Approximately 0.0397 grams of reactant will produce 1370 J of heat in this chemical reaction.
To calculate the mass of reactant needed to produce 1370 J of heat in a chemical reaction that releases 34.5 kJ/g of heat for each gram of reactant consumed, follow these steps:
Step 1: Convert the given energy value from kJ/g to J/g.
1 kJ = 1000 J
So, 34.5 kJ/g = 34.5 * 1000 J/g = 34,500 J/g
Step 2: Use the energy conversion factor to determine the mass of reactant.
We know that 34,500 J of heat is released for every 1 gram of reactant consumed. We need to calculate the mass of reactant required to produce 1370 J of heat.
Step 3: Set up a proportion.
Let "m" represent the mass of reactant needed to produce 1370 J of heat. We can set up a proportion like this:
(34,500 J/g) / (1 g) = (1370 J) / (m)
Step 4: Solve for the mass of reactant "m".
To solve for "m", multiply both sides by "m" and then divide both sides by 34,500 J/g:
m = (1370 J) / (34,500 J/g)
Step 5: Calculate the value of "m".
m = 0.0397 g
Therefore, approximately 0.0397 grams of reactant will produce 1370 J of heat in this chemical reaction.
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A balloon has a volume of 2. 32 liters at 24. 0°c. The balloon is heated to 48. 0°C. Calculate the new volume of the balloon.
To solve this problem, we need to use the combined gas law, which relates the pressure, volume, and temperature of a gas.
The combined gas law is expressed as:
(P1V1)/T1 = (P2V2)/T2
where P1 is the initial pressure, V1 is the initial volume, T1 is the initial temperature, P2 is the final pressure, V2 is the final volume, and T2 is the final temperature.
In this problem, we are given the initial volume V1 as 2.32 liters and the initial temperature T1 as 24.0°C. We need to find the final volume V2 when the temperature is raised to 48.0°C.
We can set up the equation as:
(P1V1)/T1 = (P2V2)/T2
Since the pressure remains constant, we can cancel it out:
V1/T1 = V2/T2
We can rearrange this equation to solve for V2:
V2 = (V1/T1) x T2
Substituting the given values, we get:
V2 = (2.32 L/297.15 K) x 321.15 K
V2 = 2.86 L
Therefore, the new volume of the balloon is 2.86 liters when heated to 48.0°C.
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A 0. 515 g sample of CaCl2 reacts with aqueous sodium phosphate to give 0. 484 g Ca3(PO4)2. Show the calculation for the theoretical yield of Ca3(PO4)2.
What is the percent yield of Ca3(PO4)2.
The percent yield of Ca₃(PO₄)2 is 100.6%. This means that the actual yield is slightly higher than the theoretical yield, which could be due to experimental error or incomplete reaction.
To calculate the theoretical yield of Ca₃(PO₄)2, we need to determine the limiting reagent in the reaction. We can do this by calculating the amount of Ca₃(PO₄)2 that can be produced from each reactant, using stoichiometry and the molar masses of the compounds.
The balanced chemical equation for the reaction is:
3 CaCl₂ + 2 Na₃PO₄ → Ca₃(PO₄)2 + 6 NaCl
The molar mass of CaCl₂ is 110.98 g/mol, and the molar mass of Ca₃(PO₄)2 is 310.18 g/mol.
First, we convert the mass of CaCl₂ to moles:
0.515 g CaCl₂ / 110.98 g/mol = 0.00464 mol CaCl₂
Next, we use stoichiometry to calculate the moles of Ca₃(PO₄)2 that can be produced from the CaCl₂:
0.00464 mol CaCl₂ × (1 mol Ca₃(PO₄)2 / 3 mol CaCl₂) = 0.00155 mol Ca₃(PO₄)2
Finally, we convert the moles of Ca₃(PO₄)2 to grams:
0.00155 mol Ca₃(PO₄)2 × 310.18 g/mol = 0.481 g Ca₃(PO₄)2 (theoretical yield)
Therefore, the theoretical yield of Ca₃(PO₄)2 is 0.481 g.
To calculate the percent yield, we use the formula:
percent yield = (actual yield / theoretical yield) × 100%
The actual yield is given as 0.484 g. Plugging in the values, we get:
percent yield = (0.484 g / 0.481 g) × 100% = 100.6%
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11. The latent heat of fusion of water is 334 J/g. The latent heat of
vaporization of water is 2257 J/g. The specific heat capacity of
water is 4.186 J/g °C How much heat is needed to evaporate 500
og of ice that starts at 0°C ? Hint: Sum of AQS...Q1: Solid to Liquid;
Q2 of Liquid water; Q3 Liquid to Gas
The amount heat needed to evaporate 500 g of ice that starts at 0 °C is 1504800 J
How do i determine the heat needed to evaporate the ice?First, we shall determine the heat needed to melt the ice. Details below:
Mass of ice (m) = 500 gLatent heat of fusion (ΔHf) = 334 J/gHeat (H₁) =?H₁ = m × ΔHf
H₁ = 500 × 334
H₁ = 167000 J
Next, we shall determine the heat required to change the water from 0 °C to 100°C. Details below:
Mass of water (M) = 500 gInitial temperature of water (T₁) = 0 °CFinal temperature of water (T₂) = 100 °CChange in temperature of water (ΔT) = 100 - 0 = 100°CSpecific heat capacity of water (C) = 4.186 J/gºC Heat (H₂) =?H₂ = MCΔT
H₂ = 500 × 4.186 × 100
H₂ = 209300 J
Next, we shall determine the heat required to vaporize the water. Details below:
Mass of water (M) = 500 g Heat of Vaporization (ΔHv) = 2257 J/gHeat (H₃) =?H₃ = m × ΔHv
H₃ = 500 × 2257
H₃ = 1128500 J
Finally, we shall determine the heat required to evaporate the ice. Details below:
Heat required to melt the ice (H₁) = 167000 JHeat required to change the steam from 0 °C to 100 °C(H₂) = 209300 JHeat required to vaporize the water (H₃) = 1128500 JTotal heat required (Q) =?Q = H₁ + H₂ + H₃
Q = 167000 + 209300 + 1128500
Total heat required = 1504800 J
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Design a concept map that shows the relationship between pressure, volume, and temperature in boyle's charles's and gay-lussac's laws
Gay-Lussac's Laws, also known as the Pressure-Temperature Law and Volume-Temperature Law, are a set of gas laws that explain the relationship between pressure, volume, and temperature in a given gas sample.
According to Gay-Lussac's Laws, if the pressure of a gas is increased while the volume remains constant, the temperature of the gas will also increase. Similarly, if the volume of a gas is decreased while the pressure remains constant, the temperature of the gas will increase as well.
In terms of a concept map, Gay-Lussac's Laws can be placed in the center with arrows pointing to both Boyle's Law and Charles's Law, which are two other gas laws that are also related to pressure, volume, and temperature.
Boyle's Law states that the pressure of a gas is inversely proportional to its volume, while Charles's Law states that the volume of a gas is directly proportional to its temperature.
To connect these three gas laws, the arrows can be labeled with key terms such as "pressure," "volume," and "temperature," with each gas law demonstrating how changes in one variable will affect the others.
The concept map can also include real-world examples of each gas law, such as how a tire pressure gauge can be used to demonstrate Boyle's Law, or how a hot air balloon can be used to demonstrate Charles's Law.
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-in your own words explain the steps involved to write the name (Sodium Chloride) of a chemical formula let’s include at least three steps and use your notes)?
-In your own words explain the steps involved to write the chemical formula (NaCl) from the name (must
include at least 3 steps and use your notes).
To write the name "Sodium Chloride" from a chemical formula, follow these steps:
1. Identify the elements present in the formula: In this case, the formula is "NaCl," which contains the elements Sodium (Na) and Chlorine (Cl).
2. Write the name of the metal (cation) first: In this case, the metal is Sodium (Na). So, the first part of the name is "Sodium."
3. Write the name of the non-metal (anion) with the suffix "-ide": The non-metal is Chlorine (Cl), so the name changes to "Chloride."
4. Combine the names of the metal and non-metal: The final name is "Sodium Chloride."
To write the chemical formula "NaCl" from the name "Sodium Chloride," follow these steps:
1. Identify the elements from the name: In this case, the name is "Sodium Chloride," which contains the elements Sodium (Na) and Chlorine (Cl).
2. Determine the charges of the elements: Sodium has a +1 charge as a cation, and Chlorine has a -1 charge as an anion.
3. Balance the charges to form a neutral compound: Since the charges are +1 and -1, they balance out, and you don't need to add any subscripts.
4. Write the chemical formula using the element symbols: Combine the symbols to form the formula "NaCl."
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What quantity in moles of hydrogen gas at 150. 0 °C and 23. 3 atm would occupy a vessel of 8. 50 L?
Answer ASAP
The number of moles of hydrogen gas comes out to be 5.700 that can be calculated using the ideal gas equation.
Using ideal gas equation,
PV = nRT ......(1)
It is given that,
T = 150.0 °C
P = 23.3 atm
V = 8.50 L
To calculate the number of moles, substitute the known values in equation (1).
PV = nRT
23.3 atm x 8.50 L = n x 0.0821 L atm/mol/K x 423.15 K
n = (23.3 atm x 8.50 L) / (0.0821 L atm/mol/K x 423.15 K)
= 198.05 / 34.74 mole
= 5.700 moles
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If the solubility of CO2 is 0. 348 g/100 ml water at 101. 3 kPa, calculate the solubility of CO2 in water at a pressure of 263. 4 kPa. Assume the temperature is constant at 0°C
The solubility of CO₂ in water at 263.4 kPa is 1.064 g/100 ml water.
We can use Henry's law to calculate the solubility of CO₂ in water at a different pressure. Henry's law states that the amount of gas dissolved in a liquid is directly proportional to the partial pressure of the gas above the liquid. Thus, we can set up the following equation:
(Solubility at new pressure) / (Solubility at reference pressure) = (Partial pressure of gas at new pressure) / (Partial pressure of gas at reference pressure)We are given the solubility of CO₂ at a reference pressure of 101.3 kPa, which is 0.348 g/100 ml water. We want to find the solubility at a new pressure of 263.4 kPa. We can rearrange the equation above to solve for the solubility at the new pressure:
(Solubility at new pressure) = (Partial pressure of gas at new pressure) x (Solubility at reference pressure) / (Partial pressure of gas at reference pressure)We know that the temperature is constant at 0°C, so we can assume that the solubility is directly proportional to the partial pressure. Thus, we can set up a ratio:
(Solubility at new pressure) / (Solubility at reference pressure) = (Partial pressure of gas at new pressure) / (Partial pressure of gas at reference pressure)Plugging in the given values, we get:
(Solubility at new pressure) / (0.348 g/100 ml) = (263.4 kPa) / (101.3 kPa)Solving for the solubility at the new pressure, we get:
Solubility at new pressure = (263.4 kPa) / (101.3 kPa) x (0.348 g/100 ml)Solubility at new pressure = 1.064 g/100 mlTherefore, the solubility of CO₂ in water at a pressure of 263.4 kPa is 1.064 g/100 ml water.
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2 MnI2 + 13 F2 - 2 MnF3 + 4 IF5
Write the conversion factor to use when converting moles of MnIz to moles of F2
The balanced chemical equation is:
2 MnI2 + 13 F2 → 2 MnF3 + 4 IF5
According to the stoichiometry of the reaction, for every 13 moles of F2 that react, 2 moles of MnI2 are consumed. Therefore, the conversion factor to use when converting moles of MnI2 to moles of F2 is:
13 moles F2 / 2 moles MnI2
This conversion factor can be used to convert moles of MnI2 to moles of F2 or vice versa, by multiplying the number of moles of the starting substance by the conversion factor.
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How many kj are released when 4.30 mol mg reacts with an excess of oxygen?
if 6.40 mol magnesium oxide are produced, how much energy is released?
if 68.9 g mg react with an excess of oxygen, how much energy is released?
the reaction produces 5,356 kj of energy. how many grams of mgo are formed?
The reaction of 4.30 mol of magnesium with an excess of oxygen produces 6.40 mol of magnesium oxide (MgO).
What is magnesium oxide ?Magnesium oxide is a white, odorless inorganic compound composed of magnesium and oxygen atoms. It is a strong basic oxide and an important mineral component of many rocks and soils. It has a wide range of industrial uses, such as in the production of cement, ceramics, and glass. It is also used as an antacid and laxative, and as a supplement to increase dietary magnesium intake.
The energy released in this reaction can be determined using the following equation:E = ΔHf (MgO) x (6.40 mol MgO)
In this equation, ΔHf (MgO) is the molar enthalpy of formation of magnesium oxide. The molar enthalpy of formation of magnesium oxide is -601.8 kJ/mol. Therefore, the total energy released in this reaction is:
E = -601.8 kJ/mol x (6.40 mol MgO)
E = -3,854.7 kJ.To determine the number of grams of MgO produced, we can use the following equation: Mass (MgO) = (6.40 mol MgO) x (Molar mass MgO) .
The molar mass of MgO is 40.3 g/mol. Therefore, the mass of MgO produced is: Mass (MgO) = (6.40 mol MgO.
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1. in a laboratory experiment, an undergraduate student collected a sample of ammonium
phosphate. if the sample contains 9.52 x 1025 molecules, how many grams of the sample did he
collected?
The student collected 2.63 x 10¹⁰ grams of ammonium phosphate.
To determine the mass of the sample collected, we need to know the molar mass of ammonium phosphate, which is (NH₄)₃PO₄. The molar mass of (NH₄)₃PO₄ can be calculated by adding the atomic masses of the constituent atoms:
Molar mass of (NH₄)₃PO₄ = (3 x molar mass of NH₄) + (1 x molar mass of PO₄)
= (3 x 18.04 g/mol) + (1 x 94.97 g/mol)
= 149.99 g/mol
The number of moles of (NH₄)₃PO₄ in the sample can be calculated by dividing the number of molecules by Avogadro's number (6.022 x 10²³):
Number of moles of (NH₄)₃PO₄ = 9.52 x 10²⁵ molecules / 6.022 x 10²³ molecules/mol
= 15.8 mol
Finally, we can calculate the mass of the sample using the formula:
Mass = Number of moles x Molar mass
= 15.8 mol x 149.99 g/mol
= 2.63 x 10¹⁰ g
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What is the percent dissociation of HNO2 when 0. 058 of sodium nitrate is added to 110. 0ml of a 0. 060 M HNO solution? K, for HNO2 is 4. 0x10^-4
The percent dissociation of HNO₂ comes out to be 5.2% which is shown in the below secion.
The calculations of pKa is done as follows-
pKa = - log Ka
= - log (4.0 x 10⁻⁴)
= 3.398
Mole of NaNO₂ = mass / molar mass
= 0.058 g / 68.9953 g/mole
= 8.406 x 10⁻⁴ mole
Mole of HNO₂ = 0.110 L * 0.060 mole / L = 6.6 x10⁻³ mole.
Resulting solution is buffer solution.
pH = pKa + log [salt] / [acid]
Substituting the known values in the above formula.
pH = 3.398 + log ( 8.406 x 10⁻⁴ / 6.6 x 10⁻³ )
pH = 2.503
The pH can also be evaluated using the below expression.
pH = -log[H⁺]
-log[H] = 2.503
[H⁺]= 3.14 x 10⁻³ M
Thus
Percent of ionization = 3.14 x 10⁻³ M x 100 / 0.060 = 5.2 %
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Which of the following solutions will have the greatest concentration?
a. 2 moles of solute dissolved in 1 liter of solution
b. 0.3 mole of solute dissolved in 0.6 liter of solution
c. 2 moles of solute dissolved in 10 liters of solution
d. 0.1 mole of solute dissolved in 0.5 liter of solution
2 moles of solute dissolved in 1 liter of solution has the greatest concentration.
What is concentration of a solution?Concentration refers to the quantity of solute that is dissolved in a specific amount of solution, and it is commonly measured in units such as moles per liter or grams per liter.
Equation:To determine which solution has the greatest concentration, we need to calculate the number of moles of solute present in each solution and then compare the values.
a. Concentration = 2 moles / 1 liter = 2 M
b. Concentration = 0.3 moles / 0.6 liters = 0.5 M
c. Concentration = 2 moles / 10 liters = 0.2 M
d. Concentration = 0.1 moles / 0.5 liters = 0.2 M
Comparing the concentrations, we see that solution (a) has the greatest concentration of 2 M, while the other solutions have concentrations of 0.5 M or lower.
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Help what’s the answer?
3MnO₂ + 4Al → 2Al₂O₃ + 3Mn
20.52 grams will react with 49.7 grams of MnO₂How to balance a chemical reaction?A chemical equation is said to be balanced when the number of atoms of each element on both sides of the equation are the same.
According to this question, manganese oxide reacts with aluminum to produce aluminum oxide and manganese. The balanced equation is given above.
49.7 grams of MnO₂ is equivalent to 0.57 moles
If 3 moles of MnO₂ reacts with 4moles of Al, then 0.57 moles of MnO₂ will react with 0.76 moles of Al.
0.76 moles of Al is equivalent to 20.52 grams of Al.
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Will award you points!
Read the chemical equation. N2 + 3H2 – 2NH3 Using the volume ratio, determine how many liters of NH3 is produced if 3. 6 liters of H2 reacts with an excess of N2, if all measurements are taken at the same temperature and pressure? 5. 4 liters 2. 4 liters 1. 8 liters 1. 2 liters
Using this volume ratio, we can determine that (b) 2.4 liters of ammonia are produced when 3.6 liters of hydrogen reacts with an excess of nitrogen.
The given chemical equation represents the reaction between nitrogen and hydrogen to produce ammonia. The balanced equation shows that for every 3 volumes of hydrogen, 2 volumes of ammonia are produced.
According to the balanced chemical equation N₂ + 3H₂ → 2NH₃, for every 3 volumes of H₂, 2 volumes of NH₃ are produced.
Therefore, if 3.6 liters of H₂ reacts, the amount of NH₃ produced can be calculated as follows:
3.6 L H₂ * (2 L NH₃ / 3 L H₂) = 2.4 L NH₃
Therefore, 2.4 liters of NH₃ would be produced if 3.6 liters of H₂ reacts with an excess of N₂. The correct answer is option (b) 2.4 liters.
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Consider a gas cylinder containing 0. 100 moles of an ideal gas in a
volume of 1. 00 L with a pressure of 1. 00 atm. The cylinder is
surrounded by a constant temperature bath at 298. 0 K. With an
external pressure of 5. 00 atm, the cylinder is compressed to 0. 500 L.
Calculate the q(gas) in J for this compression process.
According to the question the q(gas) in J for this compression process is 0J.
What is gas ?Gas is a state of matter in which particles are spread out and have enough energy to move around freely. Gas is composed of molecules in constant motion and takes the shape and volume of its container. Gas can be either naturally occurring or man-made and is found in the atmosphere. Examples of naturally occurring gases include oxygen, nitrogen, and carbon dioxide. Man-made gases include helium, chlorine, and hydrogen. Gas is often used as a source of energy and is burned to produce heat, which can be used to power machines and vehicles. Gas is also used in many industries, such as in the production of chemicals and plastics.
In this case, n = 0.100 moles,
[tex]C_v[/tex] = (3/2)R = (3/2)(8.314 J/mol K) = 12.471 J/mol K, and
T₁ = 298.0 K,
T2 = 298.0 K.
Therefore, q(gas)
= nCv (T₂- T₁)
= 0.100 mol × 12.471 J/mol K × (298.0 K - 298.0 K)
= 0 J.
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According to the law of conservation of mass, the total mass of the products of a chemical reaction should equal the total mass of the reactants. In our reaction on a balance, however, the mass went down, from 253. 0 g to 250. 2 grams. Using the given chemical equation, explain what caused the apparent loss of mass
The apparent loss of mass from 253.0 g to 250.2 g can be attributed to the involvement of a gas in the chemical reaction, either as a product or a reactant. This gas escapes the system during the reaction, causing a decrease in the observed mass, but the law of conservation of mass still holds true as the total mass is conserved in the reaction.
According to the law of conservation of mass, the total mass of the products of a chemical reaction should equal the total mass of the reactants. In your reaction, the mass went down from 253.0 g to 250.2 g, which seems to contradict this law. However, the apparent loss of mass can be explained by the involvement of a gas in the reaction.
Here's a step-by-step explanation:
1. Identify the given chemical equation. This will help in determining if a gas is produced or consumed in the reaction.
2. Examine the reactants and products to see if any of them are gases. Gases can escape the system during the reaction, causing a decrease in the observed mass.
3. If a gas is produced, this explains the apparent loss of mass. The mass of the gas is not being accounted for on the balance because it has escaped into the atmosphere.
4. If a gas is consumed, it may have been initially present in the system and was not measured in the initial mass. Once it is consumed, the mass of the system would appear to decrease.
In summary, the apparent loss of mass from 253.0 g to 250.2 g can be attributed to the involvement of a gas in the chemical reaction, either as a product or a reactant.
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A sample of crushed rock is found to have 4. 81 x 10^21 atoms of gold, how many moles of hold are present in this sample?
The sample of crushed rock containing 4.81 x 10²¹ atoms of gold corresponds to 0.008 moles of gold.
The number of moles of gold in the sample of crushed rock can be calculated by dividing the total number of atoms of gold by Avogadro's number, which represents the number of particles in one mole of a substance.
First, we convert the given value of atoms of gold to moles by dividing by Avogadro's number (6.022 x 10²³ atoms per mole).
Number of moles of gold = 4.81 x 10²¹ atoms / 6.022 x 10²³ atoms/mol
Simplifying the calculation, we get:
Number of moles of gold = 0.00799 moles
Therefore, there are approximately 0.008 moles of gold present in the sample of crushed rock.
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Question 1 (2 points)
2. 5 L of a gas is heated from 200 K to 300 K. What is the final volume of the gas?
The final volume of the gas is 3.75 L. This result can be explained by the fact that as the temperature of the gas increased, the kinetic energy of its particles also increased, causing them to move faster and occupy a larger volume.
According to the ideal gas law, PV = nRT, the volume of a gas is directly proportional to its temperature.
Therefore, if the temperature of a gas is increased while its pressure and amount remain constant, its volume will also increase.
In this case, the initial volume of the gas is 2.5 L and its temperature is increased from 200 K to 300 K. To find the final volume of the gas, we can use the following equation:
V2 = (T2/T1) x V1
where V1 is the initial volume of the gas, T1 is the initial temperature of the gas, T2 is the final temperature of the gas, and V2 is the final volume of the gas. Plugging in the values, we get:
V2 = (300 K/200 K) x 2.5 L
V2 = 3.75 L
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Given the chart of bond energies, calculate the enthalpy change for the reaction below. Show all work
The enthalpy of the reaction can be obtained as 118 kJ/mol.
What is the reaction enthalpy?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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How many grams of protein are needed to produce 23,000 cal of energy? Every gram of protein can produce 17 KJ of energy
A total of 96,320 kJ / 17 kJ per gram of protein = 5,670 grams of protein.
To determine the grams of protein needed to produce 23,000 calories of energy, we need to convert the calories to kilojoules (kJ) and then divide by the energy produced by each gram of protein.
23,000 calories = 96,320 kJ (1 calorie = 4.184 kJ)
Each gram of protein produces 17 kJ of energy.
Protein is an important nutrient for our bodies, as it provides the building blocks for our muscles, bones, and other tissues. It also plays a role in many cellular functions and processes. One of the functions of protein is to provide energy for our bodies, although this is not its primary role.
When we eat protein, our bodies break it down into amino acids, which can then be used for various purposes. One of these purposes is to produce energy.
Every gram of protein contains 4 calories, or 17 kilojoules, of energy. This is less than the amount of energy provided by a gram of fat (9 calories or 37 kilojoules) or a gram of carbohydrate (4 calories or 17 kilojoules), but it is still significant.
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which of the following transitions within an atom is not possible? group of answer choices an electron begins in an excited state and then gains enough energy to jump to the ground state. an electron begins in the ground state and then gains enough energy to jump to an excited state. an electron begins in the ground state and then gains enough energy to become ionized. an electron begins in an excited state and then gains enough energy to become ionized.
The transition within an atom that is not possible is an electron begins in an excited state and then gains enough energy to become ionized. Option D is correct.
An excited electron already has excess energy above its ground state energy level. If it gains more energy, it can transition to a higher energy level or even become ionized by being ejected from the atom. However, an electron that has already been excited and has reached its highest energy level cannot gain any more energy from the atom and therefore cannot be ionized further.
Once an electron is in its highest energy level, it is said to be in the ionization continuum and cannot be further excited or ionized by the atom. Therefore, the transition of an electron beginning in an excited state and then gaining enough energy to become ionized is not possible. On the other hand, the other three transitions listed are possible and occur naturally in many physical and chemical processes, such as atomic emission and absorption spectra. Option D is correct.
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A 31. 4 gg wafer of pure gold initially at 69. 7 ∘C∘C is submerged into 64. 1 gg of water at 26. 8 ∘C∘C in an insulated container. The specific heat capacity for gold is 0. 128 J/(g⋅∘C)J/(g⋅∘C) and the specific heat capacity for water is 4. 18 J/(g⋅∘C)J/(g⋅∘C)? Part A What is the final temperature of both substances at thermal equilibrium?
A 31.4 g gold wafer initially at 69.7°C is submerged into 64.1 g of water at 26.8°C. The final temperature at which both substances reach thermal equilibrium is 31.9°C.
The final temperature of both substances at thermal equilibrium needs to be determined.
We can use the principle of conservation of energy. Since the system is insulated, the heat lost by the gold will be equal to the heat gained by the water.
The heat lost by the gold can be calculated using:
Q = mcΔT
where Q is the heat lost, m is the mass of the gold, c is its specific heat capacity, and ΔT is the change in temperature.
Similarly, the heat gained by the water can be calculated using:
Q = mcΔT
where Q is the heat gained, m is the mass of the water, c is its specific heat capacity, and ΔT is the change in temperature.
Setting these two equations equal to each other and solving for the final temperature, we get:
[tex]m_{\text{gold}} \cdot c_{\text{gold}} \cdot (T_{\text{final}} - T_{\text{initial\_gold}}) = m_{\text{water}} \cdot c_{\text{water}} \cdot (T_{\text{final}} - T_{\text{initial\_water}})[/tex]
where [tex]$m_{\text{gold}}$[/tex] is the mass of the gold, [tex]c_{\text{gold}}[/tex] is its specific heat capacity, [tex]T_{\text{initial\_gold}}[/tex] is its initial temperature, [tex]m_{\text{water}}[/tex] is the mass of the water, [tex]$c_{\text{water}}$[/tex] is its specific heat capacity, and [tex]T_{\text{initial\_water}}[/tex] is its initial temperature.
Plugging in the values we get:
[tex]31.4 \, \text{g} \times 0.128 \, \text{J/(g} \cdot \text{°C)} \times (T_{\text{final}} - 69.7^\circ\text{C}) = 64.1 \, \text{g} \times 4.18 \, \text{J/(g} \cdot \text{°C)} \times (T_{\text{final}} - 26.8^\circ\text{C})[/tex]
Solving for [tex]$T_{\text{final}}$[/tex], we get:
[tex]T_{\text{final}} = \frac{(31.4 \, \text{g} \times 0.128 \, \text{J/(g} \cdot \text{°C)} \times 69.7^\circ\text{C}) + (64.1 \, \text{g} \times 4.18 \, \text{J/(g} \cdot \text{°C)} \times 26.8^\circ\text{C})}{(31.4 \, \text{g} \times 0.128 \, \text{J/(g} \cdot \text{°C)}) + (64.1 \, \text{g} \times 4.18 \, \text{J/(g} \cdot \text{°C)})}[/tex]
[tex]$T_{\text{final}}$[/tex] = 31.9°C
Therefore, the final temperature of both substances at thermal equilibrium is 31.9°C.
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Determine the mass of ammonium chloride, NH4Cl, required to prepare 0. 250 L of a 0. 35 M solution of ammonium chloride.
Answer: 4.7g NH4Cl
Explanation:
First we need to determine how many moles of NH4Cl we have:
0.250Lx0.35M= 0.0875moles
now we can multiply the molar mass of NH4Cl by how many moles we have
NH4Cl has a molar mass of 53.49g/mol
53.49 x 0.0875= 4.68g NH4Cl or 4.7g NH4Cl using 2 sig figs.
Calculate the molar solubility of agbr in 2.8×10−2 m agno3 solution. the ksp of agbr is 5.0 * 10-13
The molar solubility of [tex]AgBr[/tex] in [tex]2.8 x 10^-2 M AgNO3[/tex] solution is [tex]7.1 x 10^-7 M[/tex].
To calculate the molar solubility of [tex]AgBr[/tex] in [tex]2.8 x 10^-2 M AgNO3[/tex] solution, we need to use the common ion effect. The [tex]Ag+[/tex] ion is a common ion in both [tex]AgBr and AgNO3[/tex]. When we add [tex]AgNO3[/tex] to a solution containing AgBr, it adds more [tex]Ag+[/tex] ions to the solution and causes a shift in the equilibrium to the left. The solubility of [tex]AgBr[/tex]decreases due to this effect.
The balanced equation for the dissolution of [tex]AgBr[/tex] is:
[tex]AgBr(s) ⇌ Ag+(aq) + Br-(aq)[/tex]
The Ksp expression for AgBr is:
Ksp = [Ag+][Br-] = 5.0 x 10^-13
Let x be the molar solubility of [tex]AgBr[/tex]in [tex]2.8 x 10^-2 M AgNO3[/tex]solution. Then the concentration of [tex]Ag+[/tex] ion is[tex][Ag+] = 2.8 x 10^-2 + x[/tex], and the concentration of [tex]Br-[/tex] ion is[tex][Br-] = x[/tex].
Substituting these values into the Ksp expression, we get:
[tex]Ksp = (2.8 x 10^-2 + x)(x) = 5.0 x 10^-13[/tex]
Simplifying the equation and neglecting x in comparison to [tex]2.8 x 10^-2[/tex], we get:
[tex]x^2 = 5.0 x 10^-13x = sqrt(5.0 x 10^-13) = 7.1 x 10^-7 M[/tex]
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calculate the molality of a solition with 85 g of KOH added to 590. g of water
The molality of the solution is 2.57 mol/kg.
To calculate the molality of a solution
We need to determine the number of moles of solute (in this case, KOH) dissolved in a specified mass of the solvent (in this case, water).
First, let's convert the given mass of KOH to moles:
molar mass of KOH = 56.11 g/mol
moles of KOH = mass of KOH / molar mass of KOH
moles of KOH = 85 g / 56.11 g/mol
moles of KOH = 1.515 mol
Next, we need to calculate the mass of the solvent (water) in kilograms:
mass of solvent = 590. g
mass of solvent in kg = mass of solvent / 1000
mass of solvent in kg = 590. g / 1000
mass of solvent in kg = 0.590 kg
Now we can use these values to calculate the molality of the solution:
molality = moles of solute / mass of solvent in kg
molality = 1.515 mol / 0.590 kg
molality = 2.57 mol/kg
Therefore, the molality of the solution is 2.57 mol/kg.
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The pressure of 10 l of a gas is 1800 mmhg. how many l would this same gas occupy at a final pressure of 200 mmhg, if the amount of gas does not change?
The gas would occupy 90 L at a final pressure of 200 mmHg if the amount of gas does not change.
To determine how many liters this gas would occupy at a final pressure of 200 mmHg, we can use Boyle's Law. Boyle's Law states that the product of the initial pressure and volume of a gas is equal to the product of the final pressure and volume if the temperature and amount of gas remain constant. The formula for Boyle's Law is:
P₁ × V₁ = P₂ × V₂
Where P₁ is the initial pressure (1800 mmHg), V₁ is the initial volume (10 L), P₂ is the final pressure (200 mmHg), and V₂ is the final volume we need to find.
Rearranging the formula to find V₂:
V₂ = (P₁ × V₁) / P₂
Substituting the values:
V₂ = (1800 mmHg × 10 L) / 200 mmHg
V₂ = 18000 L·mmHg / 200 mmHg
V₂ = 90 L
So, this gas would occupy 90 L at a final pressure of 200 mmHg if the amount of gas does not change.
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A 20.0g sample of a hydrocarbon is found to contain 2.86g hydrogen. what is the percent by mass of carbon in the hydrocarbon
The percent by mass of carbon in the hydrocarbon is 85.7%.
To find the percent by mass of carbon in the hydrocarbon, follow these steps:
1. Determine the mass of hydrogen in the hydrocarbon: 2.86g.
2. Calculate the mass of carbon in the hydrocarbon by subtracting the mass of hydrogen from the total mass: 20.0g (total mass) - 2.86g (mass of hydrogen) = 17.14g (mass of carbon).
3. Calculate the percent by mass of carbon by dividing the mass of carbon by the total mass of the hydrocarbon, and then multiply by 100: (17.14g carbon / 20.0g total mass) * 100 = 85.7%.
So, the percent by mass of carbon in the 20.0g hydrocarbon sample is 85.7%.
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Is baking soda soluble in soda? Is sugar soluble in soda?
Baking soda is actually a compound known as sodium bicarbonate, which is water-soluble. Sugar, on the other hand, is also soluble in water and other liquids that contain water.
This means that it dissolves in water and can also dissolve in other liquids that contain water, such as soda. Therefore, baking soda is indeed soluble in soda.
Sugar, on the other hand, is also soluble in water and other liquids that contain water. This includes soda, which is a carbonated beverage that typically contains a high amount of dissolved sugar.
However, the solubility of sugar in soda can depend on various factors such as the temperature of the soda, the amount of sugar present, and the type of sugar used.
In general, both baking soda and sugar are soluble in soda and can dissolve to some extent. However, the exact degree of solubility can vary depending on various factors. It is worth noting that excessive consumption of sugary soda can have negative impacts on health, so it is important to consume such beverages in moderation.
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How many grams of calcium oxide will be produced in a closed vessel containing 20. 0 kg of calcium and 20. 0 kg of oxygen gas if the reaction goes to completion?
2Ca(s)+0 (g) 2CaO(s)
A total of 28,000 grams of calcium oxide will be produced.
To find out how many grams of calcium oxide will be produced in a closed vessel containing 20.0 kg of calcium and 20.0 kg of oxygen gas, follow these steps:
1. Convert the given masses into moles using the molar mass of each element:
- For calcium (Ca): 20,000 g / 40.08 g/mol ≈ 499 moles
- For oxygen (O2): 20,000 g / 32 g/mol ≈ 625 moles
2. Determine the limiting reactant using the stoichiometry of the balanced equation:
- The stoichiometric ratio of Ca to O2 is 2:1, so 625 moles of O2 would require 1,250 moles of Ca, but there are only 499 moles of Ca available. Therefore, calcium is the limiting reactant.
3. Calculate the moles of calcium oxide (CaO) produced using the stoichiometry of the balanced equation:
- The ratio of Ca to CaO is 1:1, so 499 moles of Ca will produce 499 moles of CaO.
4. Convert the moles of calcium oxide back to grams using the molar mass:
- The molar mass of CaO is 56.08 g/mol (40.08 g/mol for Ca + 16 g/mol for O). Therefore, 499 moles of CaO * 56.08 g/mol ≈ 28,000 grams of calcium oxide will be produced.
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16. If the difference in electro-negativities of the combining atoms is zero, then the bond formed is a
(a) covalent bond
(b) electrovalent bond
(c) non-polar covalent bond
(d) polar covalent bond