Consider the following equation in chemical equilibrium. C2H4(g) + H2(g) mc009-1.jpg C2H6(g) + 137 kJ What happens to the amount of ethane (C2H6) when the temperature of the system is increased? The amount of ethane decreases. The amount of ethane increases initially and then decreases. The amount of ethane increases. The amount of ethane decreases initially and then increases.

Answer: chloropentane

Explanation:

When a hydrocarbon has a halogen atom, its properties will change because this group has a higher molecular weight and a higher polar moment that will be hard to defeat in order to reach the boiling point.

The Boiling point of the pentene is 30°C // pentane is 36,1°C //  2-pentanone is 101°C and chloropentane 108°C.

Simple hydrocarbons have lower boiling points compare with those with a functional group like the Oxygen in the 2-pentanone and the Chlorine in the  chloropentane. On the other heand,  Oxygen is not as electronegative and heavy like Chlorine, thus the chloropentane is the one with higher boiling point.

Final answer:

The complete combustion of 1.0 mole of C4H10 (butane) in excess oxygen will produce 4 moles of carbon dioxide (CO2).

Explanation:

To determine how many moles of carbon dioxide (CO₂) are produced when 1.0 mole of C₄H₁₀ (butane) is completely burned in excess oxygen, we need to first write and balance the chemical equation for the combustion of butane. The balanced chemical equation for the combustion of butane is:

C₄H₁₀ + 6.5O₂ → 4CO₂ + 5H₂O

This equation shows that 1 mole of butane reacts with 6.5 moles of oxygen to produce 4 moles of CO₂ and 5 moles of water (H₂O). Therefore, the complete combustion of 1.0 mole of C₄H₁₀ will produce 4 moles of carbon dioxide.

The answer is: volume of nitrogen is 70L.

Chemical reaction: N₂H₄ + O₂ → N₂ + 2H₂O.

m(N₂H₄) = 100 g; mass of hydrazine.

M(N₂H₄) = 32 g/mol; molar mass of hydrazine.

n(N₂H₄) = m(N₂H₄) ÷ M(N₂H₄).

n(N₂H₄) = 100 g ÷ 32 g/mol.

n(N₂H₄) = 3.125 mol; amount of hydrazine.

m(O₂) = 100 g; mass of oxygen.

M(O₂) = 32 g/mol; molar mass of oxygen.

n(O₂) = 100 g ÷ 32 g/mol.

n(O₂) = 3.125 mol; amount of oxygen.

From chemical reaction: n(O₂) : n(N₂) = 1 : 1; n(O₂) = n(N₂).

n(N₂) = 3.125 mol; amount og nitrogen gas.

V(N₂) = n(N₂) · Vm.

Vm = 22.4 L/mol; molar volume.

V(N₂) = 3.125 mol · 22.4 L/mol.

V(N₂) = 70 L.

There is not excess reagent, because hydrazine and oxygen are all used in chemical reaction.

Final answer:

The correct answer is "olivine". In Bowen's discontinuous reaction series, olivine is the first mineral to crystallize from a mafic melt. It later reacts to form pyroxene as the magma cools. This series helps us understand mineral crystallization and the formation of igneous rocks.

Explanation:

In Bowen's discontinuous reaction series, the first mineral to crystallize from a mafic melt is olivine. The process of crystallization in a cooling magma begins with high-temperature minerals like olivine. As the temperature of the magma decreases, different minerals begin to crystallize while others become unstable, with olivine reacting with silica to form pyroxene at lower temperatures. This reaction is represented by the equation Mg2SiO4 + SiO2 > 2MgSiO3, turning olivine into pyroxene. Through Bowen's reaction series, we understand that the crystallization of minerals removes elements such as magnesium (Mg) and iron (Fe) from the magma, altering its composition over time. These early-formed minerals are known as phenocrysts, and their formation is sequential based on the cooling of the magma. Bowen's reaction series not only informs us about mineral crystallization sequences but also about the formation of different igneous rocks and their compositions.

To find the concentrations at equilibrium, one would use the equilibrium constant (K). Given known concentrations and the stoichiometry of the reaction, one can solve for the unknown concentration. Be sure to convert all quantities to appropriate units (molarity), and remember that these calculations assume that the system is at equilibrium.

The question pertains to chemical equilibrium, particularly the equilibrium for the reaction N₂(g) + 3H₂(g) = 2NH3(g) at 500 k. It seems like there could be some missing details in the question, so I'll provide a general approach to solving problems like this.

To find the concentrations at equilibrium, we can use the concept of equilibrium constants. In this case, the equilibrium constant (K) for the reaction N₂(g) + 3H₂(g) = 2NH3(g) would be expressed as K = [NH3]² / ([N2][H2]³). Plugging in the known concentrations, one can solve for the unknown, which might be the concentration of 'b' referred to in the original question.

Note that the concentrations should be in molarity (M) units, which represent moles of solute per liter of solution. Therefore, the 3.30 m sample needs to be converted into volume (in litres) to derive the molarity given the number of moles of the substance.

Remember that calculations with equilibrium constants assume that the system has reached equilibrium, and that temperature remains constant. If the actual situation doesn't meet these conditions, more complex calculations might be needed.

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Answer:

a ) when a neutral hydrogen atom loses an electron, a positively-charged particle should remain

To calculate moles , we divide mass of the substance given by the molar mass of the substance.

That can be mathematically represented as:

[tex] Number of moles of a substance= \frac{Given mass of a substance}{ Molar mass of substance} [/tex]

Here given mass of substance is 4540 g

Molar mass of the substance is 196 g mol⁻¹

So number of moles can be calculated as:

[tex] Number of moles of a substance= \frac{Given mass of a substance}{ Molar mass of substance} [/tex]

[tex] Number of moles of gold= \frac{4540}{196} [/tex]

So number of moles of gold =23.16 mol

Answer:

Explanation:

When we react Hydrochlorid Acid with zinc we have the following reaction:

2HCl(aq) + Zn(s) --> ZnCl2(aq) + H2(g)

The hydrogen gas formed is lost to the environment, so we can affirme that in the start we have the mass for all the H, Cl and Zn atoms in the solution, but after the reaction occurs, we have only the mass for the Cl and Zn atoms.

That's why the mass is less than the original.

The law that the student was told is only applied to closed environments.

All gases at the same temperature have the same average kinetic energy. The average velocity of gases increases with decreasing molar mass. Thus, 1.0-L samples of O2 and H2 can have the same velocity because velocity is also affected by temperature.

The kinetic energy of a gas is determined by its temperature, not by the identity of the gas itself. This is explained by the Kinetic Molecular Theory. Because all four gases are at the same temperature (standard temperature), they have the same average kinetic energy.

However, the average velocity of the gases varies depending upon the molar mass of the gas. The lighter the gas (lower molar mass), the faster it moves. Thus, the order of increasing velocity is Xe < Cl2 < O2 < H2.

To answer part c, the reason why 1.0-L samples of O2 and H2 can each have the same average velocity despite being different substances is because the average velocity of a gas depends not only on its mass, but also the temperature at which it is measured. As these two samples are both at the same temperature, they can have the same average velocity.

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The final total pressure after the completion of reaction is [tex]\boxed{0.8{\text{ atm}}}[/tex].

Further Explanation:

Stoichiometry:

The amountof species present in the reaction is determined with the help of stoichiometry by the relationship between reactants and products.

Balanced chemical reaction between nitrogen and hydrogen is as follows:

[tex]{{\text{N}}_{\text{2}}} + 3{{\text{H}}_2} \to 2{\text{N}}{{\text{H}}_{\text{3}}}[/tex]  

This balanced reaction’s stoichiometry clearly indicates that one mole of nitrogen reacts with three moles of hydrogen to produce two moles of ammonia.

Since pressure is directly related to number of moles of gas, pressure required by hydrogen to react with one mole of nitrogen should be three times of pressure of nitrogen.

Therefore pressure of hydrogen can be calculated as follows:

[tex]\begin{aligned}{\text{Pressure of hydrogen}} &= 3\left( {0.600{\text{ atm}}} \right) \\&= 1.8{\text{ atm}} \\\end{aligned}[/tex]  

But pressure of hydrogen in the rigid vessel is 0.600 atm only so it behaves as limiting reactant and its amount will govern the amount or quantity of product formed (ammonia).

Since the ratio of pressures of hydrogen and ammonia is 3:2, pressure of ammonia can be calculated as follows:

[tex]\begin{aligned}{\text{Pressure of ammonia}} &= \left( {\frac{2}{3}} \right)\left( {0.600{\text{ atm}}} \right) \\&= 0.4{\text{ atm}} \\\end{aligned}[/tex]  

Pressure of unreacted nitrogen can be calculated as follows:

[tex]\begin{aligned}{\text{Pressure of unreacted nitrogen}} &= \left( {\frac{2}{3}} \right)\left( {0.600{\text{ atm}}} \right) \\&= 0.4{\text{ atm}} \\\end{aligned}[/tex]  

Therefore total final pressure after the reaction can be calculated as follows:

[tex]\begin{aligned}{\text{Total final pressure}} &= \left( {0.4 + 0.4} \right){\text{ atm}} \\&= {\text{0}}{\text{.8 atm}} \\\end{aligned}[/tex]  

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Answer details:

Grade: Senior School

Subject: Chemistry

Chapter: Mole concept

Keywords: stoichiometry, NH3, H2, N2, pressure, hydrogen, nitrogen, ammonia, 0.4 atm, 1.8 atm, 0.600 atm, 3H2, 2NH3, 0.8 atm.

Clownfish lay their eggs near sea anemones as a reproductive strategy because the anemones' stinging tentacles protect the eggs from predators.

When clownfish are ready to lay eggs, they do so near a sea anemone to leverage the anemone's natural defenses as part of their reproductive strategy.

Sea anemones have stinging tentacles that can immobilize or deter potential predators. This interaction is a classic example of mutualism, a type of symbiotic relationship between two organisms where both benefit.

For clownfish, laying eggs near the sea anemone means the eggs are protected by the anemone's stinging capabilities, which significantly reduces the likelihood of predators consuming them. The correct answer to how this is a reproductive strategy is that the sea anemone protects the clownfish's eggs from predators.

Although clownfish and anemones do have a mutually beneficial relationship overall, in this specific case, the anemone does not fertilize, nourish the eggs, or use them to lure prey, nor does it provide a resting place for clownfish.

Answer:

WRONG-the answer is TRUE

Explanation:

The molar mass of the empirical formula CH2ClO for the compound C6H12Cl2O2 is 65.476 g/mol, calculated by summing the atomic masses for carbon, hydrogen, chlorine, and oxygen.

The student is asking about the molar mass of the empirical formula for a compound with the formula C6H12Cl2O2. An empirical formula represents the simplest whole-number ratio of the elements within a compound.

For the given compound, its empirical formula is CH2ClO. To find the molar mass of this empirical formula, we sum the atomic masses of each element, adjusting for the number of atoms present. The atomic masses are approximately 12.01 g/mol for carbon (C), 1.008 g/mol for hydrogen (H), 35.45 g/mol for chlorine (Cl), and 16.00 g/mol for oxygen (O).

The calculation is as follows:

Adding them together, the molar mass of the empirical formula CH2ClO is:

12.01 + (2 \\u00d7 1.008) + 35.45 + 16.00 = 65.476 g/mol.

Therefore, the molar mass of the empirical formula for the compound is 65.476 g/mol.

Final answer:

Hydrogen bonding affects the physical properties of substances such as water and carboxylic acids by increasing their boiling point, melting point, solubility, heat capacity, surface tension, and viscosity due to the additional attractive intermolecular forces these bonds provide.

Explanation:

Hydrogen bonding significantly influences the physical properties of substances. These intermolecular forces occur when a hydrogen atom bonded to a strongly electronegative atom, like oxygen or nitrogen, is attracted to another electronegative atom in a nearby molecule. This attraction leads to a type of bond that, while not as strong as a covalent bond, significantly affects a substance's physical characteristics.

For instance, in water molecules, hydrogen bonds form between the positively charged hydrogen atom of one molecule and the negatively charged oxygen atom of another. This results in a network of bonds that increase the melting point and boiling point of water, compared to what would be expected based on its molecular weight alone. It's also the reason why water has a high heat capacity, surface tension, and viscosity.

In the case of carboxylic acids, hydrogen bonding allows these molecules to dimerize (form pairs), which enhances their boiling points and makes them more soluble in water than comparable hydrocarbons. When carboxylic acids dissolve in water, the hydrogen bonding facilitates the interaction between acid molecules and water, which is crucial for their dissolution and the resultant physical properties.

Final answer:

Energetic coupling in a cell is demonstrated when the energy from an exergonic reaction, like ATP hydrolysis (Equation 1), is used to drive an endergonic reaction, such as the phosphorylation of glucose (Equation 3). ment.

Explanation:

Energetic coupling is a process where the energy released by an exergonic reaction (such as ATP hydrolysis) is used to drive an endergonic reaction, making the coupled process energetically favorable. To identify energetic coupling, we look for equations that pair an exergonic reaction with an endergonic reaction.

Equation 1: ATP + H2O → ADP + Pi; ΔG1 = –7 kcal/mol. This equation represents the hydrolysis of ATP, an exergonic reaction releasing energy.

Equation 3: glucose + Pi → glucose-6-phosphate + H2O; ΔG3 = +3.3 kcal/mol. This equation represents the endergonic process of phosphorylating glucose, which requires input of energy.

The coupling of ATP hydrolysis (Equation 1) to drive the phosphorylation of glucose (Equation 3) in cellular metabolism demonstrates energetic coupling. Here, the energy released from ATP is used to phosphorylate glucose, a process critical for cellular metabolism and an example of how cells harness energy from exergonic reactions to power endergonic reactions. Such coupling is central to cellular bioenergetics and metabolic pathways.

Final answer:

To find the amount of AgNO₃ consumed, calculate the moles of NaCl present in 78 g and use the one-to-one mole ratio of the reactants to determine the moles and then the mass of  AgNO₃ consumed, which is 226.86 grams.

Explanation:

To calculate how much  AgNO₃ is consumed in the reaction with 78 g of NaCl, we first need to understand the stoichiometry of the reaction. The balanced chemical equation is:

NaCl (aq) +  AgNO₃ (aq) → AgCl (s) + NaNO₃ (aq)

This indicates that 1 mole of NaCl reacts with 1 mole of  AgNO₃ to produce 1 mole of AgCl and 1 mole of NaNO₃.

First, we must examine the reaction stoichiometry, which is a one-to-one ratio. Therefore, we need to calculate the number of moles of NaCl:

Since the stoichiometry is one-to-one, the moles of NaCl will equal the moles of  AgNO₃ that react:

Therefore, 226.86 grams of  AgNO₃ is consumed when 78 grams of NaCl react.

Answer: The ionization of pure water forms hydroxide and hydronium ions.

Explanation:

Ionization is a reaction in the pure water in which water breaks down into its constituting ions that hydronium ion and hydroxide ions.

[tex]H_2O+H_2O\rightleftharpoons H_3O^++OH^-[/tex]

One molecule of water looses its proton to form hydroxide ion and l=the lost protons get associated with another water molecule to form hydronium ion.

Answer: 100.

Explanation:

1) The subscripts to the right of each element (symbol) in the chemical formula tells the number of atoms of that element present in one unit formula.

2) The unit formula of C₄H₄S₂ is equal to 1 molecule.

3) Therefore, there are 4 carbon atoms, 4 hydrogen atoms and 2 sulfur atoms in each molecule of C₄H₄S₂.

4) Then, you just have to multiply the corresponding subscript of the element times the number of molecules (25 in this case) to find the number of atoms of that kind.

5) These are the calculations for each element in the molecule C₄H₄S₂.

i) C: 4 × 25 = 100

ii) H: 4 × 25 = 100

iii) S: 2 × 25 = 50.

6) The question is about H only, so the answer is that there are 100 hydrogen atoms in 25 molecules of C₄H₄S₂.

Answer : The energy evolved in the reaction is 1499.52 kJ

Explanation :  Given,

Mass of Fe = 197 g

Molar mass of Fe = 56 g/mole

Enthalpy of reaction = -852 kJ

First we have to calculate the moles of Fe.

[tex]\text{ Moles of Fe}=\frac{\text{ Mass of Fe}}{\text{ Molar mass of Fe}}=\frac{197g}{56g/mole}=3.52moles[/tex]

Now we have to calculate the energy evolved in the reaction.

From the balanced chemical reaction we conclude that,

As, 2 mole of Fe evolved energy = 852 kJ

So, 3.52 mole of Fe evolved energy = [tex]\frac{3.52}{2}\times 852kJ[/tex]

                                                         = 1499.52 kJ

Therefore, the energy evolved in the reaction is 1499.52 kJ