Calculate the change in molar enthalpy and molar internal energy when carbon dioxide is heater from 15°c (the temperature when air is inhaled) to 37°c (blood temperature, the temperature in our lungs).


( known: energy: 229j, nco2: 3mol, molar heat capacities at constant volume: 37.1 j/kmol and constant pressure of gas: 28.8 j/kmol

A polyatomic ion is made of atoms that are covalently bonded together, which is true about polyatomic ions.

Covalent bonds form when electrons are shared between atoms. This contrasts with ionic bonds, where ions of opposite charges attract one another.

Polyatomic ions are covalently bonded molecules that contain an electrically charged atom or group of atoms. They can have either a positive or negative charge, and they are not usually found in their isolated form. Because they are charged, they have an impact on the chemistry of the surrounding substances.

An ion with more than one atom is called a polyatomic ion. There is one nitrogen atom and four hydrogen atoms in the ammonium ion. They all make up a single ion with the formula NH+4 and a charge of 1+. One carbon atom and three oxygen atoms make up the carbonate ion, which has a 2 overall charge.

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The difference in the rate of sugar and acid reaction to the reaction between KI(aq) and Pb(NO₃)₂(aq) can be explained by the type of chemical bonding present in each case. In the case of sugar and acid, the reaction is a covalent bond breaking and forming process that occurs gradually and can take time to complete.

Covalent bonds are relatively strong and require more energy to break, which can result in slower reaction rates.

On the other hand, the reaction between KI(aq) and Pb(NO₃)₂(aq) involves the formation and breaking of ionic bonds. Ionic bonds are relatively weaker than covalent bonds and require less energy to break, resulting in faster reaction rates.

Additionally, the presence of water in the reaction between KI(aq) and Pb(NO₃)₂(aq) can also speed up the reaction by facilitating the movement of ions and increasing their collision frequency.

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To form 1.4 mol of ammonia, you need 0.7 mol of nitrogen.

Ammonia is formed by combining nitrogenand hydrogenin a 1:3 ratio, as shown in the balanced chemical equation:

N₂ + 3H₂ → 2NH₃

To determine the amount of nitrogen needed to form 1.4 mol of ammonia, follow these steps:

1. Identify the stoichiometry of the reaction: 1 mol N2 reacts with 3 mol H2 to produce 2 mol NH3.
2. Divide the desired amount of ammonia (1.4 mol) by the stoichiometric coefficient of ammonia (2 mol): 1.4 mol / 2 mol = 0.7.
3. Multiply the result (0.7) by the stoichiometric coefficient of nitrogen (1 mol): 0.7 x 1 mol = 0.7 mol.

Therefore, you need 0.7 mol of nitrogen to form 1.4 mol of ammonia.

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1. The number of moles that are contained in 890 ml at 21.0 °C and 750.0 mm Hg pressure is 0.0368 moles

The ideal gas law states

PV = nRT

where P is the pressure

V is the volume

n is the number of moles

R is the gas constant

T is the temperature

Given:

P = 760 mmHg

760 mmHg = 1 atm

P = 1 atm

T = 21° C = 21+273 K = 294 K

V = 890 ml = 0.89 L

Putting them in ideal gas law,

1 * 0.89 = n * 0.0821 * 294

n = 0.0368

2.  The pressure of the container containing 1.09 g of H in a 2.00 L container at 20.0 °C is 6.55 atm

V = 2 L

n = 1.09/2 = 0.545

T = 20 + 273 K = 293 K

Putting them in ideal gas law,

P * 2 = 0.545 * 0.0821 * 293

P = 6.55 atm

3. The volume of 3.00 moles of gas will occupy at 24.0 °C and 762.4 mm Hg is 72.93 L

P = 762.4 mmHg

P = 1.003 atm

n = 3 moles

T = 24 + 273 K = 297 K

Putting them in ideal gas law,

V * 1.003 = 3 * 0.0821 * 297

V = 72.93 L

4. The volume of 20 g of Argon at STP is 11.2 L

P = 1 atm

T = 273 K

n = 20/40 = 0.5

Putting them in ideal gas law,

V * 1 = 0.5 * 0.0821 * 273

V = 11.2 L

5. The number of moles of gas that would be present in a gas trapped within a 100.0 mL vessel at 25.0 °C is 0.01

V = 100 ml = 0.1 L

T = 25 + 273 = 298 K

P = 2.5 atm

Thus, 2.5 * 0.1 = n * 0.0821 * 298

n = 0.01

6. The moles of gas that would be present in a gas trapped within a 37.0-liter vessel at 80.00 °C at a pressure of 2.50 atm is 3.19 moles

P = 2.5 atm

T = 80 + 273 K = 353 K

V = 37 L

Thus, 2.5 * 37 = 0.0821 * n * 353

n = 3.19

7. The volume will increase if the number of moles of a gas is doubled, at the same temperature and pressure

Keeping the temperature and pressure constant in the gas law we get,

V ∝ n

Thus, the volume is directly proportional to number of moles in this case.

8. The volume occupied by 1.27 moles of helium gas at STP is 28.46 L

P = 1 atm

T = 273 K

n = 1.27

Putting them in ideal gas law,

V * 1 = 1.27 * 0.0821 * 273

V = 28.46 L

9. At pressure 0.415 atm, 0.150 moles of nitrogen gas at 23.0 °C occupy 8.90 L

V = 8.9 L

T = 23 + 273 K = 300 K

n = 0.15 moles

Thus, P * 8.9 = 0.0821 * 0.15 * 300

P = 0.415 atm

10. The volume occupied by 32g of NO at 3.12 atm and 18.0 °C is 8.11 L

n = 32/30 = 1.06

P = 3.12 atm

T = 273 + 18 K = 291 K

Thus, 3.12 * V = 1.06 * 0.0821 * 291

V = 8.11 L

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The enthalpy of the reaction can be obtained as 118 kJ/mol.

Reaction enthalpy, also known as heat of reaction or ΔHrxn, is the change in enthalpy that occurs during a chemical reaction. It is defined as the difference between the enthalpy of the products and the enthalpy of the reactants.

We have;

Enthalpy of reaction = Bonds broken - Bonds formed

Enthalpy of reaction = [4(413) + 2(495) - [2(799) + 2(463)

= [1652 + 990] - [1598 + 926]

=2642 - 2524

= 118 kJ/mol

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a) The temperature of the water in the beaker is likely to increase as heat flows from the metal to the water until they reach thermal equilibrium.

b) The metal will likely lose heat to the water until it reaches thermal equilibrium with the water.

a) The temperature of the water in the beaker is likely to increase due to the transfer of heat from the metal to the water. This process is known as conduction, and it occurs because heat always flows from hotter objects to cooler objects. The metal, being at a higher temperature than the water, will transfer heat to the water until both reach a state of thermal equilibrium.

b) The amount of heat lost by the metal will depend on its mass, specific heat capacity, and initial temperature. The metal may also undergo physical changes due to the change in temperature, such as contraction or expansion. The type of metal and its properties will influence how much it changes in response to the temperature change.

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8.13 x  10²⁴ magnesium ions in 4.5 moles of magnesium phosphate.

To determine the chemical formula for magnesium phosphate. Magnesium has a 2⁺ charge, and phosphate has a 3⁻ charge, so the chemical formula for magnesium phosphate is Mg₃(PO₄)₂.

Next, we need to use the coefficients in the formula to determine the number of magnesium ions in 4.5 moles of magnesium phosphate. There are 3 magnesium ions in one molecule of magnesium phosphate, so we can set up a proportion:

3 Mg ions / 1 Mg₃(PO₄)₂ molecule = x Mg ions / 4.5 moles Mg₃(PO₄)₂

Solving for x, we get:
x = 3 Mg ions / 1 Mg₃(PO₄)₂ molecule × 4.5 moles Mg₃(PO₄)₂
x = 13.5 moles Mg ions

Therefore, there are 13.5 moles of magnesium ions in 4.5 moles of magnesium phosphate. However, if we want to convert this to a more common unit, we can use Avogadro's number to convert moles to atoms or ions:

13.5 moles Mg ions × 6.022 x 10²³ions/mol = 8.13 x  10²⁴ Mg ions

Therefore, there are approximately 8.13 x 10²⁴ magnesium ions in 4.5 moles of magnesium phosphate.

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The structure of trehalose can be determined based on its chemical formula, [tex]C12H22O11[/tex], and the fact that it only forms D-glucose upon hydrolysis.

Trehalose is a disaccharide composed of two glucose molecules linked by an alpha-1,1 glycosidic bond. This means that the glucose molecules are joined together through their first and first carbon atoms, respectively. The structure can be written as:

[tex]HOCH2(CHOH)4α-D-Glc-(1→1)-α-D-Glc-CH2OH[/tex]

where [tex]"α-D-Glc"[/tex] represents a glucose molecule in its alpha configuration.

To visualize the structure, we can draw it in a condensed form, where the two glucose molecules are shown connected by a straight line:

[tex]HOCH2(CHOH)4α-D-Glc-(1→1)-α-D-Glc-CH2OH[/tex]

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Gerald T. Moneybottom's action of buying the Amazon rainforest and protecting it from logging has significant positive impacts on both the environment and human health.

By preventing logging, he ensures the survival of various endangered tree species, which could have otherwise become extinct. The rainforest is home to many unique plants and animals that have yet to be discovered and studied, and some of these species could potentially have medicinal properties.

By protecting the rainforest, Moneybottom has provided an opportunity for scientists to study these species and develop new medicines that can improve human health.

In addition to the medicinal benefits, the rainforest also serves as a natural carbon sink, absorbing carbon dioxide from the atmosphere and slowing down the process of global warming.

The preservation of the Amazon rainforest helps to mitigate the effects of climate change by reducing the amount of carbon dioxide in the atmosphere. This action contributes to the effort to reduce greenhouse gas emissions and fight climate change, which is a critical global issue.

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You need to add 0.405 moles of CH₃NH₃Cl to 200.0 mL of 0.500 M CH₃NH₂ to create a buffer with a pH of 11.

To find the moles of CH₃NH₃Cl needed, you'll need to use the Henderson-Hasselbalch equation and the given information.

The Henderson-Hasselbalch equation is pH = pKa + log([A⁻]/[HA]).

First, calculate pKa using the given Kb value for CH₃NH₂:

pKa = -log(Ka)

= -log(Kw/Kb)

= -log(1.0 × 10⁻¹⁴ / 4.4 × 10⁻⁴)

= 10.36.

Then, plug in the desired pH (11) and the given concentrations of CH₃NH₂ (0.500 M):

11 = 10.36 + log([CH₃NH₃Cl]/[0.500]).

Solving for [CH₃NH₃Cl], you get [CH₃NH₃Cl] = 0.405 M.

Finally, multiply this concentration by the volume of the solution in liters (0.200 L) to find the moles of CH₃NH₃Cl needed: 0.405 M × 0.200 L = 0.405 moles.

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Answer:

yes acid can nuetralize bases

Answer:

Yes!

Explanation:

Strong Acids neutralize Strong bases.

When they react, water is formed. Whatever ions are left over, they become salt.

There must be an equal moles of strong acid and strong base.

To prepare 97 g of H₂SO₄, 45.3 liters of 0.018 M H₂SO₄ solution would be required.

To calculate the volume of 0.018 M H₂SO₄ needed to contain 97 g of H₂SO₄, we first need to determine the number of moles of H₂SO₄ in 97 g. From the molar mass of H₂SO₄, we can calculate that 97 g is equivalent to 0.815 moles of H₂SO₄ .

Using the molarity of the H₂SO₄ solution (0.018 M), we can then calculate the volume of solution needed using the formula:

Volume = moles / molarity

Thus, the volume of 0.018 M H₂SO₄ needed to contain 97 g of H₂SO₄ is:

Volume = 0.815 moles / 0.018 M = 45.3 L (rounded to two decimal places).

Therefore, 45.3 liters of 0.018 M H₂SO₄ solution would be needed to contain 97 g of H₂SO₄.

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The volume occupied by 3.67 moles of H₂ gas at STP is 82.19 L.

To calculate the volume, we use the equation V = n × Vm, where V is the volume, n is the number of moles, and Vm is the molar volume of a gas at STP (22.4 L/mol). At STP (standard temperature and pressure), one mole of any gas occupies 22.4 L. Given that we have 3.67 moles of H₂ gas, we can calculate the volume as follows:

1. Identify the number of moles (n): 3.67 moles of H₂
2. Find the molar volume of a gas at STP (Vm): 22.4 L/mol
3. Use the equation V = n × Vm
4. Substitute the values: V = 3.67 moles × 22.4 L/mol
5. Calculate the volume: V = 82.19 L

Therefore, 3.67 moles of H₂ gas occupy 82.19 L at STP.

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The correct description of the heat transfer is heat is released. Hence the heat released is 2150 J (last option)

The following data were obtained from the question:

The heat released or absorbed can be obtain as follow:

Q = MCΔT

Q = 50 × 4.184 × -12

Q = -2510 J

From the above, we can see that the heat energy is negative (i.e -2510 J).

Thus, we can conclude that the description of the heat transfer is heat is released (last option)

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The Ksp of NaCl when it begins to crystallize out of a 6.07 M solution is approximately 36.84.

To calculate the Ksp of NaCl in this solution, follow these steps:
1. Identify the balanced dissociation equation: NaCl(s) ↔ Na+(aq) + Cl-(aq).
2. Since NaCl dissociates into a 1:1 ratio, the concentrations of Na+ and Cl- are equal to the initial concentration, 6.07 M.
3. Determine the Ksp expression: Ksp = [Na+][Cl-].
4. Substitute the concentrations into the expression: Ksp = (6.07)(6.07) ≈ 36.84.

In this scenario, the Ksp value represents the point at which NaCl begins to crystallize from the solution. The Ksp increases as more solute precipitates, which reflects the equilibrium between dissolved and solid NaCl.

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The percent yield of KOH is 60.26%.

To calculate the percent yield, we first need to find the theoretical yield and then compare it with the actual yield. In this case, the actual yield is given as 75.00 grams.

1. Find moles of water (H2O):
40.0 g H2O × (1 mol H2O / 18.02 g H2O) = 2.2198 mol H2O

2. Use the balanced chemical equation to find moles of KOH:
H2O + KO → KOH + 1/2 H2
From the balanced equation, 1 mol of H2O produces 1 mol of KOH. Thus,
2.2198 mol H2O × (1 mol KOH / 1 mol H2O) = 2.2198 mol KOH

3. Find the theoretical mass of KOH:
2.2198 mol KOH × (56.11 g KOH / 1 mol KOH) = 124.44 g KOH

Now that we have the theoretical yield (124.44 g KOH) and the actual yield (75.00 g KOH), we can calculate the percent yield:

Percent Yield = (Actual Yield / Theoretical Yield) × 100
Percent Yield = (75.00 g KOH / 124.44 g KOH) × 100 = 60.26%

So, the percent yield of KOH is 60.26%.

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Answer:To find the number of CO2 molecules in a 0.25 g sample of dry ice, we can use the Avogadro's number and the molar mass of CO2.The molar mass of CO2 is:12.01 g/mol (C) + 2(16.00 g/mol) (O) = 44.01 g/molThis means that 1 mole of CO2 contains 6.022 x 10^23 molecules.To find the number of moles in 0.25 g of CO2, we can use the molar mass:0.25 g / 44.01 g/mol = 0.005681 molFinally, we can use Avogadro's number to find the number of CO2 molecules:0.005681 mol x 6.022 x 10^23 molecules/mol = 3.422 x 10^21 CO2 moleculesTherefore, a 0.25 g sample of dry ice contains approximately 3.422 x 10^21 CO2 molecules.

The addition of NaCl(aq) will not affect the concentration of Ag₂CO₃(s) because it is a solid and its concentration remains constant.

The addition of NaCl(aq) will introduce Cl⁻ ions into the solution, which can react with Ag+ ions to form the sparingly soluble salt AgCl(s):

Ag⁺(aq) + Cl⁻(aq) ⇆ AgCl(s)

This reaction will shift the equilibrium of the original reaction to the right, according to Le Chatelier's principle, in order to counteract the increase in Ag⁺ ions. As a result, more Ag⁺ ions will be produced from the dissociation of Ag₂CO₃(s), causing its concentration to remain constant, and more CO₃⁻²(g) ions will be consumed, decreasing their concentration. Therefore, the concentration of Ag⁺(aq) will increase, while the concentration of CO₃⁻²(g) will decrease.

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The absence of attractive or repulsive forces between gas molecules means that they are free to move independently and randomly. This results in the motion of gas particles being characterized by constant collisions and changes in direction and speed. Without any forces to constrain their movement, gas particles will continue to move until they collide with other particles or the walls of their container. This is what causes gases to fill up any container they are in, as their independent motion allows them to spread out evenly throughout the available space.

What is attractive force?

An attractive force is a force that pulls or draws two or more objects or particles towards each other. It is the opposite of a repulsive force, which pushes objects or particles away from each other.

Attractive forces can be observed in a variety of contexts, including gravity, electromagnetism, and intermolecular forces in chemistry. For example, the force of gravity between two objects is an attractive force that pulls them together, while the electromagnetic force between opposite charges is also an attractive force.

What is repulsive force?

A repulsive force is a force that pushes two or more objects or particles away from each other. It is the opposite of an attractive force, which pulls objects or particles towards each other.

Repulsive forces can be observed in a variety of contexts, including electromagnetism and intermolecular forces in chemistry. For example, the force between two like charges is repulsive, while the force between two like magnetic poles is also repulsive.

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The complete reaction would be; 2 NaCl --> 2 Na + Cl2 + H

Energy is released when an exothermic process continues in the form of heat, light, or sound. In this way, the reactants' chemical bonds initially hold the energy, which is later released as the bonds are broken and new ones are formed.

Heat or other forms of energy are released as a result of the energy differential between the reactants and the reaction's products. In an exothermic process, energy is assumed to be on the side of the products.

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The theoretical yield of this reaction in grams is approximately 1.54 g.

The theoretical yield of a reaction is the maximum amount of product that could be obtained if the reaction went to completion. In this case, since we know the actual yield (0.97 g) and the percent yield (63.1%), we can use this information to calculate the theoretical yield.

First, we can use the percent yield formula to calculate the actual amount of product that was expected based on the theoretical yield:

Percent yield = (actual yield / theoretical yield) x 100

Rearranging this formula, we can solve for the theoretical yield:

Theoretical yield = actual yield / (percent yield / 100)

Plugging in the values we know, we get:

Theoretical yield = 0.97 g / (63.1 / 100) = 1.54 g

Therefore, the theoretical yield of this reaction is 1.54 g. This means that if the reaction had gone to completion, we would have expected to obtain 1.54 g of product. The actual yield of 0.97 g represents only 63.1% of the theoretical yield.

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The value of Ea′ is -53 kJ/mol, and it represents the energy released during the chemical reaction.

The given values ∆E = −33 kJ/mol and Ea = 20 kJ/mol represent the activation energy and the change in energy, respectively, for a chemical reaction. The activation energy, Ea, is the minimum energy required for the reaction to occur, while the change in energy, ∆E, represents the difference between the energy of the reactants and the energy of the products.

The relationship between the activation energy, Ea, and the change in energy, ∆E, can be expressed using the equation: ∆E = Ea + Ea′ where Ea′ represents the energy released during the reaction. Since the change in energy and the activation energy are given, we can rearrange the equation to solve for Ea′: Ea′ = ∆E - Ea

Substituting the given values, we get: Ea′ = −33 kJ/mol - 20 kJ/mol = -53 kJ/mol. Therefore, the value of Ea′ is -53 kJ/mol. This negative value indicates that the reaction is exothermic, meaning that it releases energy as it proceeds. The magnitude of the value (-53 kJ/mol) indicates that the energy released during the reaction is significant.

In summary, the value of Ea′ is -53 kJ/mol, and it represents the energy released during the chemical reaction. This value can be calculated using the equation Ea′ = ∆E - Ea, where ∆E is the change in energy and Ea is the activation energy.

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The volume of [tex]NaOH[/tex] used to titrate the[tex]HCl[/tex] is 5.80 mL

First, we need to find the number of moles of [tex]HCl[/tex] that reacted with the [tex]CaCO3[/tex].

2 mol [tex]HCl[/tex] react with 1 mol [tex]CaCO3[/tex]

Moles of [tex]HCl[/tex] = (7.50 mL) x (2.00 mol/L) = 0.015 mol [tex]HCl[/tex]

From the balanced equation, we see that 1 mol of [tex]CaCO3[/tex] reacts with 2 mol of [tex]HCl[/tex]. Therefore, the number of moles of [tex]CaCO3[/tex] in the original 0.205 g sample is:

Moles of[tex]CaCO3[/tex] = 0.205 g / 100.09 g/mol = 0.002049 mol [tex]CaCO3[/tex]

Since 1 mol of [tex]CaCO3[/tex] produces 1 mol of [tex]CO2[/tex], we have:

Moles of[tex]CO2[/tex]produced = 0.002049 mol [tex]CaCO3[/tex]

Now we need to calculate the concentration of [tex]CO2[/tex] in the final 125.0 mL solution.

Concentration of [tex]CO2[/tex] = Moles of [tex]CO2[/tex] produced / Volume of solution

Concentration of [tex]CO2[/tex] = 0.002049 mol / 0.125 L = 0.0164 mol/L

Finally, we can use the balanced equation for the titration reaction to calculate the number of moles of [tex]NaOH[/tex]used.

1 mol [tex]NaOH[/tex] reacts with 1 mol [tex]HCl[/tex]

Moles of [tex]NaOH[/tex] used = (0.058 L) x (0.1000 mol/L) = 0.0058 mol [tex]NaOH[/tex]

Since the volume of the aliquot is 10.00 mL or 0.0100 L, the concentration of [tex]HCl[/tex] is:

Concentration of [tex]HCl[/tex] = Moles of NaOH used / Volume of [tex]HCl[/tex]

Concentration of [tex]HCl[/tex] = 0.0058 mol / 0.0100 L = 0.580 M

Therefore, the volume of [tex]NaOH[/tex] used to titrate the [tex]HCl[/tex]is:

Volume of [tex]NaOH[/tex] = (0.580 M) x (0.0100 L) = 0.00580 L or 5.80 mL

So, the answer is 5.80 mL.

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The final velocity of two cars that stick together after a collision is 18.5 m/s. The change in kinetic energy of the system is 322,505 J, and an inelastic collision occurred.

To solve this problem, we can use the principle of conservation of momentum, which states that the total momentum of a closed system remains constant if no external forces act on it.

First, we calculate the initial momentum of the system:

p_initial = m1 * v1 + m2 * v2

p_initial = 1250 kg * 20.0 m/s + 1610 kg * 8.0 m/s

p_initial = 40,000 kg m/s + 12,880 kg m/s

p_initial = 52,880 kg m/s

Next, we calculate the total mass of the system after the collision:

m_total = m1 + m2

m_total = 1250 kg + 1610 kg

m_total = 2860 kg

Since the two cars stick together after the collision, we can assume that they move as one object. Therefore, the final velocity of the two cars can be calculated as follows:

v_final = p_initial / m_total

v_final = 52,880 kg m/s / 2860 kg

v_final = 18.5 m/s

To calculate the change in kinetic energy of the system, we can use the formula:

ΔK = K_final - K_initial

The initial kinetic energy of the system can be calculated as:

K_initial = 1/2 * m1 * v1² + 1/2 * m2 * v2²

K_initial = 1/2 * 1250 kg * (20.0 m/s)² + 1/2 * 1610 kg * (8.0 m/s)²

K_initial = 400,000 J + 51,520 J

K_initial = 451,520 J

The final kinetic energy of the system can be calculated as:

K_final = 1/2 * m_total * v_final²

K_final = 1/2 * 2860 kg * (18.5 m/s)²

K_final = 774,025 J

Therefore, the change in kinetic energy of the system is:

ΔK = K_final - K_initial

ΔK = 774,025 J - 451,520 J

ΔK = 322,505 J

Since the total kinetic energy of the system is not conserved, and some of it is converted to other forms of energy such as heat and sound, we can conclude that an inelastic collision occurred in the system.

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Answer:

The theoretical yield of oxygen (O2) can be calculated using the balanced chemical equation:

2 H2O(l) → 2 H2(g) + O2(g)

From part (c), we calculated that 90.0 g of water (H2O) can produce 31.98 g of oxygen (O2). Therefore, the theoretical yield of oxygen from 43,200 g of water is:

theoretical yield = (31.98 g O2 / 90.0 g H2O) x 43,200 g H2O

theoretical yield = 15,379.2 g O2

The percent yield of oxygen can be calculated using the formula:

percent yield = (actual yield / theoretical yield) x 100%

Substituting the given values, we get:

percent yield = (43,200 g / 15,379.2 g) x 100%

percent yield ≈ 280.9%

This result seems unusually high, and suggests an error in the calculations or experimental data. A percent yield greater than 100% indicates that the actual yield is greater than the theoretical yield, which is usually not possible due to limitations in the reaction conditions or experimental procedures.

The amount of electrical energy (in kWh) needed to produce 1 kWh of electrical energy is 1 kWh or 3.6E6 J. The actual amount of energy needed may vary depending on the efficiency of the power generation system used.

A kilowatt-hour is a unit of energy commonly used by electric companies to measure the amount of energy consumed by households or businesses over a period of time. One kilowatt-hour (kWh) is equal to the amount of energy consumed by a 1,000 watt appliance for one hour.
We know that 1 kWh is equal to 3.6E6 J (joules). This means that to produce 1 kWh of electrical energy, we need to generate 3.6E6 J of energy.

In practical terms, the amount of electrical energy needed to produce 1 kWh depends on the efficiency of the power generation system. For example, a coal-fired power plant may require more energy input (e.g. coal) to generate 1 kWh of electrical energy compared to a renewable energy source such as solar or wind power.

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Answer:

7.3

Explanation:

When 66.38 g of potassium chloride reacts with fluorine, you can obtain 0.4452 moles of chlorine.

To find out how many moles of chlorine you can get when 66.38 g of potassium chloride reacts with fluorine to produce potassium fluoride and chlorine, you'll need to follow these steps:

1. Write the balanced chemical equation for the reaction:
2 KCl + F2 → 2 KF + Cl2

2. Determine the molar mass of KCl (potassium chloride):
39.10 g/mol (K) + 35.45 g/mol (Cl) = 74.55 g/mol

3. Convert the given mass of KCl (66.38 g) to moles:
(66.38 g KCl) / (74.55 g/mol) = 0.8904 mol KCl

4. Use the stoichiometry from the balanced equation to determine the moles of Cl2 (chlorine) produced:
(0.8904 mol KCl) x (1 mol Cl2 / 2 mol KCl) = 0.4452 mol Cl2

So, when 66.38 g of potassium chloride reacts with fluorine, you can obtain 0.4452 moles of chlorine.

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Explanation:

You will need the specific heat of Mg which I found to be 1.02 J / (g C)

m * 45 C  * 1.02 J . (g C) = 843

m = 843 / (45* 1.02) = 18.4 g  of Magnesium

The average atomic mass of element J is 79.854u as it determines the properties and behavior of the element in various chemical and physical processes.

To calculate the average atomic mass of element J, we need to use the formula:

Average atomic mass = (mass₁ × % abundance₁ + mass₂ x % abundance₂) ÷ 100

where mass₁ and mass₂ are the atomic masses of the two isotopes and % abundance₁ and % abundance₂ are their respective relative abundances.

Substituting the values given in the problem, we get:

Average atomic mass of J = (78.92u x 50.69% + 80.92u x 49.31%) ÷ 100

= (40.05148u + 39.80252u) ÷ 100

= 79.854u

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