What is the molecular formula of a compound that has 6 carbon atom, 8 hydrogen atoms, and 2 oxygen atoms?

Final answer:

The volume occupied by 15.6 g of H2O(g) at 36.2 degrees Celsius and 1.25 atm can be calculated using the Ideal Gas Law. The volume is approximately 18.13 liters.

Explanation:

To find the volume occupied by 15.6 g of H2O(g) at 36.2 degrees Celsius and 1.25 atm, we can use the Ideal Gas Law, which is PV = nRT. Here, P is the pressure, V is the volume, n is the number of moles, R is the gas constant, and T is the temperature in Kelvin.

First, we convert the mass of water to moles:

Next, we convert the temperature from degrees Celsius to Kelvin:

Now we can plug these values into the Ideal Gas Law:

So, the volume occupied by 15.6 g of H2O(g) at 36.2 degrees Celsius and 1.25 atm is approximately 18.13 liters.

To complete the chart, we need to determine the number of valence electrons for each element. Starting from Period 1, we place electrons in the subshells according to the periodic table.

Start at Period 1 of Figure 2.8.2. Place two electrons in the 1s subshell (1s²). Proceed to Period 2 (left to right direction). Place the next two electrons in the 2s subshell (2s²) and the next six electrons in the 2p subshell (2pº).

12 moles of ammonia  can be made.

In chemistry, a mole, sometimes spelled mole, is a common scientific measurement unit for significant amounts of very small objects like atoms, molecules, or other predetermined particles.

Given that

1 mole N₂  required 2 mole NH₃

6 mole N₂ required  x mole NH₃

x=2×6/1= 12 mole.

Thus,12 moles of ammonia  can be made.

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A positively charged ion, or cation, results when an atom loses electrons, resulting in more protons than electrons. In this case, the ion with 38 protons and 36 electrons carries a 2+ charge due to the excess of two protons.

In an atom, the number of protons determines the atomic number and identifies the element. Normally, an atom is neutral, having the same number of protons and electrons. However, when an atom gains or loses electrons, it becomes an ion and carries a charge. In the case of your ion, it has 38 protons and 36 electrons. The positive protons outnumber the negative electrons by two, so your ion carries a 2+ charge.

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To determine the concentrations of the HCl and NaOH solutions, we can use the concept of titration.

To determine the concentrations of the HCl and NaOH solutions, we can use the concept of titration. In the first titration, 27.5 ml of NaOH was used to titrate 100.0 ml of HCl. From this, we can determine the concentration of HCl using the balanced chemical equation:

HCl + NaOH -> NaCl + H2O

By using the given information and the equation, we can determine that the concentration of HCl is 0.500 M. Similarly, in the second titration, 18.4 ml of NaOH was used to titrate 50.0 ml of 0.0782 M H2SO4. By using the balanced chemical equation:

NaOH + H2SO4 -> NaHSO4 + H2O

Therefore, the concentrations of the HCl and NaOH solutions are 0.500 M and 0.168 M, respectively.

Constructing the ICE table for acid-dissociation  of sulfurous acid

 H₂SO₃ --> H⁺ + HSO₃⁻

I    0.163 M      0        0

C     - x           + x       + x

E   0.163 - x    + x       + x

Writing the acid dissociation expression  of sulfurous acid,

Kₐ = [H⁺ ][ HSO₃⁻]/ [H₂SO₃]

Plugging in the values we get,

\frac{x²}{(0.163 - x)} = 1.7 x 10⁻²

Since 1.7 x 10⁻² is small we can ignore x in the denominator,

\frac{x²}{0.163}  = 1.7 x 10⁻²

x = 0.052640 M  

pH = 1.28  

Thus the pH of a 0.163 M aqueous solution of sulfurous acid is 1.28.

The pH of a 0.163 M sulfurous acid solution is calculated by considering only the first dissociation step due to the significantly larger first acid-dissociation constant. The concentration of H+ ions is found by solving the equilibrium expression of dissociation, leading to the calculation of pH with the negative logarithm of the H+ concentration.

To calculate the pH of a 0.163 M aqueous solution of sulfurous acid, we must consider its acid-dissociation constants. Sulfurous acid is a diprotic acid with two dissociation steps. The first dissociation constant (Ka1) is significantly larger than the second (Ka2), which means that the first dissociation step will contribute the most to the hydronium ion concentration [H+] in solution. Due to the relatively large Ka1, we can approximate that the contribution from the second dissociation is insignificant for the calculation of pH in a 0.163 M H2SO3 solution.

The dissociation of H2SO3 can be represented as follows:

Since Ka1 > Ka2, we focus on Ka1 for the pH calculation. The dissociation can be described by the equilibrium expression:

Ka1 = [H+][HSO3-] / [H2SO3]

Assuming x represents the equilibrium concentration of H+ and HSO3-, the equation becomes:

Ka1 = (x)(x) / (0.163-x) ≈ (x2) / (0.163)

Solving for x yields the concentration of H+, and the pH is calculated using the equation pH = -log[H+].

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The total heat needed to heat ice from -12°C to 0°C, melt the ice at 0°C, and heat the liquid water from 0°C to 27°C is 2778 J.

To calculate the total heat needed for the three processes, we need to calculate the heat needed for each process separately and then add them together.

Heating the ice from -12°C to 0°C

The heat needed for this process can be calculated using the following equation:

Q = m * C * ΔT

where:

Q is the heat in Joules (J)

m is the mass of the ice in grams (g)

C is the specific heat capacity of ice in Joules per gram degree Celsius (J/g°C)

ΔT is the change in temperature in degrees Celsius (°C)

The mass of the ice is 5.88 g, the specific heat capacity of ice is 2.09 J/g°C, and the change in temperature is 12°C (from -12°C to 0°C). Substituting these values into the equation above, we get:

Q = 5.88 g * 2.09 J/g°C * 12°C = 147.47 J

Melting the ice at 0°C

The heat needed to melt the ice can be calculated using the following equation:

Q = m * Δh_fus

where:

Q is the heat in Joules (J)

m is the mass of the ice in grams (g)

Δh_fus is the latent heat of fusion of ice in Joules per gram (J/g)

The latent heat of fusion of ice is 6.02 kJ/mol. We need to convert the mass of the ice to moles first.

0.327 moles = 5.88 g / 18.0 g/mol

Substituting the mass of the ice in moles and the latent heat of fusion into the equation above, we get:

Q = 0.327 moles * 6.02 kJ/mol = 1.96653 kJ = 1966.53 J

Heating the liquid water from 0°C to 27°C

The heat needed for this process can be calculated using the following equation:

Q = m * C * ΔT

where:

Q is the heat in Joules (J)

m is the mass of the liquid water in grams (g)

C is the specific heat capacity of liquid water in Joules per gram degree Celsius (J/g°C)

ΔT is the change in temperature in degrees Celsius (°C)

The mass of the liquid water is 5.88 g, the specific heat capacity of liquid water is 4.184 J/g°C, and the change in temperature is 27°C (from 0°C to 27°C). Substituting these values into the equation above, we get:

Q = 5.88 g * 4.184 J/g°C * 27°C = 663.82 J

Total heat

The total heat needed for all three processes is:

Q_total = Q_1 + Q_2 + Q_3 = 147.47 J + 1966.53 J + 663.82 J = 2777.82 J

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To remedy overly acidic soil, use lime to raise pH, add organic matter like compost, and monitor pH levels regularly for optimal plant growth..

To remedy soil that is overly acidic (low pH), gardeners can take several steps to raise the pH to a more neutral or slightly acidic range, which is typically better for most plants.

Here’s how you can do it:

1. Test the Soil pH: Use a soil pH testing kit or send a sample to a lab to determine the current pH level accurately. This will help you gauge how much adjustment is needed.

2. Add Lime: Lime is the most common amendment used to raise soil pH. There are two main types:

Follow the application rates recommended based on your soil test results. Lime should be worked into the soil thoroughly for best results.

3. Use Wood Ash: Wood ash from hardwoods (like oak or maple) can also raise soil pH because it contains potassium carbonate. However, its use should be limited and monitored due to its high alkalinity and potential to raise pH too much if over-applied.

4. Add Organic Matter: Incorporating organic matter like compost, well-rotted manure, or peat moss can help buffer pH levels and improve soil structure over time. While organic matter alone won't drastically change pH, it can make the soil more hospitable to plants that prefer slightly acidic conditions.

5. Avoid Aluminum Sulfate and Ammonium-Based Fertilizers: These can lower pH levels, so they should be avoided in soils that are already acidic.

6. Monitor and Retest: After making amendments, retest the soil periodically (every few months or at least annually) to monitor pH levels and make adjustments as necessary.

7. Consider Plant Preferences: Some plants prefer acidic soils (e.g., blueberries, azaleas), so make sure the pH adjustments align with the needs of the plants you intend to grow.

By carefully applying these methods, gardeners can gradually raise the pH of overly acidic soil to create a more balanced environment for healthy plant growth.

The half-cell reaction with the most positive standard half-cell potential (E°) has the greatest tendency to occur at the cathode since it contains the strongest oxidizing agent.

In an electrochemical cell, the half-cell reaction that has the greatest tendency to occur at the cathode is the one with a more positive standard half-cell potential (E°). The cathode is the site of reduction in an electrochemical cell. The half-cell with the higher E° has the highest tendency because it has the strongest oxidizing agent (reactant species in the half-cell reaction). This is because according to the electrochemical series, the stronger the oxidizing agent, the more positive the E°.

For instance, if you compare the silver(I)/silver(0) half-reaction to the copper(II)/copper(0) half-reaction, the silver one would predominate at the cathode since its entry for standard potential is above the copper one, thus it has a more positive E°, and the reaction is predicted to be spontaneous (E°cathode > E°anode and so E°cell > 0).

A useful established reference for cell potential measurements is the standard hydrogen electrode (SHE), which has an assigned potential of exactly 0 V. This helps in comparing different half-cell reactions and determining which is more likely to occur at the cathode.

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The Biuret test is a simple and quick method to detect proteins in a sample, and a positive result is indicated by a color change from blue to violet or purple. The correct answer is proteins.

Biuret reagent is used to test for the presence of proteins in a sample. The Biuret test is a chemical test used to detect the presence of peptide bonds in proteins and peptides. When Biuret reagent, which contains copper(II) ions, is added to a solution containing proteins, the copper(II) ions react with the nitrogen and oxygen atoms in the peptide bonds to form a violet or purple-colored complex. This color change indicates the presence of proteins.

The Biuret reaction is not specific to proteins; it can also react with compounds that contain two or more peptide bonds. However, it is most commonly used to detect proteins in biological samples. The test is not quantitative, but it can give a rough estimate of the amount of protein present based on the intensity of the color change.

 The Biuret reagent typically consists of a solution of potassium hydroxide (KOH) and copper(II) sulfate (CuSOâ‚„). The alkaline solution (KOH) denatures the proteins, exposing the peptide bonds, and the copper(II) ions form the characteristic colored complex with the peptide bonds.

 In summary, the Biuret test is a simple and quick method to detect proteins in a sample, and a positive result is indicated by a color change from blue to violet or purple.

The pH of acid is between 0-7 on pH scale while for base pH range is from 7-14. Therefore,  the pH of solution is  1.84. pH is a unitless quantity.

pH is a measurement of amount of hydronium ion H₃O⁺ in a given sample. More the value of hydronium ion concentration, more will be the solution acidic.

On subtracting pH from 14, we get pOH which measures the concentration of hydroxide ion in a given solution. pH depend on the temperature. At room temperature pH scale is between 0 to 14. pH of neutral solution is 7.

Ka for  Co (H2O)[tex]_6[/tex]³⁺ is 1.0 ✕ 10⁻⁵

Ka = 1.0 ✕ 10⁻⁵

x²/[0.3-x]x =1.0 ✕ 10⁻⁵

Substituting all the given values in the above equation,  we get

[H+]= 0.014

The formula for calculating the pH of solution is given as

pH = -log [H+]

pH = 1.84

Therefore,  the pH of solution is 1.84.

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We need an equation that would relate the concentration of the original solution to that of the desired solution. To solve this we use the equation expressed as follows, 

M1V1 = M2V2

where M1 is the concentration of the stock solution, V1 is the volume of the stock solution, M2 is the concentration of the new solution and V2 is its volume.

M1V1 = M2V2

12.0 M x V1 = 3.50 M x 75.0 mL

V1 = 21.88 mL

Therefore, we need about 21.88 mL of the 12.0 M of hydrochloric acid solution to make 75.0 mL of the 3.50 M hydrochloric acid solution.

The amount of energy needed for a reaction to take place is called activation energy. It determines the rate at which a chemical reaction occurs.

In a potential energy diagram, the amount of energy needed for the reaction to take place is called the activation energy. Activation energy is the minimum energy required for reactant molecules to collide with sufficient energy to form a high-energy activated complex or transition state. It determines the rate at which a chemical reaction occurs, with higher activation energy leading to slower reactions and lower activation energy leading to faster reactions.

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The molarity of HCl will be "1.5 M".

Molarity,

Volume,

According to the dilution equation,

→  [tex]M_1 V_1= M_2 V_2[/tex]

or,

→       [tex]M_2=\frac{M_1 V_1}{V_2}[/tex]

By substituting the given values, we get

→             [tex]= \frac{0.500\times 30}{10}[/tex]

→             [tex]=\frac{15}{10}[/tex]

→             [tex]= 1.5 \ M[/tex]

Thus the above is the appropriate answer.

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The empirical formula of phosphorus selenide, formed from a reaction between 45.2 mg of phosphorus and selenium resulting in 131.6 mg of the compound, is P4Se3.

To determine the empirical formula of phosphorus selenide, we have to find the ratio of the number of moles of phosphorus to the number of moles of selenium. First, convert the mass of each element to moles. The molar mass of phosphorus (P) is 30.97 grams per mole, and the molar mass of selenium (Se) is 78.97 grams per mole. Thus, we have 45.2 mg of P = 0.00146 mole and 86.4 mg of Se (= 131.6 mg - 45.2 mg) = 0.0011 mole.

Then, find the smallest whole number ratio of moles of P to Se, by dividing both by the smallest amount. The ratio of P:Se is 1.33:1, which is close to 4:3 when multiplied up.

So, the empirical formula of phosphorus selenide is P4 Se3.

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Determine the empirical formula of phosphorus selenide follows steps involving mass calculations and mole conversions, leading to the empirical formula of P₄Se₃.

To determine the empirical formula of phosphorus selenide, follow these steps:

Calculate the mass of selenium in the compound:

Mass of selenium = Mass of phosphorus selenide - Mass of phosphorus

Mass of selenium = 131.6 mg - 45.2 mg = 86.4 mg

Convert the masses to moles:

Moles of phosphorus (P):

45.2 mg P × (1 g / 1000 mg) × (1 mol P / 30.97 g P) = 0.00146 mol P

Moles of selenium (Se):

86.4 mg Se × (1 g / 1000 mg) × (1 mol Se / 78.96 g Se) = 0.00109 mol Se

Determine the simplest whole number ratio of moles:

Ratio of P to Se = 0.00146 / 0.00109 ≈ 1.34

The ratio of P to Se is approximately 1.34:1. This ratio is close to the simple fraction 4/3. Therefore, the ratio is adjusted to 4:3 to yield whole numbers.

Based on this ratio, the empirical formula of phosphorus selenide is P₄Se₃.

Answer:

The empirical formula of phosphorus selenide is P₄Se₃.

Answer:

Option A = 17.03 g/mol

Explanation:

Given data:

Atomic mass of nitrogen = 14.01 g/mol

Atomic mass of hydrogen = 1.008 g/mol

Molecular mass of NH₃ = ?

Explanation:

Molecular mass of NH₃ = (14.01 g/mol × 1) + (1.008 g/mol × 3)

Molecular mass of NH₃ = 14.01 g/mol + 3.024 g/mol

Molecular mass of NH₃ =  17.03 g/mol

Ammonia consist of hydrogen and nitrogen both are nonmetals that's why ammonia is an covalent compound.

To solve this we use the dilution equation used in chemistry, 

M1 V1 = M2 V2

where M1 is the concentration of the stock solution, V1 is the volume of the stock solution, M2 is the concentration of the new solution and V2 is its volume.

M1 V1 = M2 V2

1.25 M x V1 = 0.500 M x 180 mL

V1 =72 mL of the concentrated solution

Therefore, the correct answer would be option C.

Answer : 24 atomic mass units (amu)

Explanation : Taking into consideration that the oxygen isotope has the molecular mass as 18 amu and the isotope of hydrogen will be tritium which will have the molecular mass as 3 amu.

The water molecule has two hydrogen and one oxygen; which means 2H and 1 O = [tex] H_{2}O[/tex]

So, to calculate the largest mass that a water molecule could have using other isotopes will be;

(2 X 3) + 18 = 24 amu.

So, the largest mass that a water molecule can have is 24 amu.

The largest mass that a water molecule could have using other isotopes = 24.0312

The elements in nature have several types of isotopes

Isotopes are atoms whose no-atom has the same number of protons while still having a different number of neutrons.

So Isotopes are elements that have the same Atomic Number (Proton)

Atomic mass is the average atomic mass of all its isotopes

In determining the mass of an atom, as a standard is the mass of 1 carbon-12 atom whose mass is 12 amu

So the atomic mass obtained is the mass of the atom relative to the carbon atom

[tex]\large {\boxed{mass~average~atom~X~=~ \frac {mass\: isotope ~ 1 + mass ~ isotope ~ 2} {whole ~ atom ~ X}}[/tex]

An atomic mass unit = amu is a relative atomic mass of 1/12 the mass of an atom of carbon-12.

The 'amu' unit has now been replaced with a unit of 'u' only

for example, Carbon has 3 isotopes, namely ₆C¹², ₆C¹³, and ⁶C¹⁴

To determine the largest molecular mass for air, we use the largest isotope mass of Hydrogen and Oxygen as its constituent elements

Hydrogen (1 H) has 3 stable natural isotopes, namely ₁H¹, ₁H², and ₁H³

There are also unstable isotopes obtained through the synthesis in laboratories ₁H⁴, ₁H⁵, ₁H⁶ and ₁H7⁷

While Oxygen (₁₆O) has 3 natural isotopes ₈O¹⁶, ₈O¹⁷, and ₈O¹⁸

If we use the largest mass of isotopes, we use stable isotopes ₁H³ and ₈O¹⁸ to form 1 H₂O water molecule

₁H³ = 3,016 049 amu

and the atomic mass of ₈O¹⁸ = 17,999 amu

So that the mass of the water molecule

= 2. The atomic mass of ₁H³ + 1. atomic mass ₈O¹⁸

= 2. atomic mass of 3,0161 amu + 17,999 amu

= 24.0312

Water itself has no atomic mass, because water is a molecule

And we should be able to distinguish between the number of mass and atomic mass

The subatomic particle that has the least mass

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The balanced equation for the reaction between sodium carbonate and nickel(II) chloride is Na2CO3(aq) + NiCl2(aq) -> NiCO3(s) + 2NaCl(aq). This means one molecule of sodium carbonate reacts with one molecule of nickel(II) chloride to produce a molecule of nickel(II) carbonate and two molecules of sodium chloride.

The chemical reaction between aqueous sodium carbonate (Na2CO3) and aqueous nickel(II) chloride (NiCl2) can be represented and balanced as follows:

This balanced molecular equation indicates that one molecule of aqueous sodium carbonate reacts with one molecule of aqueous nickel(II) chloride to produce one molecule of solid nickel(II) carbonate and two molecules of aqueous sodium chloride.

In terms of phases, the sodium carbonate and nickel(II) chloride start as aqueous (dissolved in water) compounds, while the produced nickel(II) carbonate is solid, and the sodium chloride is still aqueous.

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From a reaction equation, check the enthalpy change (ΔH). Negative ΔH represents an exothermic reaction (heat producing) while positive ΔH relates to endothermic reaction (heat absorbing). Other methods include reaction diagrams, bond energies, and Hess's Law.

An exothermic reaction, which produces heat, will have a negative ΔH, as the bonds in the products are stronger than the bonds in the reactants. This implies that energy is released during the reaction. For instance, when heat (q) is negative in a calorimetric determination, this suggests an exothermic process is taking place, and thermal energy is transferred from the system to its surroundings.

On the other hand, an endothermic reaction, which consumes heat, will have a positive ΔH, as the bonds in the products are weaker than the ones in the reactants. This indicates that energy is absorbed during the reaction. If heat (q) is positive in a calorimetric determination, it signifies that an endothermic process is happening, with thermal energy being transferred from the surroundings to the system.

Furthermore, reaction diagrams, bond energies, and Hess's Law can be applied to predict and calculate the enthalpy changes for reactions, thus determining whether they are exothermic or endothermic.

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The mass of oxygen required to react with 7.6 g of ethanol is 5.3 g.

This problem is a stoichiometric problem. To solve problems like this we always begin with the balanced equation. Then, we use the stoichiometric ratios provided by the coefficients of the reactants and products.

1. Write the balanced chemical equation.

CH₃CH₂OH + O₂ → H₂O + CH₃COOH

2. Convert the mass of oxygen to moles.

[tex]7.6 \ g \ CH_3CH_2OH \times \frac{1 \ mol CH_3CH_2OH}{46.07 \ g} = 0.165 \ mol \ CH_3CH_2OH\\[/tex]

3. Determine the equivalent moles of oxygen that reacts with the given quantity of ethanol. The stoichiometric ratio for ethanol and oxygen indicated in the balanced chemical equation is 1:1.

[tex]moles \ O_2 = 0.165 \ mol \ CH_3CH_2OH \times \frac{1 \ mol O_2}{ 1 \ mol CH_3CH_2OH}\\\\moles \ O_2 = 0.165 \ mol \ O_2[/tex]

4. Convert the moles of O₂ to mass.

[tex]mass \ of \ O_2 = 0.165 \ mol \ O_2 \times \frac{32 \ g}{1 \ mol \ O_2 }\\\\\boxed {mass \ of \ O_2 \ = 5.28 \ g}[/tex]

The answer required should only have 2 significant digits. Therefore, the final answer is:

[tex]\boxed {\boxed {mass \ of \ O_2 \ = 5.3 \ g}}[/tex]

To calculate the mass of oxygen gas consumed by the reaction of 7.6g of ethanol, we need to convert the mass of ethanol to moles, and then use the balanced chemical equation to determine the moles of oxygen gas. Finally, we convert moles of oxygen gas to grams.

To calculate the mass of oxygen gas consumed by the reaction of 7.6g of ethanol, we first need to convert the mass of ethanol to moles. Ethanol has a molar mass of 46.06 g/mol, so we divide 7.6g by the molar mass to get 0.165 moles of ethanol. The balanced chemical equation shows that for every 1 mole of ethanol, 3 moles of oxygen gas are consumed. Therefore, we multiply the moles of ethanol by the ratio of moles of oxygen gas to moles of ethanol (3/1) to get 0.495 moles of oxygen gas. Finally, we convert moles of oxygen gas to grams by multiplying by the molar mass of oxygen gas (32.00 g/mol), giving an answer of 15.8g of oxygen gas consumed.

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