Calculate the percent composition of Zn and Cu in your penny

a) If the partial pressure of CO2 is increased, the equilibrium will tend to shift towards the formation of products (C6H12O6 and O2) to reduce the concentration of CO2.

(b) If the system is compressed, the equilibrium will tend to shift towards the formation of products (C6H12O6 and O2) to reduce the number of gas molecules.

What is Equilibrium?

In chemistry, equilibrium is a state in a chemical reaction where the rate of the forward reaction is equal to the rate of the reverse reaction. At equilibrium, the concentrations of the reactants and products remain constant over time, although the reactants are still being converted into products and vice versa.

When a system is at equilibrium, the concentrations of reactants and products are said to be in balance. This means that the concentrations of the reactants and products are no longer changing, even though the reaction is still ongoing. At equilibrium, the concentrations of reactants and products are related by a constant called the equilibrium constant (K), which depends on the specific reaction conditions such as temperature and pressure.

c) If the amount of H2O is increased, the equilibrium will tend to shift towards the formation of products (C6H12O6 and O2) to consume the excess water.

(d) If the temperature is increased, the equilibrium will tend to shift towards the formation of products (C6H12O6 and O2) because the reaction is endothermic and increasing the temperature favors the endothermic reaction.

(e) If some of the O2 is removed, the equilibrium will tend to shift towards the formation of products (C6H12O6 and O2) to compensate for the loss of O2.

(f) If water is added, the equilibrium will tend to shift towards the formation of reactants (CO2 and H2O) to consume the excess water.

(g) If the partial pressure of O2 is decreased, the equilibrium will tend to shift towards the formation of reactants (CO2 and H2O) to compensate for the loss of O2.

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1. The mass of magnesium oxide produced would be 6630.5 g.

2. The formula of the iron oxide would be Fe2O3.

1. Calculation of magnesium oxide produced:

The balanced chemical equation for the reaction of magnesium with oxygen is:

2 Mg + O2 → 2 MgO

For 2 g of magnesium:

Number of moles of Mg = mass / molar mass = 2 / 24.31 = 0.082 moles

According to the balanced equation, 2 moles of Mg produce 2 moles of MgO

Therefore, 0.082 moles of Mg will produce 0.082 moles of MgO

Mass of MgO = number of moles of MgO * molar mass of MgO = 0.082 * 40.31 = 3.29 g

For 10 g of magnesium:

Number of moles of Mg = mass / molar mass = 10 / 24.31 = 0.411 moles

According to the balanced equation, 2 moles of Mg produce 2 moles of MgO

Therefore, 0.411 moles of Mg will produce 0.411 moles of MgO

Mass of MgO = number of moles of MgO * molar mass of MgO = 0.411 * 40.31 = 16.54 g

For 4 kg of magnesium:

Number of moles of Mg = mass / molar mass = 4000 / 24.31 = 164.5 moles

According to the balanced equation, 2 moles of Mg produce 2 moles of MgO

Therefore, 164.5 moles of Mg will produce 164.5 moles of MgO

Mass of MgO = number of moles of MgO * molar mass of MgO = 164.5 * 40.31 = 6630.5 g or 6.63 kg

2. Calculation of formula of iron oxide produced:

The balanced chemical equation for the reaction between iron and oxygen is:

4 Fe + 3 O2 → 2 Fe2O3

According to the equation, 4 moles of Fe react with 3 moles of O2 to produce 2 moles of Fe2O3. Therefore, the molar ratio of Fe to O2 is 4:3.

Given that 0.4 moles of Fe react with 0.3 moles of O2, the ratio of Fe to O2 in the reaction is:

Fe:O2 = 0.4/0.3 = 4/3

This ratio is equivalent to the molar ratio in the balanced equation, which means that the reaction produces the stoichiometric amount of Fe2O3. Therefore, the formula of the iron oxide produced is Fe2O3.

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The pair which are miscible liquids are the correct option is water and the ethanol.

The Miscible liquids are the liquids that are dissolve in the each other and will  form the homogeneous mixture and the  immiscible liquids are the liquids in which the liquids that will not mix well in the each other. The Alcohol and the water are the miscible liquids and the  oil and the water are the immiscible pair of the liquids.

Therefore, the water and the ethanol are the miscible liquids as they both are dissolve in each other of the other and will forms the homogeneous mixture.

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The amount of SO₂(g) in the reaction vessel has a lower value compared to its value at the original equilibrium. Option d is correct choice.

Injecting pure O₂(g) into the reaction vessel at a constant temperature will cause the system to shift towards the right side of the equation in order to consume the added O₂. This means that the amount of SO₂(g) in the reaction vessel will decrease, while the amount of SO₃(g) and O₂(g) will increase.

Since the reaction is exothermic, adding O₂(g) will not change the equilibrium constant (Keq) of the reaction, so (A) is not affected. However, the amount of O₂(g) in the reaction vessel will increase, so (C) has a higher value compared to its value at the original equilibrium.

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--The complete question is, 2SO(g) <-> 2SO₂(g) + O₂(g)

After the eq. represented above is established, some pure O₂(g) is injected into the reaction vessel at a constant temperature. After equilibrium is reestablished, which of the following has a lower value compared to its value at the original equilibrium?

A. Keq for the reaction

B. The amount of SO₃(g) in the reaction vessel

C. The amount of O₂(g) in the reaction vessel.

D. The amount of SO₂(g) in the reaction vessel.--

The given statement "A neutral atom of the element given by the symbol ca will to become an ion with a complete outer shell " is true because this is to complete the octet rule.

The atomic number of the calcium, Ca is 20. The neutral calcium atom, has the  20 protons and the 20 electrons, and it readily loses the two electrons. This will results in the cation with the 20 protons, the 18 electrons, with the charge of  2+ charge. Calcium has the same number of the electrons as the atoms of the preceding the noble gas, the argon, and the symbol is  Ca²⁺. The calcium ion is more stable than the calcium neutral atom.

Thus ca loose the 2 electrons and acquire the noble gas configuration to become more special.

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Nitrogen is indeed a nonmetal as well as the lightest member of Periodic Table. 0.016mol of N[tex]_2[/tex] will be produced.

Nitrogen has the chemical symbol N and the atomic number 7. Nitrogen is indeed a nonmetal as well as the lightest member of Periodic Table Group 15, often known as the pnictogens. This is a common element inside the cosmos, with an estimated total abundance of sixth in the Milky Way.

NaNO[tex]_2[/tex](aq) + H[tex]_2[/tex]NSO[tex]_3[/tex]H(s) → NaHSO[tex]_4[/tex](aq) + N[tex]_2[/tex](g) + H[tex]_2[/tex]O(l)

moles of H[tex]_2[/tex]NSO[tex]_3[/tex]H = 1.627 /97.09=0.016mol

the mole ratio between H[tex]_2[/tex]NSO[tex]_3[/tex]H and N[tex]_2[/tex] is 1:1

moles of N[tex]_2[/tex] =0.016mol

Therefore, 0.016mol of N[tex]_2[/tex] will be produced.

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The electron configuration for the ion formed by the element magnesium, Mg is 1s²2s²2p⁶ by assuming that the octet rule is obeyed. Therefore, option A is correct.

The octet rule refers to atoms' preference for having eight electrons in their valence shell. Atoms with fewer than eight electrons are more likely to react and form more stable compounds.

The Mg atom will achieve an octet by losing its two outermost electrons and thus gaining 2+ charges, according to the octet rule. Because Mg belongs to the alkali metal group, it will lose electrons rather than gain them.

We know that when an atom completes its octet., electrons in its valence shell, it becomes stable. Now, electrons must be given out in magnesium ion valence to complete its octet.

Thus, The electron configuration for the ion formed by the element magnesium, Mg is 1s²2s²2p⁶. Option A is correct.

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Your question is incomplete, most probably your question was

assuming that the octet rule is obeyed, write out the electron configuration for the ion formed by the element magnesium, Mg

A. 1s²2s²2p⁶

B.  1s²2s²2p²

C.  1s²2s²2p₅

D.  1s²2s²2p¹

The mole ratio of one reactant to the other can be determined from the balanced chemical equation of the reaction. Here, the ratio of H₃PO₄ to water is 1 : 3.

The mole ratio of a reactant in a reaction is the ratio of its number of moles needed for the reaction to the number of moles of other reactant. The balanced chemical equation of a reaction represents the prefect stoichiometry of all the reactants and products.

The reaction between phosphoric acid and water can be written as follows:

[tex]\rm H_{3}PO_{4} + 3 H_{2}O \rightarrow PO_{4}^{-} + 3H_{3}O^{+}[/tex]

As per this balanced reaction, one mole of phosphoric acid requires 3 moles of water for complete reaction. The reaction gives one mole of phosphate ion and 3 moles of hydronium ions.

Therefore, the mole ratio of H₃PO₄ to H₂O is 1: 3.

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The theoretical yield of lead (II) nitrate obtained from the reaction is 0.50 grams

The theoretical yield of lead (II) nitrate obtained from the reaction can be obtained

PbCO₃ + 2HNO₃ -> Pb(NO₃)₂ + H₂O + CO₂

From the balanced equation above,

267.21 g of PbCO₃ reacted to produce 331.2 g of Pb(NO₃)₂

Therefore,

4.0 g of PbCO₃ will react to produce = (4 × 331.2) / 267.21 = 0.50 g of Pb(NO₃)₂

Thus, we can conclude that the theoretical yield of Pb(NO₃)₂ is 0.50 grams

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Ea = 7.7289*104 J/mol ≈ 7.73*104 J/mol is the correct answer. Activation energy is the minimum amount of energy needed for a chemical reaction to occur. It is measured in units of J/mol or KJ/mol and is visualized as a barrier that the reactant molecules must overcome to form products.

Activation energy is the minimum amount of energy required for a chemical reaction to occur. It is the energy needed to break the bonds in the reactant molecules and form new bonds in the product molecules. The activation energy is usually denoted as Ea and is measured in units of joules per mole (J/mol) or kilojoules per mole (kJ/mol).

The activation energy can be visualized as a barrier that the reactant molecules must overcome in order to form products. The higher the activation energy, the more difficult it is for the reaction to occur. For a reaction to take place, the reactant molecules must collide with enough energy to break the bonds and form the new bonds. The activation energy is the minimum energy required for this to happen.

ln (0.4483 s-1/0.2785 s-1) = Ea/R*(1/310 – 1/315) K-1

===> ln (1.6097) = Ea/R*(5.1203*10-5) K-1

===> 0.476 = Ea/R*(5.1203*10-5 K-1)

===> Ea = (0.476)*(8.314 J/mol.K)/(5.1203*10-5 K-1)

===> Ea = 7.7289*104 J/mol ≈ 7.73*104 J/mol (ans).

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Answer:

0.556 moles of gas in this volume

there are approximately 3.35 x 10^23 molecules in this volume of gas.

Explanation:

Given:

Volume of gas (V) = 13.4 L

Standard temperature (T) = 273 K

Standard pressure (P) = 1 atm

a. To determine the number of moles of gas in this volume, we can use the ideal gas law equation:

PV = nRT

where P is pressure, V is volume, n is the number of moles, R is the gas constant, and T is temperature in Kelvin.

At STP, we know that the pressure is 1 atm and the temperature is 273 K. The gas constant R is 0.08206 L atm/mol K.

Plugging in the values, we get:

(1 atm) (13.4 L) = n (0.08206 L atm/mol K) (273 K)

Solving for n, we get:

n = (1 atm * 13.4 L) / (0.08206 L atm/mol K * 273 K) = 0.556 mol

Therefore, there are 0.556 moles of gas in this volume.

b. To determine the number of molecules in this volume of gas, we can use Avogadro's number, which tells us the number of molecules in one mole of a substance. Avogadro's number is approximately 6.02 x 10^23 molecules/mol.

Multiplying the number of moles by Avogadro's number, we get:

0.556 mol * (6.02 x 10^23 molecules/mol) = 3.35 x 10^23 molecules

Therefore, there are approximately 3.35 x 10^23 molecules in this volume of gas.

"Hydrogen bonds occur when partially positive hydrogen atoms attract partially negative atoms nearby. Examples include the bonds between water molecules, ammonia molecules, and DNA base pairs."

Hydrogen bonds are a type of intermolecular force that occurs when a hydrogen atom that is covalently bonded to an electronegative atom (such as nitrogen, oxygen, or fluorine) interacts with another electronegative atom nearby.

The hydrogen atom has a partial positive charge because it is less electronegative than the other atom it is bonded to, while the other atom has a partial negative charge because it is more electronegative.

Hydrogen bonds are important for many biological processes, including the structure of DNA and the properties of water. The bonds between water molecules, for example, are hydrogen bonds that contribute to the high boiling point, surface tension, and other unique properties of water.

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2.20×10²³ atoms are in 3.65 mol of titanium. Therefore, the correct option is option B among all the given options.

Titanium has the chemical symbol Ti and the atomic number 22. It is only found in nature as an oxide, but it may be reduced to form a beautiful transition metal with such a silver hue, low density, as well as high strength that is corrosion resistant in sea water, aqua regia, as well as chlorine.

number of atoms = number of mole× 6.022×10²³  

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

number of atoms = 3.65 mol× 6.022×10²³  

                             = 2.20×10²³   atoms

Therefore, the correct option is option B.

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Only a very small percentage of the heat input to the heart is converted to flow work. The majority of the energy is lost as heat transferred to the tissues surrounding the heart.

How to calculate the heat input?

(a) For this system, we can simplify Equation 7.4-12 as follows:

ΔH = Δ(P/ρ) + Δ(V^2/2) + gΔ(z) + Q

where:

ΔH is the change in enthalpy

Δ(P/ρ) is the change in pressure energy

Δ(V^2/2) is the change in kinetic energy

gΔ(z) is the change in potential energy

Q is the heat added to the system

Since there is no change in internal energy from inlet to outlet, we can assume that the change in enthalpy (ΔH) is equal to the work done by the heart (W):

W = Δ(P/ρ) + Δ(V^2/2) + gΔ(z) + Q

(b) We can find the percentage of the heat input to the heart (Q˙in) that is converted to flow work (the efficiency of the heart as a pump) by calculating the ratio of flow work to heat input:

Efficiency = (flow work / heat input) x 100%

To calculate the flow work, we can use the equation:

W_flow = Δ(P/ρ) x Q

where Δ(P/ρ) is the pressure difference across the heart and Q is the volumetric flow rate of blood.

Δ(P/ρ) = (100 - 0) mm Hg / (13.6 x 1000) kg/m^3 = 7.35 x 10^-6 Pa

Q = 5 x 10^-3 m^3/min = 8.33 x 10^-5 m^3/s

W_flow = (7.35 x 10^-6 Pa) x (8.33 x 10^-5 m^3/s) = 6.13 x 10^-10 J/s

To calculate the heat input, we can use the equation:

Q_in = (5 mL/min) x (20.2 J/mL) = 101 J/min = 1.68 J/s

Therefore, the efficiency of the heart as a pump is:

Efficiency = (W_flow / Q_in) x 100%

Efficiency = (6.13 x 10^-10 J/s / 1.68 J/s) x 100% = 0.0365%

Only a very small percentage of the heat input to the heart is converted to flow work. The majority of the energy is lost as heat transferred to the tissues surrounding the heart.

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given compounds based on their relative Bronsted acidities are: H - F < H - Cl < H - NH2 < H - CH3 < H - SH

What is Bronsted acidities?

Bronsted acidities is a common concept in chemistry which describes the ability of an acid to donate a proton (H+) to a base. This is based on the Bronsted-Lowry Theory which states that an acid is a substance that donates a proton and a base is a substance that accepts a proton. Acids are typically characterized by their acidity constants, which measure the amount of acidity in a solution. Bronsted acidities can range from very weak (like citric acid) to very strong (like hydrochloric acid). Bronsted acidities can be measured in terms of pH, which is a measure of hydrogen ion concentration.

Therefore, given compounds based on their relative Bronsted acidities are: H - F < H - Cl < H - NH2 < H - CH3 < H - SH

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In the given system, the concentrations of H2, N2, and NH3 would change over time as the system approaches equilibrium, with the rates of the forward and reverse reactions becoming equal at equilibrium. The specific concentrations of H2,

In a chemical reaction, reactants are transformed into products, and the reaction can proceed in both the forward and reverse directions. At some point, the rates of the forward and reverse reactions become equal, and the system reaches a state of dynamic equilibrium.

At equilibrium, the concentrations of the reactants and products remain constant over time.The specific concentrations of the reactants and products at equilibrium depend on the equilibrium constant (K), which is a measure of the ratio of the concentrations of the products to the concentrations of the reactants at equilibrium.

If the initial concentrations of the reactants are known, the concentrations of the reactants and products at equilibrium can be calculated using the equilibrium constant.

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The 4 species below which specify the hydrogen bonding behavior are:

Water (H2O): both (acts as both donor and acceptor)

Methanol (CH3OH): both (acts as both donor and acceptor)

Ammonia (NH3): donor (acts as a donor only)

Carbon dioxide (CO2): neither (does not act as a donor or acceptor)

Hydrogen bonding is a type of intermolecular force that occurs between a hydrogen atom bonded to a highly electronegative atom such as nitrogen, oxygen, or fluorine, and an electronegative atom in a nearby molecule.

The hydrogen atom has a partial positive charge due to the electronegativity difference between the bonded atoms, and the electronegative atom in the nearby molecule has a partial negative charge. These opposite charges attract each other, forming a relatively strong electrostatic interaction called a hydrogen bond.

Hydrogen bonding is responsible for many important properties of substances, including the high boiling and melting points of water, the high heat of vaporization of water, and the unique structure and properties of biomolecules such as DNA and proteins.

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Answer:

GIVE IT NOWWWW

Explanation:

The number of grams of Al2O3 that can be formed if 12.5 g of O2 reacts completely with aluminum is 26.6 g.

The balanced chemical equation for the reaction is:

4Al + 3O2 -> 2Al2O3

From above,

We can conclude that,

4 moles of Al react with 3 moles of O2 to produce 2 moles of Al2O3.

Now using the above expression for calculating the number of moles of Al2O3 that can be produced from 12.5 g of O2.

For finding the number of moles, converting the mass of O2 to moles using its molar mass:

molar mass of O2 = 32.00 g/mol

moles of O2 = mass / molar mass = 12.5 g / 32.00 g/mol = 0.391 mol

Next, using the mole ratio from the balanced chemical equation to determine the number of moles of Al2O3 that can be produced:

moles of Al2O3 = (2/3) * moles of O2 = (2/3) * 0.391 mol = 0.261 mol

Now converting the number of moles of Al2O3 to grams using its molar mass:

molar mass of Al2O3 = 101.96 g/mol

So, the value of mass of Al2O3 will be

= moles of Al2O3 * molar mass = 0.261 mol * 101.96 g/mol = 26.6 g

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An organic liquid is a mixture of methyl alcohol (CH3OH) and ethyl alcohol (C2H5OH). A 0.220-g sample of the liquid is burned in an excess of O2(g) and yields 0.338 g CO2(g) (carbon dioxide). The mass percentage of ethyl alcohol, C2H5OH, in the solution is 0.0641 g.

The term mass percent of a solution is defined as the ratio of the mass of solute that is present in a solution, relative to the mass of the solution.

Molar mass of CH₃OH is 32.04 g/mol

Molar mass of C₂H₅OH is 46.07 g/mol

Molar mass of CO₂ is 44.01 g/mol

M(CH₃OH)+ M(C₂H₅OH) = 0.220

Mass of CO₂ produced from M grams of CH₃OH

= 1.374 M

Mass of carbon dioxide is   1.374 M + 1.911 E

= 0.386

Thus, the calculation are

1.374 M + 1.911 (0.220 - M) = 0.386

1.374 M + 0.4204 - 1.911 M = 0.386

- 0.537 M = - 0.0344

M = 0.0344 / 0.537

= 0.0641 g

Thus, the mass percentage of ethyl alcohol, C2H5OH, in the solution is 0.0641 g.

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CH3OH and NH3 would exhibit hydrogen bonding between the solute and solvent.

Hydrogen bonding occurs when hydrogen atoms in a molecule are attracted to electronegative atoms in another molecule. In water the electronegative oxygen atoms are capable of forming hydrogen bonds with molecules that contain hydrogen atoms bonded to electronegative atoms such as nitrogen, oxygen or fluorine.

CH3OH  (methanol) and  NH3 (ammonia) both contain hydrogen atoms bonded to electronegative atoms: allowing them to form hydrogen bonds with water molecules. H2,  CO2 and  NaCl do not contain hydrogen atoms bonded to electronegative atoms and therefore cannot form hydrogen bonds with water molecules.

This question should be provided as:

Which of the following compounds dissolved in water would exhibit hydrogen bonding between the solute and solvent?

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If you do not quantitatively transfer the solution and there is still some in the graduated cylinder when you obtain the volume in Part D, the resulting calculated density will be too high.

This is because the volume you measure will be lower than the actual volume of the solution, but the mass will remain the same.

Since density is calculated by dividing mass by volume (density = mass/volume), a lower volume will result in a higher calculated density.

Therefore, it is important to accurately transfer and measure the solution in order to obtain an accurate calculation of density.

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If 0.8423 g of the ore yielded 0.307 g of MnO precipitate .The percent Mn in the ore is 24.1%.

To determine the percent Mn in the ore, we need to calculate the mass of Mn in the ore and then convert that to a percentage.

First, we'll calculate the mass of Mn in the MnO precipitate:

Mass of Mn = 0.307 g MnO * (1 mol MnO / 70.9 g MnO) * (1 mol Mn / 1 mol MnO) * (54.9 g Mn / 1 mol Mn)

Mass of Mn = 0.203 g Mn

Next, we'll divide the mass of Mn in the ore by the total mass of the ore and multiply by 100 to get the percentage:

Percentage = (0.203 g Mn / 0.8423 g ore) * 100

Percentage  = 24.1% Mn

Therefore the percent Mn in the ore is 24.1%.

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If a desktop computer uses 180 W of power when plugged into a 120-V socket, 1.5 A of current is flowing into the device.

To calculate the current flowing into a desktop computer plugged into a 120-V outlet, we can use the formula:

Current (I) = Power (P) / Voltage (V)

here:

Current is measured in amperes (A)

Power is measured in watts (W)

Voltage is measured in volts (V)

So, for a desktop computer that uses 180 W and is plugged into a 120-V outlet, the current flowing into the computer would be:

I = P / V

= 180 W / 120 V

= 1.5 A

Therefore, the current flowing into the desktop computer is 1.5 amperes.

Note: It's important to ensure that the electrical outlet and the computer's power supply can handle the amount of current being drawn by the computer to avoid overloading the circuit and causing damage.

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Upon addition of iron, the equilibrium will shift toward forward according to Le Chatelier’s principle in the reaction 4 Fe (s) + 3 O[tex]_2[/tex] (g) →2 Fe[tex]_2[/tex]O[tex]_3[/tex] (S)

Equilibrium is commonly characterized as a condition of rest in which no change occurs. A body in equilibrium will have no negative or positive energy exchanges.

The equilibrium state is defined differently in biology, physics, and chemistry. However, the underlying principle remains the same. External forces will have little effect on an organism that is in balance. Upon addition of iron, the equilibrium will shift toward forward according to Le Chatelier’s principle in the reaction 4 Fe (s) + 3 O[tex]_2[/tex] (g) →2 Fe[tex]_2[/tex]O[tex]_3[/tex] (S)

Therefore, upon addition of iron, the equilibrium will shift towards forward according to Le Chatelier’s principle.

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The pressure of a gas increases when the temperature of the gas is increased because of two main reasons:

A. The increase in temperature causes more collisions of the gas particles with the walls, and

C. The average kinetic energy of the gas increases as the temperature increases, causing more energetic collisions with the walls.

As the temperature of a gas increases, the average kinetic energy of the gas particles also increases. This causes the gas particles to move faster and collide with the walls of the container more frequently and with greater force. These more frequent and energetic collisions result in an increase in the pressure of the gas.

It is important to note that option B is not correct because the size of the gas particles does not increase as the temperature increases. Option D is also not correct because the volume of the gas does not decrease as the temperature increases unless the gas is in a closed container and the pressure is kept constant.

In conclusion, the pressure of a gas increases when the temperature of the gas is increased due to an increase in the frequency and energy of the gas particle collisions with the walls of the container.

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Answer:

Explanation:

To determine the amount of chlorine needed to make 75.0 grams of C2H2Cl4, we need to balance the chemical equation and then use the molar ratio between the reactants and product to find the amount of Cl2 needed.

The balanced equation is:

2 Cl2(g) + C2H2(g) -> C2H2Cl4(l)

Next, we can use the molar mass of C2H2Cl4 to find the number of moles of C2H2Cl4 produced:

75.0 g C2H2Cl4 x (1 mole C2H2Cl4 / 153.8 g C2H2Cl4) = 0.489 moles C2H2Cl4

Since the balanced equation has a 1:2 ratio of C2H2 to Cl2, this means that we need 2 moles of Cl2 for every mole of C2H2Cl4 produced. Therefore, we will need 2 x 0.489 moles = 0.978 moles of Cl2.

Finally, to find the volume of Cl2 at STP, we can use the ideal gas law:

PV = nRT

Where P is pressure, V is volume, n is the number of moles, R is the ideal gas constant (0.0821 L-atm/mol-K), and T is the temperature in Kelvin (273 K).

Since the pressure is 1 atm and the temperature is 273 K, we can rearrange the equation to solve for volume:

V = nRT / P = 0.978 moles x 0.0821 L-atm/mol-K x 273 K / 1 atm = 17.1 L

Therefore, 17.1 liters of Cl2 at STP will be needed to make 75.0 grams of C2H2Cl4.