CH3)2CO

Amino acid glycine, NH2CH2COOH

As a result, the correct combination of elements that are required for a compound to be considered organic are carbon and hydrogen.

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4.83 x 10^24 atoms are there in 32.10 g of He.

To determine the number of atoms in 32.10 g of He, we first need to convert the mass to moles using the atomic mass of He, which is 4.003 g/mol.

number of moles of He = 32.10 g / 4.003 g/mol = 8.024 mol He

Next, we use Avogadro's number, which is 6.022 x 10^23 atoms/mol, to calculate the number of atoms in 8.024 mol of He:

8.024 mol He x 6.022 x 10^23 atoms/mol = 4.83 x 10^24 atoms

Therefore, there are approximately 4.83 x 10^24 atoms in 32.10 g of He.

Atoms are the fundamental matter units that comprise everything around us, from the air we breathe to the food we consume. They are made up of three different sorts of particles: protons, neutrons, and electrons.

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Answer: Different isotopes of the same sample have different scattering signals in neutron experiments due to their varying neutron cross-sections.

The term neutron scattering refers to a type of scattering in which neutrons collide with a target material, resulting in the emission of secondary particles. Because the neutron is a subatomic particle, it cannot be directly detected.

The effect of its presence, however, can be seen in the pattern of scattered secondary particles. Neutrons are scattered in much the same way that light is, except that they are much less affected by surface roughness and other surface-related issues.

This implies that neutron scattering is a more efficient tool for investigating material microstructures than other kinds of scattering. Neutron scattering's biggest advantage is its sensitivity to the atomic nuclei of a sample's constituent atoms.

Neutrons, unlike other subatomic particles, have no electric charge, making them less likely to be deflected by the electrons surrounding atomic nuclei, and more likely to penetrate deep into a sample's interior.

As a result, neutron scattering may reveal information about the locations and movements of atomic nuclei in materials that is inaccessible to other methods. Cross-sections of neutron scattering: The cross-section of a neutron scattering material is the probability of a neutron scattering off that material.

In other words, it's the ratio of the number of neutrons scattered per second per unit area of material to the number of neutrons striking the material per second per unit area.

Because the probability of a neutron scattering off a given isotope varies based on the neutron's energy and the isotopes present, the cross-section of a sample's individual isotopes influences the total neutron scattering signal produced by the sample.

Different isotopes of the same sample have different scattering signals in neutron experiments due to their varying neutron cross-sections.

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Magnesium carbonate breaks down into solid magnesium (MgO) & gaseous carbon dioxide in the aforementioned mechanism, which is a chemical property (CO2).

In these equations, chemical reactions are represented by chemical formulae and symbols. Chemical equations have two sides: the reactants are on the left, and the products are on the right.

Chemical equations represent the transformation of reactants into products in this process. Take the combination of iron (Fe) with sulfur (S) to create iron sulfide as an example. Fe(s) = S(s) + FeS (s) Iron and sulfur react, as indicated by the plus symbol.

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The activation energy for a forward reaction is not the same as the activation energy for the reverse of the same reaction. It is because of the reason that activation energy is the energy needed for a reaction to occur.

The energy barrier for a forward reaction is distinct from the energy barrier for a backward reaction. The energy required to break bonds in the reactants is known as activation energy.

Only those molecules with sufficient kinetic energy can overcome the activation energy barrier and form new products. The energy that must be overcome in order to transform reactants into products is referred to as activation energy. If the activation energy for a reaction is lower, the reaction will proceed more quickly than if it were higher.

The activation energy of a forward reaction is not the same as the activation energy of a reverse reaction since the energy requirements for each reaction are unique.

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Organic molecules are those that contain carbon and often hydrogen atoms bonded together, and they are the building blocks of life.

Carbon is an element that is essential to life on Earth and is the central atom in organic compounds. It can form covalent bonds with other elements such as hydrogen, oxygen, nitrogen, and sulfur.

Carbon has the unique ability to form long chains of molecules, branched structures, and rings that are essential to the structure and function of organic molecules.

Organic molecules include carbohydrates, lipids, proteins, and nucleic acids. Carbohydrates are sugars and starches that provide energy to living organisms.

Lipids are fats and oils that are important for insulation and energy storage. Proteins are complex molecules that carry out many functions in the body, such as catalyzing chemical reactions and providing structure to cells.

Nucleic acids are DNA and RNA, which carry genetic information and are essential for the synthesis of proteins.

Oxygen is another element that is essential to life on Earth. It is often found in organic molecules, especially in carbohydrates and lipids.

Oxygen is important for respiration, the process by which living organisms use energy stored in organic molecules to carry out cellular processes.

In respiration, oxygen reacts with organic molecules such as glucose to produce carbon dioxide, water, and energy in the form of ATP.

Organic molecules contain carbon and often hydrogen atoms bonded together, and they are the building blocks of life.

Carbon has the unique ability to form long chains of molecules, branched structures, and rings that are essential to the structure and function of organic molecules.

Oxygen is another element that is often found in organic molecules and is important for respiration.

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It is important not to dilute the initial sample before loading it onto the chromatography column because this can negatively impact the separation and resolution of the components in the sample.

Dilution can lead to a decrease in the concentration of the components in the sample, which can result in poor separation and overlap of the peaks. Additionally, dilution can cause loss of the target compound or impurities in the sample due to adsorption onto the walls of the container used for dilution.

By keeping the sample concentrated and loading it directly onto the chromatography column, the chances of obtaining a clear separation and good resolution of the components in the sample are increased

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The molarity of the first solution containing 0.500 mol of NaOH in 2.30 l of the solution is 0.217 M.

The molarity of a solution is defined as the number of moles of solute per liter of solution. In order to calculate the molarity of the given solution, we need to divide the number of moles of solute by the volume of the solution given in liters. Using the formula for molarity, we have;

Molarity = Number of moles of solute / Volume of solution in liters

Given, Number of moles of solute = 0.500 mol

Volume of solution = 2.30 L

Substitute the values of the given information into the molarity formula; Molarity = 0.500 mol / 2.30 L = 0.217 M

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Phenolphthalein is a commonly used indicator in acid-base titrations because it changes color at a pH around 8.2-10.0.

Phenolphthalein itself is a weak acid and has a specific equilibrium between its acidic and basic forms. When added to an acidic solution, it is predominantly in the acidic form and colorless. As the titration progresses and the solution becomes more basic, the equilibrium shifts towards the basic form which is pink.

The amount of indicator used in the titration should be kept to a minimum to avoid affecting the accuracy of the results. Using too much indicator can affect the stoichiometry of the reaction, leading to inaccurate results.

Therefore, only a small amount of phenolphthalein, typically two drops, is used to minimize its impact on the titration while still providing a clear visual indication of the endpoint.

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The reaction has reached its equivalence point once it is complete.

To determine if the reaction has reached its equivalence point once the reaction is complete, we must first calculate the moles of each compound:

HCl moles = 1.0 M x (10.0 mL / 1000 mL/L) = 0.01 mol

NaOH moles = 2.0 M x (5.0 mL / 1000 mL/L) = 0.01 mol

The two compounds react in a 1:1 ratio.

There are now no more moles of HCl or NaOH left to react since they have equal moles.

We can thus conclude that the reaction has reached its equivalence point as soon as the reaction is over. Since the moles of both HCl and NaOH have been completely neutralized, the pH at the equivalence point is 7.

This indicates that the reaction has reached its equivalence point once it has finished.

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using many methods I gess I am not good at drawing

the radioactive decay of c14 which is used in estimating the age of archaeological  after 2500 years, 0.0027 mol of c14 remain in the sample.

The amount of c14 remaining after 2500 years can be calculated using the first-order rate equation:

N(t) = N0 * e^(-kt)

where N0 is the initial amount of c14, N(t) is the amount remaining after time t, k is the decay constant, and e is the base of the natural logarithm. The half-life of c14 is given as 5725 years, which means that k can be calculated as:

k = ln(2)/t1/2 = ln(2)/5725

Substituting the values given in the problem, we get:

k = ln(2)/5725 = 1.21 * 10^-4 /year

Now, we can use the rate equation to find the amount of c14 remaining after 2500 years:

N(2500) = 0.0035 * e^(-1.21*10^-4 * 2500) = 0.0027 mol

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Answer: In the movie Dark Waters, the call from the Kigers is significant because it leads to the discovery of a link between unexplained cattle deaths and pollution caused by the chemical company DuPont.

Explanation: In the movie Dark Waters, the call from the Kigers is the key moment that sets off the plot. The Kigers, who are farmers in West Virginia, call Robert Bilott, a corporate defense attorney, and ask for his help in investigating the strange deaths of their cattle. Bilott is reluctant to take on the case at first, but he eventually agrees to visit the Kigers' farm and see the situation for himself.

During his visit, Bilott discovers that the Kigers are just one of many families in the area who have experienced unexplained deaths and illnesses among their livestock, as well as health problems among their own family members. Bilott begins to suspect that the cause of these health issues is pollution from a nearby chemical plant owned by DuPont, a multinational chemical company.

Bilott takes on the case and begins a long and difficult legal battle against DuPont, uncovering evidence that the company had long known about the dangers of the chemicals it was using - specifically a substance called PFOA, which was used in the production of Teflon - but had covered up the evidence and misled regulators and the public about the risks.

In the end, the call from the Kigers is significant because it leads to the discovery of a link between unexplained cattle deaths and pollution caused by DuPont, and sets off a series of events that ultimately lead to the exposure of corporate wrongdoing and the pursuit of justice for those affected by the pollution. The Kigers' call is a catalyst for change, prompting Bilott to take action and exposing the truth about a powerful and deceitful corporation.

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The concentration of perchlorate ion in the solution that has a ph of 3.158 is 7.9 × 10−4 M.

Perchloric acid has the chemical formula HClO4. When it dissolves in water, it completely dissociates into H+ ions and ClO4- ions. The pH of a solution is defined as the negative logarithm of the hydrogen ion concentration [H+].A perchloric acid solution with a pH of 3.158 has an [H+] of 7.9 × 10−4 M, according to the following formula:

pH = −log [H+]

The concentration of the perchlorate ion [ClO4-] can be calculated using the following formula:

Kw = [H+][OH-] = 1 × 10-14 = [H+]2[H+] = 1 × 10-14[H+] = √(1 × 10-14) = 1 × 10-7M[OH-] = Kw/[H+] = (1 × 10-14) / (1 × 10-7) = 1 × 10-7M

The concentration of ClO4- is equal to the concentration of H+ because they are present in equal amounts as a result of complete dissociation of perchloric acid: [ClO4-] = [H+] = 7.9 × 10−4 M.

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In 1.2 x [tex]10^{24}[/tex] formula units of [tex]Li_{2} (SO)_{4}[/tex], there are roughly 1.993 moles of

[tex]Li_{2} (SO)_{4}[/tex].

Using Avogadro's number, or 6.022 x [tex]10^{23}[/tex] molecules/mol, we can calculate the number of moles of Li2SO4 in 1.2 x [tex]10^{24}[/tex]formula units.

First, we need to figure out how many moles of [tex]Li_{2} (SO)_{4}[/tex]  are needed to equal 1.2 x [tex]10^{24}[/tex]  formula units:

Formula units equal 6.022 x [tex]10^{23}[/tex] per mole of [tex]Li_{2}(SO)_{4}[/tex].

As a result, there are: 1.2 x [tex]10^{24}[/tex] moles of [tex]Li_{2}(SO)_{4}[/tex] in the formula units.

1.993 moles are equal to 1.2 x [tex]10^{24}[/tex] formula units / 6.022 x [tex]10^{23}[/tex] formula units/mol.

Hence, 1.2 × [tex]10^{24}[/tex] formula units of [tex]Li_{2} (SO)_{4}[/tex] contain about 1.993 moles.

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2.62 moles of glucose can react with 15.7 moles of oxygen. The balanced chemical equation for the combustion of glucose is:

C6H12O6 + 6O2 → 6CO2 + 6H2O

From the equation, we can see that for every mole of glucose that reacts, 6 moles of oxygen are required. Therefore, the number of moles of glucose that can react with 15.7 moles of oxygen can be calculated as follows:

Number of moles of glucose = (Number of moles of oxygen) / 6

Number of moles of glucose = 15.7 / 6

Number of moles of glucose = 2.62

Therefore, 2.62 moles of glucose can react with 15.7 moles of oxygen.

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Answer:

Ra3P2

Explanation:

Ra is +2

P is -3

Ra3P2

The volume in liters of a 0.020mm barium chlorate solution that contains 375 mmol of barium chlorate is 18.75 L.

To calculate the volume of barium chlorate in liters, we can use the formula of concentration. The formula of concentration is

C = n/V

where

C = Concentration

n = moles of the solute

V = volume of the solution

To calculate the volume of the solution in liters, we need to first calculate the moles of the solute ([tex]BaCl_{2}[/tex]). We are given moles of [tex]BaCl_{2}[/tex] = 375 mmol

Now, n = 375 mmol. So, by using the formula of concentration:

C = n/VC = 0.020 mm

V = n/CV

= 375 mmol/0.020 mmV

= 18750 mL

We know that 1 L = 1000 mL. So, the volume of the solution in liters

= 18750/1000L

= 18.75 L

Thus, the volume of the solution in liters is 18.75 L.

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The molarity of the solution prepared by mixing 100.0 ml of the solution made in number 3 with 900.0 ml of 0.0250 m NaCl is 0.1225 M.

We first calculate the moles of NaCl present in 900.0 ml of 0.0250 m NaCl solution.The formula to calculate the moles of solute is given as:

Moles of solute = molarity x volume (in liters)

So, the moles of NaCl in 900.0 ml of 0.0250 m NaCl solution would be:

Moles of NaCl = 0.0250 x (900.0/1000) = 0.0225 mol

Calculate the total volume of the mixed solution.The total volume of the mixed solution would be the sum of the volumes of the two solutions used in the mixing process.Total volume of mixed solution = 100.0 ml + 900.0 ml = 1000.0 ml or 1.0 L

Calculate the total number of moles of NaCl in the mixed solution.Total moles of NaCl in the mixed solution = moles of NaCl in 900.0 ml of 0.0250 m NaCl solution + moles of NaCl in 100.0 ml of the solution made in number 3

Total moles of NaCl in the mixed solution = 0.0225 mol + 0.100 mol = 0.1225 mol

Calculate the molarity of the mixed solution.The molarity of the mixed solution would be the number of moles of solute present in the solution per liter of solution.

Molarity of the mixed solution = Total moles of NaCl in the mixed solution / Total volume of the mixed solution

Molarity of the mixed solution = 0.1225 mol / 1.0 L = 0.1225 M

Therefore, the molarity of the solution prepared by mixing 100.0 ml of the solution made in number 3 with 900.0 ml of 0.0250 m NaCl is 0.1225 M.

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(+61.3) is the specific rotation of pure (s)-carvone if a sample of (r)-carvone of 85% ee has a specific rotation of -52.

A chiral chemical compound's unique rotation is a characteristic in chemistry. It is described as the shift in monochromatic plane-polarized light's orientation, expressed as the product of distance and concentration, as the light passes through a sample of a substance dissolved in solution. Dextrorotary substances are those that spin a plane polarised light beam's polarisation plane clockwise, and they correlate to positive specific rotation values.

[α] = α / (c×l)

[α] =specific rotation

α = observed rotation

c=concentration in g/mL

l =path length in dm

[α] = (-52)/(1×1)

    = -52

(-52) = (0.85)×αr + (0.15)×αs

αs= (-52 - 0.85×αr) / 0.15

[α] = αs

    = (-52 - 0.85αr) / 0.15

(-52) = (0.85)(+112.0) + (0.15)α

α = (+61.3)

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Answer: Phase change from solid to gas will have a more dramatic increase in entropy.

This is because gas has the highest entropy of all phases. Gas has the highest entropy because its molecules are moving randomly, and it has the greatest amount of disorder. In addition, the transition from solid to gas involves both increasing temperature and changing the arrangement of particles from an ordered solid to a disordered gas. This results in a significant increase in entropy.

Phase transition refers to the process of changing from one phase of matter to another. When a substance changes from one phase to another, its entropy changes. Entropy refers to the degree of disorder or randomness in a system, and it is related to the number of ways that a system can be arranged. When the degree of disorder increases, the entropy also increases.

In summary, phase change from solid to gas has a more dramatic increase in entropy. This is because gas has the highest entropy of all phases, and the transition from solid to gas involves both increasing temperature and changing the arrangement of particles from an ordered solid to a disordered gas, resulting in a significant increase in entropy.



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The given statement "every atom in the universe emits energy in the form of a nucleus" is False.

In the universe, every atom does not emit energy in the form of a nucleus. It is not true in the case of every atom in the universe. But it is true that every atom in the universe emits energy.

According to the Bohr model of the atom, an electron orbiting an atomic nucleus emits radiation when it changes its energy level. The radiation emitted by the electron is in the form of a photon of electromagnetic energy. This is a spontaneous process and it is called spontaneous emission. It can be said that every atom in the universe emits energy.

Therefore, it is false that every atom in the universe emits energy in the form of a nucleus.

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To determine the number of atoms in 15.0 grams of calcium, we need to calculate the molar mass of calcium.

The molar mass of calcium is 40.08 g/mol. This means that for every 1 mole of calcium, there are 40.08 grams. Since we have 15.0 grams of calcium, we can divide this by the molar mass to find the number of moles of calcium. 15.0 g / 40.08 g/mol = 0.37 moles of calcium. To find the number of atoms in 15.0 grams of calcium, we need to multiply the number of moles of calcium by Avogadro's number. 0.37 moles x 6.022 x 1023 atoms/mol = 2.223 x 1023 atoms of calcium.

Therefore, there are 2.223 x 1023 atoms of calcium in 15.0 grams of calcium.

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The solution that has the highest vapor pressure is the one with the lowest boiling point. The lower the boiling point, the higher the vapor pressure.

Vapor pressure is the pressure exerted by the vapor of a substance in equilibrium with its liquid or solid phase. When the rate of evaporation and the rate of condensation is equal, equilibrium occurs. At a particular temperature, each liquid has a distinct vapor pressure that is directly proportional to its temperature. A liquid with a low boiling point has a higher vapor pressure than one with a high boiling point.

The glucose and sucrose solutions are both nonvolatile solutes, whereas potassium acetate is a volatile solute. As a result, the potassium acetate solution has a higher vapor pressure than either the glucose or sucrose solutions. The answer is option C.10.0 g of potassium acetate in 100.0 ml of water.

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The problem can be solved using Boyle's Law. The final pressure of the gas in the cylinder is 289.31 Pa.

Boyle's law is a gas law that describes the relationship between the pressure and volume of a gas at a constant temperature. Boyle's Law states that the pressure and volume of a gas are inversely proportional when temperature is held constant. Mathematically, it can be expressed as:

P₁V₁ = P₂V₂

where P₁ and V₁ are the initial pressure and volume, and P₂ and V₂ are the final pressure and volume.

We can plug in the given values to solve for the final pressure:

P₁ = 156 Pa

V₁ = 910 mL = 0.91 L

V₂ = 490 mL = 0.49 L

P₁V₁ = P₂V₂

156 Pa × 0.91 L = P₂ × 0.49 L

P₂ = (156 Pa × 0.91 L) / 0.49 L

P₂ = 289.31 Pa

Therefore, the final pressure is 289.31 Pa.

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According to the second law of Faraday, the oxidation number of gold ions is +3.

The second law of Faraday is also known as Faraday's law of electrolysis. According to this, the quantity of a substance that is deposited or released during electrolysis is directly proportional to the amount of electric charge that is transported through the electrolyte.

Given information,

Mass of silver (Ag) deposited = 0.732 g

Mass of gold (Au) deposited = 0.446 g

According to this law,

Weight of Ag/Equivalent weight of Ag = Weight of Au/Equivalent weight of Au

0.732/108 = 0.446/196.96 × valency

Since the equivalent weight of Ag is 108g and the equivalent weight of Au is 196.96g.

0.0067 = 0.0022  × valency

Valency = 0.0067/ 0.0022

Valency = 3

Therefore, the oxidation state of the gold ion (Au⁺³) is +3.

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(a) We would need 7 pies to serve a slice of pie with each cup of hot chocolate.

(b) There would be 6 slices of pie left over.

From item 6, we know that there are 50 cups of hot chocolate to be served.

Since each pie can be cut into 8 slices, we would need to serve 50/8 = 6.25 pies.

Since we cannot serve a fractional pie, we would need to round up to the next whole number of pies, which is 7.

To find out how many slices of pie would be left over, we need to calculate the total number of slices of pie and subtract the number of slices used to serve the hot chocolate.

Total number of slices of pie = 7 pies x 8 slices per pie = 56 slices

Number of slices used to serve the hot chocolate = 50 slices

Therefore, the number of slices of pie left over would be:

56 slices - 50 slices = 6 slices

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When raising solvent temperature, solvent-solute collisions become more frequent and more energetic.

In chemistry, a solvent is a substance capable of dissolving another substance, usually a solid, liquid, or gas, to produce a homogeneous solution (mixture). The most common solvent is water, although there are other solvents that are widely used in many different industries. In a solvent, a solute is a substance that dissolves. It is usually a solid, but it can also be a liquid or a gas.

When a solute dissolves in a solvent, it forms a homogeneous solution.The solute will dissolve in the solvent when they collide. If the solute is in the solid-state, a solvent-solute collision may only occur if the solute dissolves in the solvent. The rate and frequency of solvent-solute collisions are impacted by a variety of factors, including solvent temperature. When solvent temperature is increased, the kinetic energy of solvent molecules is also increased, resulting in more frequent and energetic collisions.

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