when kc is much less than 1, the equilibrium lies towards the side of reactants, and the concentration of reactants is much greater than the concentration of products at equilibrium. the concentration of reactants is much greater than the concentration of products. Hence, option (a) is the correct answer.
The value of kc is the equilibrium constant which is a measure of the extent to which a reaction will proceed towards the formation of products. When kc is much less than 1, it means that the numerator of the equilibrium constant expression, which represents the concentration of products, is much smaller than the denominator, which represents the concentration of reactants. This indicates that the reaction is not proceeding much towards the formation of products and is mostly staying in the form of reactants.
Therefore, at equilibrium, the concentration of reactants will be much higher than the concentration of products. The other options are incorrect as they do not explain the behavior of a reaction where kc is much less than 1. A catalyst will not change the position of equilibrium, and the concentrations of reactants and products will not be equal at equilibrium.
In conclusion, when kc is much less than 1, the equilibrium lies towards the side of reactants, and the concentration of reactants is much greater than the concentration of products at equilibrium.
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When the equilibrium constant Kc is much less than 1 in a reaction, it indicates that at equilibrium, the system is dominated by reactants rather than products. Therefore, the concentration of the reactants is much greater than the concentration of the products.
Explanation:In the given reaction, when the equilibrium constant (Kc) is much less than 1, it means the reaction system contains mostly reactants, not products, when equilibrium is reached. Therefore, option 'A' is correct: the concentration of reactant is much greater than the concentration of products.
The value of the equilibrium constant Kc provides us with a sense of the ratio of product concentrations to reactant concentrations at equilibrium. If Kc is less than one, this suggests that, at equilibrium, the concentration of the reactants is larger than the concentration of the products. Establishment of the equilibrium does not tell us about the speed of the process. Some equilibriums are reached quickly, and others happen slower and no observable change can be seen over a lengthy period.
Note that the equal concentrations of reactants and products are not mandatory for the equilibrium. The system reaches equilibrium when the rate of the forward reaction is equal to the rate of the backward reaction, and not necessarily when the concentrations of reactants and products are equal.
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Ammonia rapidly reacts with hydrogen chloride, making ammonium chloride. Calculate the number of grams of excess reactant when 3.46 g of NH3 reacts with 4.91 g of HCl.
The number of grams of excess reactant is 1.16 grams of NH₃.
To calculate the number of grams of excess reactant, we first need to determine the limiting reactant, which is the reactant that is completely consumed and determines the amount of product formed. The other reactant is considered the excess reactant.
Given;
Mass of NH₃ = 3.46 g
Mass of HCl = 4.91 g
To determine the limiting reactant, we can compare the moles of each reactant using their respective molar masses.
Molar mass of NH₃ (ammonia) = 17.03 g/mol
Molar mass of HCl (hydrogen chloride) = 36.46 g/mol
Moles of NH₃ = mass of NH₃ / molar mass of NH₃
Moles of HCl = mass of HCl / molar mass of HCl
Plugging in the given values;
Moles of NH₃ = 3.46 g / 17.03 g/mol
= 0.2031 mol
Moles of HCl = 4.91 g / 36.46 g/mol
= 0.1347 mol
To calculate the amount of excess reactant, we subtract the moles of the limiting reactant from the moles of the excess reactant;
Excess moles of NH₃ = Moles of NH₃ - Moles of HCl
Excess moles of NH₃ = 0.2031 mol - 0.1347 mol
= 0.0684 mol
Now, we can calculate the mass of the excess reactant using its molar mass;
Mass of excess NH₃ = Excess moles of NH₃ × molar mass of NH₃
Mass of excess NH₃ = 0.0684 mol × 17.03 g/mol
= 1.16 g
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Write net ionic equations for: a. the neutralization of NaOH with HCl. b. the dissolution of calcium in acid. c. the dissolution of calcium in water. Then combine equations a and b so they result in equation c.
The net ionic equations are as follows:
a. [tex]OH^-(aq) + H^+(aq)[/tex] → [tex]H_2O(l)[/tex]
b. [tex]Ca(s) + 2H^+(aq)[/tex] → [tex]Ca^{2+}(aq) + H_2(g)[/tex]
c. [tex]Ca + 2HCl + 2H_2O[/tex] → [tex]Ca(OH)_2 + H_2[/tex]
a. The neutralization of NaOH with HCl can be represented by the following balanced chemical equation:
NaOH + HCl → NaCl + [tex]H_2O[/tex]
To write the net ionic equation, we need to show only the species that are involved in the chemical reaction. The complete ionic equation is:
[tex]Na^+(aq) + OH^-(aq) + H^+(aq) + Cl^-(aq)[/tex] → [tex]Na^+(aq) + Cl^-(aq) + H_2O(l)[/tex]
The net ionic equation is:
[tex]OH^-(aq) + H^+(aq)[/tex] → [tex]H_2O(l)[/tex]
b. The dissolution of calcium in acid can be represented by the following balanced chemical equation:
Ca + 2HCl → [tex]CaCl_2 + H_2[/tex]
To write the net ionic equation, we need to show only the species that are involved in the chemical reaction. The complete ionic equation is:
[tex]Ca(s) + 2H^+(aq) + 2Cl^-(aq)[/tex] → [tex]Ca^{2+}(aq) + 2Cl^-(aq) + H_2(g)[/tex]
The net ionic equation is:
[tex]Ca(s) + 2H^+(aq)[/tex] → [tex]Ca^{2+}(aq) + H_2(g)[/tex]
c. The dissolution of calcium in water can be represented by the following balanced chemical equation:
[tex]Ca + 2H_2O[/tex] → [tex]Ca(OH)_2 + H_2[/tex]
To combine equations a and b so they result in equation c, we can first write the net ionic equation for the neutralization of NaOH with HCl:
[tex]OH^-(aq) + H^+(aq)[/tex] → [tex]H_2O(l)[/tex]
Then, we can substitute [tex]OH^-[/tex] with Ca and [tex]H^+[/tex] with 2HCl from the net ionic equation for the dissolution of calcium in acid:
[tex]Ca(s) + 2H^+(aq)[/tex] → [tex]Ca^{2+}(aq) + H_2(g)[/tex]
The resulting equation is:
[tex]Ca + 2HCl + 2H_2O[/tex] → [tex]Ca(OH)_2 + H_2[/tex]
which represents the dissolution of calcium in water.
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If the actual density of a mineral is 3.89 g/ml and the experimental density is 4.1 g/ml, then what is the % error for the mineral?
The percent error for the mineral is 5.4%.
The absolute difference between the actual value and the experimental value is taken, divided by the actual value, and multiplied by 100 to provide the percent error, which is a measure of the precision of a measurement or calculation.
The percent error can be calculated using the formula:
Percent error = (|experimental value - actual value| / actual value) x 100%
Substituting the given values, we get:
Percent error = (|4.1 g/ml - 3.89 g/ml| / 3.89 g/ml) x 100%
Percent error = (0.21 g/ml / 3.89 g/ml) x 100%
Percent error = 0.054 x 100%
Percent error = 5.4%
Therefore, the percent error for the mineral is 5.4%.
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When doing integrated rate law calculations for second order reactions, we are assuming a rate law that resembles:Choose the correct answer:a) rate=kb) rate=k[A]c) rate=k[A][B]d) rate=k[A]2
The correct answer is d) rate=k[A]². When we use the integrated rate law for second-order reactions, we assume a rate law that resembles rate=k[A]². In this equation, the rate of the reaction is determined by the rate constant (k) multiplied by the concentration of the reactant A squared ([A]²). This is characteristic of second-order reactions.
This is because the rate of the reaction is proportional to the square of the concentration of the reactant A. By plotting the concentration of A versus time and using the integrated rate law equation for a second-order reaction, we can calculate the rate constant and determine the reaction order.
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How does entropy change in gas reactions
Entropy will change as a result of a change in the number of gas motes present in a response.
Entropy is the intensity present in the substance frame with steady pressure. The entropy change of the response goes up as the operative number goes up.
In a loose sense, entropy is a measure of energy quality, with lower entropy indicating advanced quality. The energy put down in a painstakingly requested manner( the effective library) has lower entropy.
Entropy is high in chaotically stored energy( the arbitrary-pile library). The substance's intelligence and molarity have a direct impact on the response's entropy.
It is known that the entropy increases when there are more intelligencers of the product.
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a sample of radioactive isotope is found to have an activity of 114 bq imediately after it is pulled from the reactor that formed the isotope. its activity 3 h, 50 min later is measured to be 80.2 bq. find the decay constant
The decay constant for the radioactive isotope in this problem is approximately 0.069[tex]h^-^1[/tex].
The activity of a radioactive isotope is the rate at which it decays, and is measured in becquerels (Bq). The activity of a sample of radioactive material decreases over time as the number of radioactive nuclei in the sample decreases due to radioactive decay.
The rate of radioactive decay is described by the first-order rate law, which relates the rate of decay to the number of radioactive nuclei present in the sample. The rate constant (λ) for radioactive decay is a characteristic property of the isotope and is related to its half-life (t1/2) by the equation:
t1/2 = ln(2)/λ
where ln(2) is the natural logarithm of 2, which is approximately 0.693.
To find the decay constant for the radioactive isotope in the given problem, we can use the following equation:
A = A0 e^(-λt)
where A is the activity at time t, A0 is the initial activity, and t is the time elapsed since the initial measurement.
Substituting the given values into this equation, we get:
80.2 Bq = 114 Bq e^(-λ(3 h 50 min))
Converting the time elapsed to hours, we get:
t = 3.833 h
Substituting this value, we get:
80.2 Bq = 114 Bq e^(-λ(3.833 h))
Dividing both sides by 114 Bq, we get:
0.704 = e^(-λ(3.833 h))
Taking the natural logarithm of both sides, we get:
ln(0.704) = -λ(3.833 h)
Solving for λ, we get:
λ = -ln(0.704)/3.833 h
λ ≈ 0.069 h^-1
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write 2-3 sentences to describe the interactions that will occur for each amino acid with the anion exhcange column and its efect on column retention
Anion exchange chromatography is a technique commonly used in protein purification. The retention of an amino acid on an anion exchange column depends on the interaction between the positively charged amino acid molecule and the negatively charged resin of the column.
For amino acids that are positively charged at neutral pH, such as lysine, arginine, and histidine, they will interact strongly with the negatively charged resin of the anion exchange column. This will result in increased retention time for these amino acids on the column. As the concentration of salt in the mobile phase is increased, these positively charged amino acids will be displaced from the column.
On the other hand, amino acids that are negatively charged at neutral pH, such as aspartic acid and glutamic acid, will not interact with the negatively charged resin of the anion exchange column. This results in minimal retention time on the column. As the concentration of salt in the mobile phase is decreased, these negatively charged amino acids will interact more strongly with the column, increasing retention time.
Amino acids that are neutral at neutral pH, such as glycine, alanine, and valine, will not interact strongly with the anion exchange column. Therefore, they will have minimal retention time on the column, regardless of the salt concentration in the mobile phase.
In conclusion, the retention of amino acids on an anion exchange column is dependent on the interaction between the charge of the amino acid and the resin of the column. By manipulating the salt concentration in the mobile phase, it is possible to elute amino acids of interest from the column, which can be useful in protein purification techniques.
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Enabling auto-tagging does what?
Enabling auto-tagging allows for automatic tagging of certain attributes or information within a system or program.
This can save time and effort by eliminating the need for manual tagging and ensuring accuracy in the tagging process. Enabling auto-tagging is a process that allows an analytics or advertising platform to automatically assign tags to specific elements in a campaign or website. This helps in tracking and organizing data more efficiently, making it easier to analyze and optimize your online presence. When auto-tagging is enabled, the system will automatically generate and add tags to your URLs or content without the need for manual input, saving time and effort.
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How did the infrared spectrum of your product demonstrate that aspirin had been synthesized? - What evidence would you expect to see of unreacted salicylic acid? What evidence would you expect to see of unreacted acetic anhydride? - What evidence would you expect to see of acetylsalicylic acid (aspirin)? - Which species did you observe?
Based on their ability to absorb infrared light, chemical compounds may be recognised and described using infrared spectrum and infrared spectroscopy, a potent analytical technique.
IR spectroscopy may be used to validate the creation of acetylsalicylic acid (aspirin) and find any unreacted starting materials (salicylic acid and acetic anhydride) in the aspirin manufacturing process.
The characteristic salicylic acid absorption bands, which include a broad and strong peak in the 3300-2500 cm-1 range due to the O-H stretching vibration and a sharp peak at about 1700 cm-1 due to the C=O stretching vibration of the carboxylic acid group, would be visible in the IR spectrum as evidence of unreacted salicylic acid. Consequently, by contrasting the product's IR spectrum with other IR spectra.
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7. What is the difference between 0.50mol HCI and 0.50M HCI?
Explanation:
0.5 mol HCl represents the amount of HCl in moles and 0.50 M HCl represents that there are 0.5 mol HCl per 1 L solution.
If the mass is 12.3 g, volume without mineral is 50ml, volume with mineral is 53ml, then what is: (a) the volume of water displaced and (b) the final density of the mineral?
a.) The Volume of water displaced is 3 ml
b.) The final density of the mineral is 4.1 g/ml.
(a) The volume of water displaced is the ratio of the volume containing mineral to the volume excluding mineral.
Volume of water displaced = Volume with mineral - Volume without mineral
Volume of water displaced = 53 ml - 50 ml
Volume of water displaced = 3 ml.
(b) The following formula can be used to determine the mineral's density:
Mass / Volume equals density.
The difference between the mass of the mineral and the mass without the mineral is the mass of the mineral.
Mass of mineral = Mass with mineral - Mass without mineral
Mass of mineral = 12.3 g - 0 g (since the mass without mineral is not given)
Mass of mineral = 12.3 g
By deducting the volume without the mineral from the volume with, one may determine the volume of the mineral.
Volume of mineral = Volume with mineral - Volume without mineral
Volume of mineral = 53 ml - 50 ml
Volume of mineral = 3 ml
Therefore, the density of the mineral is:
Density = Mass of mineral / Volume of mineral
Density = 12.3 g / 3 ml
Density = 4.1 g/ml
Therefore, the final density of the mineral is 4.1 g/ml.
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both magnesium and calcium react with water. Which element would you expect to react more vigorously? Provide an explanation for your answer
Both calcium and magnesium reacts with water form their corresponding hydroxides along with the evolution of hydrogen gas. Calcium forms calcium hydroxide whereas magnesium forms magnesium hydroxide with water. But calcium reacts more violently with water.
The reactivity of metals depends on their capacity to lose electrons. The nucleus of calcium is farther away from the valence electrons and thus exert a smaller electrostatic pull on those electrons than the nucleus of magnesium.
Reactivity depends on ability to lose electrons. So calcium can lose electrons more easily and hence it is more reactive.
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Which number indicates neutral on a pH scale?
A) 1
B) 3
C) 5
D) 7
E) 9
The number indicates neutral on a pH scale is 7. Therefore the correct option is option E.
The acidity or basicity (alkalinity) of a solution is gauged using the pH scale. With 0 being the most acidic and 14 being the most basic, it has a range of 0 to 14.
Since a solution's pH is 7 or higher, it is regarded as neutral because it is neither acidic nor basic. The pH of pure water at normal temperature is 7, which is regarded as neutral.
While bases have a pH above 7, acids have a pH below 7, with lower numbers suggesting greater acidity and higher numbers indicating greater basicity. Therefore the correct option is option E.
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The half-life period of a zero order reaction, A ââ product is given by:
A. [A]âk[A]âk
B. 0.693k0.693k
C. [A]â2k[A]â2k
D. 2[A]âk
The correct answer is B. The half-life period of a zero order reaction is given by the equation 0.693/[A]k, where [A] is the initial concentration of the reactant and k is the rate constant for the reaction. This equation shows that the half-life period is independent of the initial concentration of the reactant, which is a characteristic of zero order reactions.
For a zero-order reaction, the half-life period is given by the following formula:
Half-life (t½) = [A₀] / 2k
Where:
- t½ is the half-life period
- [A₀] is the initial concentration of reactant A
- k is the rate constant for the reaction
So, the correct answer is:
D. 2[A]₀/k
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The standard potential for the reduction of agscn(s) is 0. 09 v. Agscn(s) e− ---→ag(s) + SCN−(aq).
Using this value and the electrode potential for Ag+(aq),
calculate the Ksp for AgSCN
The Ksp for AgSCN is 1.1 × 10⁻¹².
The half-reaction for the formation of AgSCN is: Ag⁺(aq) + SCN⁻(aq) → AgSCN(s)
The standard potential for this half-reaction is given as 0.09 V.
The standard potential for the reduction of Ag⁺ to Ag(s) is 0.80 V. Using the Nernst equation:
Ecell = E°cell - (RT/nF)lnQWe can calculate the equilibrium constant, Kc, for the reaction from the cell potential as:
Ecell = E°cell - (0.0257/n)logKcSubstituting the values:
0.80 = 0.09 + (0.0257/2)log(Kc/[Ag⁺][SCN⁻])Simplifying and solving for Kc:
Kc = [Ag⁺][SCN⁻]/[AgSCN] = 1.1 × 10⁻¹²Since the reaction is a 1:1 stoichiometry, we can use the Kc as the Ksp value for AgSCN. Therefore, the Ksp for AgSCN is 1.1 × 10⁻¹².
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ite a balanced half-reaction for the reduction of aqueous nitrous acid to gaseous nitric oxide in basic aqueous solution. be sure to add physical state symbols where appropriate.
The following balanced half-reaction can be used to depict the reduction of aqueous nitrous acid (HNO₂) to gaseous nitric oxide (NO) in basic aqueous solution:
HNO₂ (aq) + 3e⁻ → NO (g) + 2OH⁻ (aq)
What is reduction?The process through which an atom or an ion gains one or more electrons is known as reduction, according to the electronic idea.
The reduction of aqueous nitrous acid (HNO₂) to gaseous nitric oxide (NO) in basic aqueous solution can be represented by the following balanced half-reaction:
HNO₂ (aq) + 3e⁻ → NO (g) + 2OH⁻ (aq)
This half-reaction shows that nitrous acid is reduced by gaining three electrons and that hydroxide ions are present in the reaction as a result of the basic aqueous solution. The stoichiometry of the reaction requires 1 mole of HNO₂ to be reduced for every 3 moles of electrons transferred, and produces 1 mole of NO gas and 2 moles of OH⁻ ions for every mole of HNO₂ reduced.
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2. A new alloy of steel is 525 g at 100°C. It is dropped into 375 grams of water at 25 °C. The final temperature changes to 55°C, what is the specific heat of steel?
Answer:
The specific heat of the steel can be calculated using the formula:
Q = mcΔT
where Q is the heat transferred, m is the mass of the steel, c is the specific heat of the steel, and ΔT is the change in temperature.
First, calculate the heat transferred from the steel to the water:
Qsteel = mcΔT = (525 g)(c)(100 °C - 55 °C) = 27675c J
Next, calculate the heat transferred from the water to the steel:
Qwater = mcΔT = (375 g)(4.184 J/g. °C)(55 °C - 25 °C) = 50202 J
Since the heat lost by the steel is equal to the heat gained by the water:
Qsteel = Qwater
27675c J = 50202 J
c = 1.81 J/g. °C
Therefore, the specific heat of the steel is 1.81 J/g. °C.
Explanation:
if you want to make 1500 grams of a 2.8% by mass glucose solution how many grams of glucose do you need to add (i will give brainliest)
You need to add 42 grams of glucose to make 1500 grams of a 2.8% glucose solution.
To calculate the amount of glucose you need to add to make 1500 grams of a 2.8% glucose solution, you first need to determine what 2.8% by mass means.
2.8% by mass means that there are 2.8 grams of glucose per 100 grams of solution.
So, if you want to make 1500 grams of a 2.8% glucose solution, you can use the following equation:
mass of glucose = (percent by mass / 100) x total mass of solution
mass of glucose = (2.8 / 100) x 1500
mass of glucose = 42 grams
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Natural gas is primarily composed of ________.
A) nitrogen
B) oxygen
C) hydrogen
D) methane
E) carbon dioxide
Natural gas is primarily composed of methane. Therefore the correct option is option E.
However, traces of other hydrocarbon molecules like ethane, propane, and butane as well as non-hydrocarbon gases like nitrogen, carbon dioxide, and helium can also be found in natural gas.
Natural gas is created from the decayed organic matter of extinct plants and animals that were buried, subjected to tremendous pressure, and heated for millions of years.
As a result, their organic content gradually broke down and changed into hydrocarbon molecules.
Because it burns relatively cleanly and emits less carbon dioxide than other fossil fuels like coal and oil, natural gas is a popular energy source. Therefore the correct option is option E.
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Use standard enthalpies of formation to calculate ΔH∘rxn for the following reaction. Mg(OH)2(s)→MgO(s)+H2O(g)
The value of ΔH∘rxn is -804.3 kJ/mol, under the condition that the given reaction is Mg(OH)₂(s)→hMgO(s)+ H₂O.
The given standard enthalpy of formation of Mg(OH)2 is +37.1 kJ/mol and that of MgO is -601.6 kJ/mol. Utilizing these values, we can evaluate the standard enthalpy change for the reaction
ΔH∘rxn = ΣnΔH∘f(products) - ΣmΔH∘f(reactants)
Here
ΔH∘f = standard enthalpy of formation for each species
n and m = specific stoichiometric coefficients concerning the products and reactants.
For this given reaction,
Mg(OH)₂(s) → MgO(s) + H₂O(g)
So n = 1 and m = 1.
Staging the values
ΔH∘rxn = [ΔH∘f(MgO) + ΔH∘f(H₂O)] - ΔH∘f(Mg(OH)₂)
ΔH∘rxn = [-601.6 kJ/mol + (-241.8 kJ/mol)] - (+37.1 kJ/mol)
ΔH∘rxn = -804.3 kJ/mol
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According to the Bohr model of the atom, the energies of the electrons around an atom
have positive values.
are quantized.
equal n, the orbit number.
are quantificated.
get further apart as n increases.
According to the Bohr model of the atom, the energies of the electrons around an atom are quantized. The Bohr model, proposed by Niels Bohr in 1913, was an early attempt to describe the structure of atoms.
In this model, an atom consists of a central nucleus surrounded by electrons orbiting in specific energy levels or shells.
Electrons in the Bohrs model can only occupy discrete energy levels, meaning they cannot have just any energy value; instead, their energies are quantized. The quantization of electron energy levels is based on the concept that electrons can only occupy orbits with specific, fixed distances from the nucleus. Each of these orbits corresponds to a specific energy level. Electrons can move between energy levels by absorbing or emitting energy in the form of photons, but they cannot exist in between these quantized energy levels.
The energy levels are often represented by the principal quantum number, n, which is a positive integer (n = 1, 2, 3, etc.). As the value of n increases, the energy of the electron in that orbit also increases, and the electron is found at a greater distance from the nucleus. Consequently, the energy levels get further apart as n increases.
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complete question:
According to the Bohr model of the atom, the energies of the electrons around an atom
a, have positive values.
b. are quantized.
c. equal n, the orbit number.
d. are quantificated.
e. get further apart as n increases
acetylene gas and oxygen gas react to form carbon dioxide gas and water vapor. suppose you have of and of in a reactor. could half the react? yes no if you answered yes, calculate how many moles of would be produced after half the was used up. round your answer to the nearest .
The reaction between acetylene gas and oxygen gas results in the formation of carbon dioxide gas and water vapor. In the given reaction, acetylene (C₂H₂) is the limiting reactant, resulting in the production of 4 moles of carbon dioxide (CO₂). The moles of acetylene used in the reaction are 1.97, leading to the formation of 3.94 moles of CO₂.
The balanced chemical equation for the reaction is:
2 H₂ + 5 O₂ -> 4 CO₂ + 2 H₂O
Using the given amounts of acetylene and oxygen:
moles of C₂H₂ = / = 3.94
moles of O₂ = / = 68.97
The limiting reactant is acetylene since it produces fewer moles of product. Therefore, only half of the acetylene will be consumed in the reaction.
moles of C₂H₂ used = 3.94 / 2 = 1.97
Using the mole ratio from the balanced equation, the moles of CO₂ produced will be:
moles of CO₂ = 1.97 mol C₂H₂ × (4 mol CO2 / 2 mol C₂H₂) = 3.94 mol CO₂
Rounding to the nearest whole number, the answer is: 4 mol CO₂.
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The concentration of PBDEs in herring gull eggs from the Great Lakes was about 1100 ppb in 1990, and about 7000 ppm in 2000. What is the doubling time for PBDEs in this source? If past trends continue, what will be the concentration in 2010
For a concentration of PBDEs in herring gull eggs, doubling time for PBDEs in this source is 0.778 yrs. The concentration in 2010 is equals to 44.16 ppm.
We have a concentration of PBDEs in herring gull eggs from the Great Lakes was about 1100 ppb in 1990.
Concentration in 2000 = 7000 ppm
= 7000 × 10³ ppb
We have to doubling time for PBDEs in this source and concentration in 2010.
Time = 10 yr
The rate constant is [tex]k = \frac{ 2.303 }{t} \frac{ log[a]}{log[a - x]}[/tex],
Plugging the values, [tex]k = \frac{ 2.303 }{10} log( \frac{ 7000× 10³ }{1100})[/tex]
= 0.875/yr
Doubling time = 0.69/k
= 0.778 yrs.
Now, the we determine the concentration in 2010. Let the concentration be equal x.
[tex]0.778 = \frac{ 2.303 }{10} log(\frac{ x}{7000 })[/tex]
=> [tex]\frac{ x}{7000 \: ppm} = 10^{3.8}[/tex]
=> x = 44.16
Hence, required value is 44.16 ppm.
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a tank contain 102 moles of gas. it has a pressure of 68 atm at a temperature of 316 K. calculate the volume of the tank in liters
Answer:
38.89302738712 litres
Explanation:
pv =nRT
V = nRT/p where R is the ideal gas constant R=8.314 J/mol·K
p in atm to p in pascal = x 101325
V = (102)(8.314)(316)/(68 x 101325)
V = 0.03889302739 m3
m3 to l = x 1000
0.03889302739 x 1000
V = 38.89302738712 litres
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H(g)+Cl(g)→HCl(g)The formation of HCl(g) from its atoms is represented by the equation above. Which of the following best explains why the reaction is thermodynamically favored?
The reaction is thermodynamically favored because it releases energy, which is indicated by the negative value of the change in enthalpy (∆H) of the reaction. This means that the products have a lower enthalpy than the reactants, making the reaction spontaneous and energetically favorable.
Additionally, the decrease in the disorder or randomness of the system (negative ∆S) is outweighed by the decrease in enthalpy, resulting in a negative change in Gibbs free energy (∆G) and indicating that the reaction will proceed in the forward direction.
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Nitrogen monoxide, NO(g), and carbon monoxide, CO(g), are air pollutants generated by automobiles. It has been proposed that under suitable conditions these two gases could react to form N2(8) and CO2(8), which ar components of unpolluted air. (a) Write a balanced equation for the reaction described above. Indicate whether the carbon in CO is oxidized or whether it is reduced in the reaction. Justify your answer.
a)The balanced equation for the reaction described above is:
2NO(g) + 2CO(g) → N₂(g) + 2CO₂(g)
In this reaction, the carbon in CO is oxidized. We can determine this by analyzing the change in oxidation states.
In the balanced equation for the reaction, nitrogen monoxide (NO) and carbon monoxide (CO) combine to form nitrogen gas (N₂) and carbon dioxide (CO₂), which are both components of unpolluted air.
In the reaction, the carbon in CO is oxidized. This is because the oxidation state of carbon in CO is +2, while in CO₂ it is +4. This means that the carbon has gained two electrons, which is the definition of oxidation. Therefore, the carbon in CO is oxidized in the reaction.
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A solution from the stockroom has a concentration of 14 molarity. For use in a lab 3.5 liters of 2.3 molarity is needed. How many liters of the original solution
should be used?
The volume (in liters) of the the original solution that should be used is 0.578 Liter
How do i determine the volume that should be used?The volume of the original solution that should be used can be obtained as follow:
Molarity of original solution (M₁) = 14 MVolume of diluted solution (V₂) = 3.5 Liters Molarity of diluted solution (M₂) = 2.3 MVolume of original solution needed (V₁) =?Dilution equation is given as follow:
M₁V₁ = M₂V₂
Inputting the given parameters, we have:
14 × V₁ = 2.3 × 3.5
14 × V₁ = 8.05
Divide bioth sides by 14
V₁ = 8.05 / 14
V₁ = 0.578 Liter
Thus, from the above calculation, we can conclude that the volume of the original solution needed is 0.578 Liter
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How many mL of 1.81 M CaCl2 have 18.4 g of CaCl2 in them?
It is crucial to understand that when a specific solution is described in terms of molarity or molar concentration (M).
Thus, The unit of concentration actually refers to the number of moles of solute that are present per litre of the solution.
The concentration of the calcium chloride solution in the given problem is 0.80 M, meaning that 0.80 moles of calcium chloride are present in one litre.
The molarity, M, is the number of moles of a pure substance present in a litre of a solution, whereas the molar mass, M, is the mass of a mole of a pure material.
Thus, It is crucial to understand that when a specific solution is described in terms of molarity or molar concentration (M).
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Write the electron configurations for neutral atoms of gallium (Ga), chlorine (Cl), phosphorus (P), calcium (Ca), and sulfur (S ). Electron configuration for Ga: electron configuration for Cl: electron configuration for P: electron configuration for Ca: electron configuration for S: Arrange the atoms according to both decreasing atomic radius and increasing first ionization energy (IE). Largest radius Smallest first IE Smallest radius Largest first IE Answer Bank Answer Bank Ga Cl Са Ga S Cl P S Са
The electronic configurations for neutral atoms are:
Gallium (Ga): [tex]1s^{2} 2s^{2}2p^{6} 3s^{2}3p^{6} 4s^{2} 3d^{10}4p[/tex]
Chlorine (Cl): [tex]1s^{2} 2s^{2}2p^{6} 3s^{2}3p^{5}[/tex]
Phosphorus (P): [tex]1s^{2} 2s^{2}2p^{6} 3s^{2}3p^{3}[/tex]
Calcium (Ca): [tex]1s^{2} 2s^{2}2p^{6} 3s^{2}3p^{6} 4s^{2}[/tex]
Sulfur (S): 1s^2 2s^2 2p^6 3s^2 3p^4[tex]1s^{2} 2s^{2}2p^{6} 3s^{2}3p^{4}[/tex]
Arranging the atoms according to both decreasing atomic radius and increasing first ionization energy (IE):
Largest radius: Ca > Ga > P > S > Cl
Smallest radius: Cl < S < P < Ga < Ca
Smallest first IE: Ca < S < P < Cl < Ga
Largest first IE: Ga > Cl > P > S > Ca
Note: Atomic radius generally increases down a group and decreases across a period, while first ionization energy generally decreases down a group and increases across a period.
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How many moles of LiCl do you need to make 0. 250 L of 0. 50 M solution?
We need 0.125 moles of LiCl to make a 0.50 M solution in 0.250 L of solution.
The volume of solution = 0. 250 L
Molarity of solution = 0. 50 M
A mole is described as the quantity of a substance that includes as many particles that are bonded together in a compound as there are atoms in exactly 12 g of carbon 12 isotope.
To find the number of moles of LiCl, we can use the formula:
moles of solute = concentration of solute * volume of solution
moles of LiCl = 0.50 mol/L x 0.250 L
moles of LiCl = 0.125 mol
Therefore, we can conclude that we need 0.125 moles of LiCl to make a 0.50 M solution in 0.250 L of solution.
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