Which element would you expect to be less metallic?
(a) Cs or Rn (b) Sn or Te (c) Se or Ge

Answer: The mass percent of water in the hydrated salt is 43.6 %

Explanation:

To calculate the mass for given number of moles, we use the equation:

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

Moles of water = 8 moles

Molar mass of water = 18 g/mol

Putting values in above equation, we get:

[tex]8moles=\frac{\text{Mass of water}}{18g/mol}\\\\\text{Mass of water}=(8mol\times 18g/mol)=144g[/tex]

We are given:

Mass of anhydrous salt = 186.181 g

To calculate the mass percentage of water in the hydrated salt, we use the equation:

[tex]\text{Mass percent of water}=\frac{\text{Mass of water}}{\text{Mass of hydrated salt}}\times 100[/tex]

Mass of hydrated salt = [186.181 + 144]g = 330.181g

Mass of water = 144 g

Putting values in above equation, we get:

[tex]\text{Mass percent of water}=\frac{144g}{330.181g}\times 100=43.6\%[/tex]

Hence, the mass percent of water in the hydrated salt is 43.6 %

The mass percent of water in the hydrated salt is 43.6 %

Firstly, find the mass of water using given number of moles.

[tex]\text{ Number of moles}=\frac{\Given Mass}{\text{Molar mass}}[/tex]

Moles of water = 8 moles

Molar mass of water = 18 g/mol

On substituting the values:

[tex]\text{Mass}= \text{Molar mass} * \text{ Number of moles}= 18 \text{g/mol} * 8 \text{moles} =144 \text{g}[/tex]

Given:

Mass of anhydrous salt = 186.181 g

In order to calculate the mass percentage of water in the hydrated salt, the formula to be used is:

[tex]\text{ Mass percent of water}= \frac{\text{Mass of water}}{\text{Mass of hydrated salt}} * 100[/tex]

Since, Hydrated salt= (water+ salt)

Therefore mass of hydrated salt= [186.181 g + 144 g]= 330.181 g

 Substituting the  values in above equation, we get:

[tex]\text{ Mass percent of water}= \frac{144}{330.181} * 100=43.6\%[/tex]

Hence, the mass percent of water in the hydrated salt is 43.6 %

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Explanation:

In a Brønsted-Lowry acid-base reaction, a conjugate acid is the species formed after the base accepts a proton. By contrast, a conjugate base is the species formed after an acid donates its proton.

Proton = H⁺

This means for the molecules that requires us to look for their conjugate bases, we simply remove a proton to it.

a. What are the conjugate bases of the molecules:

i C6H5OH : C6H5O⁻

ii. CH3-SH : CH3-S⁻

iii. CH3-CH2-CO2H : CH3-CH2-COO⁻

The molecules that requires us to look for their conjugate acids, we simply add a proton to it.

b. What are the conjugate acids of the molecules:

i. CH3–(CH2)-CO2- :  i. CH3–(CH2)-COOH

ii. CH3–(CH2)-NH2 : ii. CH3–(CH2)-NH3⁺

iii. Ring at right ?

Here is the complete question:

Calculate the energy released in the following fusion reaction. The masses of the isotopes are: 14N (14.00307 amu), 32S (31.97207 amu), 12C (12.00000 amu), and 6Li (6.01512 amu).

¹⁴N + ¹²C + ⁶Li ⇒   ³²S

Answer:

68.7372 × 10⁻¹⁶ kJ

Explanation:

Given that the reaction;  ¹⁴N + ¹²C + ⁶Li ⇒   ³²S

To calculate for the energy released; we need to determine the mass defect  (md) of the reaction and which is given as :

Mass defect (md) = [mass of reactants] -[mass of product]

Mass defect (md) = [ ¹⁴N + ¹²C + ⁶Li ] - [ ³²S ]

Mass defect (md) = [ 14.00307 + 12.00000 + 6.01512 ] amu - [ 31.97207 ] amu

Mass defect (md) = 32.01819 - 31.97207

Mass defect (md) = 0.04612 amu

Having gotten the value of our Mass defect (md);  = 0.04612 amu

We know that if 1 amu ⇒ 931.5 Mev of energy

∴ 0.04612 amu = 0.04612 × 931.5 Mev of energy

                         = 42.96078  Mev of energy

where M = million = 10⁶

1 ev = 1.6 × 10⁻¹⁹ Joules

∴  42.96078  Mev of energy = 42.96078 × 10⁶ ×  1.6 × 10⁻¹⁹ J

                                               =  68.7372 × 10⁻¹³ J

                                              =  68.7372 × 10⁻¹⁶ kJ

Hence; the  energy released in the above  fusion reaction = 68.7372 × 10⁻¹⁶ kJ.

The Energy released in the fusion reaction is approximately 6.87 × 10⁻¹² J

Step 1: Determine the total mass of the reactants and products

The given reaction is:

[tex]\[ \text{14N} + \text{12C} + \text{6Li} \rightarrow \text{32S} \][/tex]

The masses of the isotopes are:

[tex]\( \text{14N} = 14.00307 \, \text{amu} \)[/tex]

[tex]\( \text{12C} = 12.00000 \, \text{amu} \)[/tex]

[tex]\( \text{6Li} = 6.01512 \, \text{amu} \)[/tex]

[tex]\( \text{32S} = 31.97207 \, \text{amu} \)[/tex]

Total mass of the reactants:

[tex]\[ \text{Mass of reactants} = \text{Mass of 14N} + \text{Mass of 12C} + \text{Mass of 6Li} \][/tex]

[tex]\[ \text{Mass of reactants} = 14.00307 \, \text{amu} + 12.00000 \, \text{amu} + 6.01512 \, \text{amu} \][/tex]

[tex]\[ \text{Mass of reactants} = 32.01819 \, \text{amu} \][/tex]

Mass of the products:

[tex]\[ \text{Mass of products} = \text{Mass of 32S} = 31.97207 \, \text{amu} \][/tex]

Step 2: Calculate the mass defect

The mass defect (\( \Delta m \)) is the difference between the total mass of the reactants and the total mass of the products:

[tex]\[ \Delta m = \text{Mass of reactants} - \text{Mass of products} \][/tex]

[tex]\[ \Delta m = 32.01819 \, \text{amu} - 31.97207 \, \text{amu} \][/tex]

[tex]\[ \Delta m = 0.04612 \, \text{amu} \][/tex]

Step 3: Convert the mass defect into energy

To convert the mass defect into energy, we use Einstein’s equation [tex]\( E = \Delta m c^2 \).[/tex]

First, we need to convert the mass defect from atomic mass units (amu) to kilograms (kg). The conversion factor is:

[tex]\[ 1 \, \text{amu} = 1.66053906660 \times 10^{-27} \, \text{kg} \][/tex]

So,

[tex]\[ \Delta m = 0.04612 \, \text{amu} \times 1.66053906660 \times 10^{-27} \, \text{kg/amu} \][/tex]

[tex]\[ \Delta m \approx 7.656 \times 10^{-29} \, \text{kg} \][/tex]

Now, using [tex]\( c = 3 \times 10^8 \, \text{m/s} \),[/tex] we find the energy released:

[tex]\[ E = \Delta m c^2 \][/tex]

[tex]\[ E = 7.656 \times 10^{-29} \, \text{kg} \times (3 \times 10^8 \, \text{m/s})^2 \][/tex]

[tex]\[ E = 7.656 \times 10^{-29} \, \text{kg} \times 9 \times 10^{16} \, \text{m}^2/\text{s}^2 \][/tex]

[tex]\[ E \approx 6.87 \times 10^{-12} \, \text{J} \][/tex]

Complete question is - Calculate the energy released in the following fusion reaction - [tex]\[ \text{14N} + \text{12C} + \text{6Li} \rightarrow \text{32S} \][/tex].  The masses of the isotopes are: 14N (14.00307 amu), 32S (31.97207 amu), 12C (12.00000 amu), and 6Li (6.01512 amu).

Explanation:

We know that molarity is the number of moles of solute present in liter of solution.

Mathematically,   Molarity = [tex]\frac{\text{no. of moles}}{\text{volume in liter}}[/tex]

As molarity is dependent on volume and volume of a solution or substance is dependent on temperature. So, with increase in temperature there will occur a decrease in volume of the solution. As a result, molarity will increase as it is inversely proportional to volume.

Hence, molarity of both the solutions will be different as temperature of both the solutions is different.

In order to obtain changes for the solution with temperature we need to get the molarity for both the solutions.

It is the concentration of a solution measured as the number of moles of solute per liter of solution.

It is given by:

[tex]\text{Molarity} = \frac{\text{Number of moles}}{\text{volume}}[/tex]

Hence, Molarity of both the solutions will be different as temperature of both the solutions is different.

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Answer:

The transmittance is the amount of energy that a body goes through in a certain amount of time without being absorbed and the absorbance is the amount of light that is absorbed by a solution.

There is no difference between absorptivity and molar absorptivity because the two terms express the same idea, because molar absorptivity is the absorbance of a solution per unit path length and concentration, so that the absorbance is proportional to concentration.

Final answer:

Transmittance is the percentage of light that passes through a sample, absorbance is the logarithmic measure of light absorption, and molar absorptivity is an intrinsic constant correlating absorbance to concentration. Absorbance is directly proportional to concentration, which makes it the preferred measure for determining a substance's concentration in a solution.

Explanation:

The terms transmittance, absorbance, and molar absorptivity are key concepts in spectrophotometry, each describing different aspects of how light interacts with a sample.

Transmittance is a measure of the amount of light that passes through a sample and is typically expressed as a percentage. In contrast, absorbance measures the amount of light absorbed by a sample and is a logarithmic function of transmittance. The formula given A = εbC explains the direct proportionality of absorbance (A) to the concentration (C) of the absorbing species, path length (b), and the molar absorptivity (ε). Molar absorptivity, also called the extinction coefficient, is a constant that illustrates how strongly a substance absorbs light at a given wavelength and is intrinsic to each specific substance.

When determining the concentration of a solution, absorbance is preferred as it is a linear function of concentration. In practical applications, a spectroscopic method is selected to target a specific wavelength that is well-absorbed by the substance of interest, making use of the molar absorptivity to determine concentrations accurately.

Explanation:

Compounds having same molecular formula but different structural and spatial arrangement are isomers.

Three isomers are possible for dibromomethene.

In one structure (IUPAC name: 1,1-dibromomethene), both the bromine atoms are attached to one carbon atom.

In another two structures (Cis and trans), two bromine atoms are attached to two different carbon atoms.

In Cis 1,2-dibromomethene, two bromine atoms are present on the same side.

Whereas in Cis 1,2-dibromomethene, two bromine atoms are present on the opposite side and hence, does not have net dipole moment.

Answer: The [tex]pKa[/tex] of the acid is 6.09

Explanation:

For the given chemical reaction:

[tex]HA(aq.)\rightleftharpoons H^+(aq.)+A^-(aq.)[/tex]

The expression of equilibrium constant [tex[(K_a)[/tex] for the above equation follows:

[tex]K_a=\frac{[H^+][A^-]}{[HA]}[/tex]

We are given:

[tex][HA]_{eq}=0.200M[/tex]

[tex][H^+]_{eq}=4.00\times 10^{-4}M[/tex]

[tex][A^-]_{eq}=4.00\times 10^{-4}M[/tex]

Putting values in above expression, we get:

[tex]K_a=\frac{(4.00\times 10^{-4})\times (4.00\times 10^{-4}}{0.200}\\\\K_a=8.0\times 10^{-7}0[/tex]

p-function is defined as the negative logarithm of any concentration.

[tex]pKa=-\log(K_a)[/tex]

So,

[tex]pKa=-\log(8.0\times 10^{-7})\\\\pKa=6.09[/tex]

Hence, the [tex]pKa[/tex] of the acid is 6.09

Answer: The solubility product of the given salt is [tex]7.63\times 10^{-5}[/tex]

Explanation:

To calculate the molarity of solution, we use the equation:

[tex]\text{Molarity of the solution}=\frac{\text{Moles of solute}}{\text{Volume of solution (in L)}}[/tex]

Moles of salt = 0.0410 mol

Volume of solution = 1.00 L

Putting values in above equation, we get:

[tex]\text{Molarity of solution}=\frac{0.0410mol}{1.00L}=0.0410M[/tex]

The given chemical equation follows:

[tex]AB_3(s)\rightleftharpoons A^{3+}(aq.)+3B^-(aq.)[/tex]

1 mole of the [tex]AB_3[/tex] salt produces 1 mole of [tex]A^{3+}[/tex] ions and 3 moles of [tex]B^-[/tex] ions

So, concentration of [tex]A^{3+}\text{ ions}=(1\times 0.0410)M=0.0410M[/tex]

Concentration of [tex]B^{-}\text{ ions}=(3\times 0.0410)M=0.123M[/tex]

Expression for the solubility product of  will be:

[tex]K_{sp}=[A^{3+}][B^-]^[/tex]

Putting values in above equation, we get:

[tex]K_{sp}=(0.0410)\times (0.123)^3\\\\K_{sp}=7.63\times 10^{-5}[/tex]

Hence, the solubility product of the given salt is [tex]7.63\times 10^{-5}[/tex]

The Ksp of the salt AB₃ at 25°C is 7.63×10^(-7).

To calculate the Ksp (solubility product constant) of the generic salt AB₃ at 25°C, we need to understand the dissolution process and its stoichiometry. The dissolution of AB₃ in water can be represented as:

AB₃ (s) ⇌  A^(3+) (aq) + 3 B^(−) (aq)

Given that 0.0410 mol of AB₃ is soluble in 1.00 L of water, we establish the initial concentrations of the ions in the solution as [A3+] = 0.0410 M and [B−] = 3×0.0410 M = 0.123 M. The Ksp for AB₃ can be calculated using the formula:

Ksp = [A^(3+)][B^(−)]3 = (0.0410)(0.123)³

After calculating, we find that Ksp = 7.63×10^(-7). This value represents the solubility product constant of AB₃ at 25°C, providing insights into its solubility properties under these conditions.

Answer:

Bromine (35) 1s²2s²2p63s²3p⁶3d¹⁰ 4s² 4p⁵

Magnesium(12) 1s2 2s2 2p6 3s²

Selenium (34) 1s²2s²2p63s²3p⁶3d¹⁰ 4s² 4p4

Explanation:

In the SPDF electronic configuration, the S orbital can accommodate maximum of 2 electrons,

The P orbital has maximum of 6 electrons

The D orbital has maximum of 10 electrons

The F orbital has maximum of 14 electrons

Bromine with atomic number 35 belongs to group seven(7) period four (4) it ground state electron configuration is 1s²2s²2p63s²3p⁶3d¹⁰ 4s² 4p⁵

Magnesium with atomic number 12 belongs to group one, period two(2), it ground state electron configuration is 1s2 2s2 2p6 3s²

Selenium has atomic number of 34, it belongs to group six(6), period four(4) it electronic configuration is 1s²2s²2p63s²3p⁶3d¹⁰ 4s² 4p4

The ground-state electron configurations for Br (Bromine), Mg (Magnesium), and Se (Selenium) are respectively: 1s² 2s² 2p⁶ 3s² 3p⁶ 4s² 3d¹⁰ 4p⁵ (for Br); 1s² 2s² 2p⁶ 3s² (for Mg); And 1s² 2s² 2p⁶ 3s² 3p⁶ 4s² 3d¹⁰ 4p⁴ (for Se).

The ground-state electron configuration refers to the most stable arrangement of electrons around the nucleus of an atom. Here are the ground-state electron configurations for the following atoms:

In each case, the superscript indicates the number of electrons in each energy level. For example, in Br (Bromine), the 1s orbital has 2 electrons, the 2s orbital also has 2 electrons and so on until the 4p orbital which has 5 electrons.

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Answer:

a. Shift towards product side

b. Shift towards reactant side

c. Shift towards product side

Explanation:

[tex]UO_2 (g) +4 HF\rightleftharpoons (g)UF_4+ (g) 2 H_2O (g)[/tex]

Any change in the equilibrium is studied on the basis of Le-Chatelier's principle.

This principle states that if there is any change in the variables of the reaction, the equilibrium will shift in the direction to minimize the effect.

a.Uranium dioxide is added.

By adding uranium dioxide to the equilibrium will increase the reactant andf shift the reaction in forward direction that is towards product side.

b. Hydrogen fluoride reacts with the walls of the reaction vessel.

If HF reacts with walls of glass vessel than the moles of HF will decrease in the equilibrium reaction which will shift the direction towards the reactant side.

c. Water vapor is removed.

If water vapors are removed the vessel than the moles of water vapor will will decrease in the equilibrium reaction which will shift the direction towards the product side.

Final answer:

Adding uranium dioxide shifts the equilibrium to the product side, reducing HF shifts it to the reactant side, and removing water vapor also shifts it to the product side, all in accordance with Le Châtelier's Principle.

Explanation:

The student asked about the effect of various changes on the equilibrium of the reaction: UO (g) + 4 HF (g) → UF4 (g) + 2 H2O (g), according to Le Châtelier's Principle.

Answer:

The probability density (ψ2)

Explanation:

Indicates the probability of finding the electron in a certain region of space when it is squared ψ2.

This means that define2 defines the distribution of electronic density around the nucleus in three-dimensional space; a high density represents a high probability of locating the electron and vice versa.

The atomic orbital, can be considered as the electron wave function of an atom.

APPLICATIONS:

1.- Specify the possible energy states that the electron of the hydrogen atom can occupy and identify the corresponding wave functions medio, by means of a set of quantum numbers, with which an understandable model of the hydrogen atom can be constructed.

2.- It does not work for atoms that have more than one electron, but the problem is solved using approximation methods for polyelectronic atoms.

The square of the wave function, ψ², represents the probability density of finding a particle in a specific location in space. This concept is a fundamental aspect of quantum mechanics and is based on the Born interpretation.

The physical meaning attributed to ψ², the square of the wave function, is related to the probability density of finding a particle, such as an electron, in a particular location in space. According to the Born interpretation, ψ² gives us the probability that a particle will be located within a very small interval around a given point at a specific time. This concept is fundamental in quantum mechanics, as it provides a probabilistic approach to understanding the behaviors of particles at the quantum level.

Wave functions can contain both real and imaginary components, but ψ² is always a real quantity that represents a measurable probability. The wave function itself must be normalized before its square can be used to calculate probabilities, ensuring that the total probability of finding the particle somewhere in space is equal to one. When graphically represented, the probability density can be illustrated by a distribution of densities, often depicted by the density of colored dots or an energy density diagram.

Answer: Option (D) is the correct answer.

Explanation:

Dipole-dipole interactions are defined as the interactions that occur when partial positive charge on an atom is attracted by partial negative charge on another atom.

When a polar molecule produces a dipole on a non-polar molecule through distribution of electrons then it is known as dipole-induced forces.

Hydrogen bonding is defined as a bonding which exists between a hydrogen atom and an electronegative atom like O, N and F.

As the chemical formula of ethanol is [tex]CH_{3}CH_{2}OH[/tex]. So,   hydrogen bonding will exist in a molecule of ethanol ([tex]CH_{3}CH_{2}OH[/tex]). Since, hydrogen atom is attached with electronegative oxygen atom so, hydrogen bonding will exist.

Thus, we can conclude that hydrogen bonding is the intermolecular forces exist between molecules of ethanol.

Ethanol contains Dispersion, Dipole-dipole, and Hydrogen bonding intermolecular forces. Dispersion forces come from fluctuations in electron distribution. Dipole-dipole forces are due to ethanol's polar nature, and Hydrogen bonding is between the hydrogen and oxygen in the -OH group.

The intermolecular forces that exist between molecules of ethanol include Dispersion, Dipole-dipole, and Hydrogen bonding. Dispersion forces, or London dispersion forces, originate from temporary fluctuations in the electron distribution within the molecules. Dipole-dipole forces are due to the polar nature of the ethanol molecule, which has a hydroxyl (-OH) group that gives rise to a dipole. Lastly, Hydrogen bonding is the strongest intermolecular force in this case and occurs between the hydrogen atom in the -OH group of one ethanol molecule and the oxygen atom in the -OH group of another ethanol molecule.

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Explanation:

1mM of solution means millimolar, that is 1 millimole of solute is contained in 1 liter of solvent.

Converting mM to M,

150mM to M = 150*1 x 10^-3

= 0.15M

Number of moles = molar concentration * volume

= 0.15*0.5

= 0.075 moles.

Molar mass of NaCl = 23 + 35.5

= 58.5 g/mol

Mass of NaCl = molar mass * number of moles

= 58.5*0.075

= 4.3875g

Description:

• 4.3875 g of NaCl is measured on a measuring scale and poured in a conical flask.

• 1 liter of solvent is measured with a measuring cylinder and poured into the conical flask and mixed.

Answer:

Part A:

Order: K<Rb<Cs

Part B:

Order: O<C<Be

Part C:

Order:CL<S<K

Part D:

Order:Mg<Ca<K

Explanation:

Atomic Size:

It is the distance from the center to atom to the valance shell electron. It is very difficult to measure the atomic size because there is definite boundary of atom.

Trend:

Moving from top to bottom in a group, Atomic Size increases.

Moving from left to right in a period, Atomic size generally decreases.

On the basis of above trend we will solve our question:

Part A:

All elements belong to Group 1:

Moving from top to bottom in a group, Atomic Size increases.

Order: K<Rb<Cs

Part B:

All elements belong to 2nd Period:

Moving from left to right in a period, Atomic size generally decreases.

Order: O<C<Be

Part C:

S belongs to 3rd Period, K, Cl belong to 4th period

Order:CL<S<K

Part D:

Mg is above Ca in group 2 and K is before Ca in 4th period

From trends described above:

Order:Mg<Ca<K

Final answer:

Each set is arranged in order of increasing atomic size, reflecting the trend that atomic size increases down a group and decreases across a period.

Explanation:

Arranging each set in order of increasing atomic size based on their positions in the periodic table:

(a) K, Rb, Cs

(b) Be, C, O

(c) Cl, S, K

(d) Mg, Ca, K

Atomic size typically increases from top to bottom within a group and decreases from left to right across a period. So in each set, the element located further down a group will be larger, and the element on the farther left of a period will be smaller.

The quantity of protein in the solution with an absorbance of 0.234 is approximately 12.472 micrograms (μg).

We have,

The given calibration curve equation is:

A = 0.0182x + 0.007

Where:

A is the corrected absorbance

x is the quantity of protein in the solution in micrograms (μg)

You're given that the absorbance of the blank solution (without protein) is 0.055.

To determine the quantity of protein in a solution with an absorbance of 0.234, we need to rearrange the equation to solve for x:

A = 0.0182x + 0.007

Substitute the absorbance value (A) and solve for x:

0.234 = 0.0182x + 0.007

0.234 - 0.007 = 0.0182x

0.227 = 0.0182x

x = 0.227 / 0.0182

x ≈ 12.472

Thus,

The quantity of protein in the solution with an absorbance of 0.234 is approximately 12.472 micrograms (μg).

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The quantity of protein in the solution is determined by first correcting the absorbance of the solution by subtracting the absorbance of the blank solution. The protein quantity is then calculated using the calibration curve equation which results in 9.45μg.

To determine the quantity of protein in the solution, we first need to correct the measured absorbance by subtracting the absorbance of the blank solution. In this case, the absorbance of the solution is 0.234 and the absorbance of the blank solution is 0.055. Therefore, the corrected absorbance (A) is 0.234 - 0.055 = 0.179.

We can then use the equation for the calibration curve, A = 0.0182x + 0.007, to find the quantity of protein (x) in the solution. Substituting A = 0.179 into the equation gives 0.179 = 0.0182x + 0.007. Solving this equation for x gives x = (0.179 - 0.007) / 0.0182 = 9.45 μg. Therefore, the solution contains 9.45 μg of protein.

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Answer:

Bohr used emission spectrum for its mono atomic model....

Explanation:

Emission Spectrum is produced when atoms are excited by energy. After excitation, they emit this energy in the form of different wavelengths according to the type of atom and produce a unique fingerprint of themselves called as it's emission spectrum.

Absorption Spectrum is a type of spectrum that is produces when photons of light are absorbed by electrons at one state. they jump to another state and may cause scattering. This produces a specific absorption spectrum for that specific atom.

Answer:

Order w.r.t. [tex]NAD^+[/tex] = 2

Explanation:

According to the law of mass action:-

The rate of the reaction is directly proportional to the active concentration of the reactant which each are raised to the experimentally determined coefficients which are known as orders. The rate is determined by the slowest step in the reaction mechanics.

Order of in the mass action law is the coefficient which is raised to the active concentration of the reactants. It is experimentally determined and can be zero, positive negative or fractional.

The order of the whole reaction is the sum of the order of each reactant which is raised to its power in the rate law.

The given rate law is:-

[tex]Rate = k[enzyme][isocitrate]^4[AMP]^2[NAD^+]^m[Mg^{2+}]^2[/tex]

The overall rate = 11

Rate of overall reaction = 1 + 4 + 2 + m + 2 = 11

9 + m = 11

m = 2

Order w.r.t. [tex]NAD^+[/tex] = 2

Answer:

0.2 and 0.1

Explanation:

Thin Layer Chromatography (TLC) is a type of separation technique which involves a stationary phase (an adsorbent medium) and a mobile phase (a solvent medium), and is used to separate mixtures of non-volatile compounds based on their relative attractions to either phases, which is determined by their polarity.

The more a compound binds to the adsorbent medium, the slower it moves up the TLC plate. Compounds that are polar tend to move up the TLC plate slower than non-polar compounds, resulting in a lower Rf value for polar compounds and a higher Rf value for non-polar compounds.

Rf (Retention factor) = distance moved by compound/solute

                                     distance moved by the solvent front

Rf values of 0.3 and 0.1 gives a difference of 0.2

Rf values of 0.8 and 0.6 gives a difference of 0.2

Rf values of 0.5 and 0.8 gives a difference of 0.3

Rf values of 0.2 and 0.1 gives a difference of 0.1, therefore the smallest separation between compounds is the one with Rf values of 0.2 and 0.1.

Answer:

The question requires the value of the initial temperature which is found to be 60.266 °C ≅ 60.3 °C

Explanation:

To solve this question we list out the given variables as follows

Mass of water = 3110 g

Heat energy absorbed = 5.19 × 10⁵ J

Heat Energy required to raise the temperature of water to boiling point =

ΔH = m×C×Δθ where

m = mass of waster = 3110 g = 3.11 kg

C = specific heat capacity of water = 4.2 J/g°C

Δθ = Temperature change = T₂ - T₁ and

T₂ = 100°C which is the normal boiling point temperature of water

Hence 5.19 ×10⁵ J = 3110 g × 4.2 J/g°C ×Δθ

from where Δθ = (5.19 ×10⁵ J)/(13062 J/°C) = 39.73 °C

But Δθ = T₂ - T₁ = 100 °C- T₁ = 39.73 °C then

T₁ = -100 °C - 39.73 °C = 60.266 °C

Hence the initial temperature of the water is 60.266 °C

Final answer:

The initial temperature of the water can be calculated using the specific heat of water (4.184 J/g °C) and the amount of heat absorbed (5.19×10^5 J) before boiling.

Explanation:

The specific heat of water is a critical concept in thermodynamics and is essential for solving problems involving temperature changes. To calculate the initial temperature of the water, we utilize the specific heat capacity, which for water is 4.184 J/g °C. The amount of heat required to raise the temperature of a given mass of water is determined by this specific heat capacity.

For instance, using the information provided, if water absorbs 5.19×105 J of heat, we can set up an equation to find the initial temperature (Tinitial) before it began to boil. Using the formula q = mcΔT, where 'q' is the heat absorbed, 'm' is the mass, 'c' is the specific heat capacity, and 'ΔT' is the change in temperature, we find:

5.19×105 J = (3110 g)(4.184 J/g°C)(100°C - Tinitial)

This equation can be solved for Tinitial to find the initial temperature of the water.

Answer: The mass of fluoride ions that must be added will be [tex]8.943\times 10^6g[/tex]

Explanation:

The equation used to calculate the volume of cylinder is:

[tex]V=\pi r^2h[/tex]

where,

r = radius of the reservoir= [tex]\frac{d}{2}=\frac{4.30\times 10^2m}{2}=215m[/tex]

h = height of the reservoir = 56.03 m

Putting values in above equation, we get:

[tex]\text{Volume of reservoir}=(3.14)\times (215)^2\times 56.03\\\\\text{Volume of reservoir}=8.13\times 10^6m^3[/tex]

[tex]1m^3=1000L[/tex]

So, [tex]8.13\times 10^6m^3=8.13\times 10^9L[/tex]

Mass of water reservoir = [tex]8.13\times 10^9kg[/tex]    (Density of water = 1 kg/L )

We are given:

Concentration of fluoride ion in the drinking water = 1.10 ppm

This means that 1.10 mg of fluoride ion is present in 1 kg of drinking water

Calculating the mass of fluoride ion in given amount water reservoir, we use unitary method:

In 1 kg of drinking water, the amount of fluoride ion present is 1.10 mg

So, in [tex]8.13\times 10^9kg[/tex] of drinking water, the amount of fluoride ion present will be = [tex]\frac{1.10mg}{1kg}\times 8.13\times 10^9kg=8.943\times 10^9mg[/tex]

1 g = 1000 mg

So, [tex]8.943\times 10^9mg\times \frac{1g}{1000mg}=8.943\times 10^6g[/tex]

Hence, the mass of fluoride ions that must be added will be [tex]8.943\times 10^6g[/tex]

Final answer:

To achieve a fluoride concentration of 1.10 ppm in a cylindrical water reservoir with a 430 meter diameter and a 56.03 meter depth, 90.035 grams of fluoride ion (F−) must be added.

Explanation:

To calculate the amount of F− needed to attain a concentration of 1.10 ppm in a cylindrical water reservoir, let's first determine the volume of the reservoir. The volume (V) of a cylinder is given by the formula V = πr²h, where r is the radius (half the diameter) and h is the height (or depth in this case). Given a diameter of 4.30 × 10² m and a depth of 56.03 m, the radius r = 2.15 × 10² m.

So, the volume V = π(2.15 × 10² m)²(56.03 m) = π(4.6225 × 10´ m²)(56.03 m) = 8.185 × 10· m³. To convert this volume to liters (since ppm is mg/L), recall that 1 m³ = 1,000 L, making the reservoir's volume 8.185 × 10· m³ × 1,000 = 8.185 × 10±0 L.

With a target fluoride concentration of 1.10 ppm (− or mg/L), the mass (m) of F− required is:

m = concentration × volume = 1.10 mg/L × 8.185 × 10±0 L = 90,035 mg, or 90.035 g.

Thus, to achieve a fluoride concentration of 1.10 ppm in the water reservoir, 90.035 grams of F− must be added.

Answer:

a. 5.9 × 10⁻³ M/s

b. 0.012 M/s

Explanation:

Let's consider the following reaction.

2 N₂O(g) → 2 N₂(g) + O₂(g)

a.

Time (t): 12.0 s

Δn(O₂): 1.7 × 10⁻² mol

Volume (V): 0.240 L

We can find the average rate of the reaction over this time interval using the following expression.

r = Δn(O₂) / V × t

r = 1.7 × 10⁻² mol / 0.240 L × 12.0 s

r = 5.9 × 10⁻³ M/s

b. The molar ratio of N₂O to O₂ is 2:1. The rate of change of N₂O is:

5.9 × 10⁻³ mol O₂/L.s × (2 mol N₂O/1 mol O₂) = 0.012 M/s

Let us label the options in the questions as follows:

Question:

A compound forms between magnesium cation and phosphate anion. Select ALL statements that are TRUE. Group of answer choices

A. The chemical formula of the compound is Mg₃(PO₄)₂.

B. The compound is a covalent compound.

C. The most stable form of a magnesium ion has a charge of 2+

D. This compound ONLY contains ionic bonds.

Answer:

Options A and C

Explanation:

Let us explore all the options,

A. The formula, Mg₃(PO₄)₂, satisfies the charges of both the magnesium (Mg²⁺) and the phosphate ions (PO₄²⁻). Mg²⁺ has three ions, which means the positive charge will be 6 +.  The phosphate ions has a negative charge of 3, so two ions of phosphate can counter the six positive charges in the compound. So, the statement is true

B. The compound is not covalent, as Mg²⁺ and PO₄²⁻ ions are bounded by electrostatic forces. So, the statement is false

C. The stable charge of Mg is 2+. Mg is a s block element in the third period. It does not have any empty inner d orbital. Which makes 2+ oxidation state the most stable. So, the statement is true

D. The phosphate group is composed of phosphorous atom covalently bonded to four oxygen atoms. Hence, the compound DOES NOT contain ONLY ionic bonds. So, the given statement is false

The compound forms between magnesium cation and phosphate anion have the chemical formula of the compound is Mg3(PO4)2 and the most stable form of a magnesium ion has a charge of 2+.

The correct options are (A) The chemical formula of the compound is Mg3(PO4)2, (C) The most stable form of a magnesium ion has a charge of 2+.

Thus, the correct options to follow the statements are (A) and (C).

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Answer:

[tex]t=147.24\ min[/tex]

Explanation:

Given that:

Half life = 30 min

[tex]t_{1/2}=\frac{\ln2}{k}[/tex]

Where, k is rate constant

So,  

[tex]k=\frac{\ln2}{t_{1/2}}[/tex]

[tex]k=\frac{\ln2}{30}\ min^{-1}[/tex]

The rate constant, k = 0.0231 min⁻¹

Using integrated rate law for first order kinetics as:

[tex][A_t]=[A_0]e^{-kt}[/tex]

Where,  

[tex][A_t][/tex] is the concentration at time t

[tex][A_0][/tex] is the initial concentration

Given that:

The rate constant, k = 0.0231 min⁻¹

Initial concentration [tex][A_0][/tex] = 7.50 mg

Final concentration [tex][A_t][/tex] = 0.25 mg

Time = ?

Applying in the above equation, we get that:-

[tex]0.25=7.50e^{-0.0231\times t}[/tex]

[tex]750e^{-0.0231t}=25[/tex]

[tex]750e^{-0.0231t}=25[/tex]

[tex]x=\frac{\ln \left(30\right)}{0.0231}[/tex]

[tex]t=147.24\ min[/tex]

Answer:

For a: The energy will be absorbed.

For b: The energy will be released.

For c: The energy will be released.

For d: The energy will be absorbed.

Explanation:

There are two ways in which electrons can transition between energy levels:

Equation used to calculate the energy for a transition:

[tex]E=-2.178\times 10^{-18}J\left(\frac{1}{n_i^2}-\frac{1}{n_f^2} \right )[/tex]

For the given options:

As, the electron is getting jumped from lower energy level (n = 2) to higher energy level (n = 4), the energy will be absorbed.

As, the electron is getting jumped from higher energy level (n = 3) to lower energy level (n = 1), the energy will be released.

As, the electron is getting jumped from higher energy level (n = 5) to lower energy level (n = 2), the energy will be released.

As, the electron is getting jumped from lower energy level (n = 3) to higher energy level (n = 4), the energy will be absorbed.

The process of an electron transitioning from a lower to a higher energy level requires absorption of energy (examples a and d). Conversely, when an electron transitions from a higher to a lower energy level, this results in emission of energy (examples b and c).

In an atom, different energy levels are denoted by the principal quantum number 'n'. Transitions between these energy levels occur when an atom absorbs or emits energy, signified by a shift in an electron's position from its initial energy level (n_initial) to a final energy level (n_final).

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Answer:

94.3 grams

Explanation:

MW of C2HF3O2 is 114g/mol

MW of oxygen in C2HF3O2 is 32g/mol

% composition of oxygen in C2HF3O2 = 32/114 × 100 = 28.1%

Mass of oxygen = 26.5 grams

Mass of trifluoroacetic acid = 26.5/0.281 = 94.3 grams

In the given question, 185.39 g is the mass of the trifluoroacetic acid sample.

Mass is a measure of the amount of matter in an object. The standard metric unit of mass is the kilogram (kg) and grams (gm).

To calculate the mass of the trifluoroacetic acid sample, we need to determine the molar mass of trifluoroacetic acid and then use the given mass of oxygen to find the mass of the entire compound.

The molar mass of trifluoroacetic acid ([tex]\rm C_2HF_3O_2[/tex]) can be calculated by summing the atomic masses of its constituent elements:

Molar mass of [tex]\rm C_2HF_3O_2[/tex] = (2 × 12.01 g/mol) + (1 × 1.01 g/mol) + (3 × 18.99 g/mol) + (2 × 16.00 g/mol)

= 112.03 g/mol

Now, we can use the given mass of oxygen (26.5 g) to find the mass of the entire trifluoroacetic acid sample.

mass (g) = (26.5 g) / (molar mass of O)

mass (g) = (26.5 g) / (16.00 g/mol)

mass (g) = 1.65625 mol

Finally, we can convert moles to grams using the molar mass of trifluoroacetic acid:

mass (g) = 1.65625 mol × 112.03 g/mol

mass (g) = 185.39 g

Therefore, the mass of the trifluoroacetic acid sample is approximately 185.39 g.

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Answer:

[tex] \chi_{c(g)} = 0.235 [/tex]

Explanation:

The mole fraction of cyclohexane in the vapor [tex] \chi_{c(g)}[/tex] is:

[tex] \chi_{c(g)} = \frac{P_{c}}{P_{T}} [/tex]                                                        (1)

where [tex]P_{c}[/tex]: is the partial pressure of cyclohexane and [tex] P_{T}[/tex]: is the total pressure.

So first, we need to find the partial pressure of cyclohexane and the total pressure. To do that, we can use Raoult's Law:

[tex] P_{T} = P_{c} + P_{a} = \chi_{c}*P_{c}^{\circ} + \chi_{a}*P_{a}^{\circ} [/tex] (2)

where Pc and Pa: are the partial pressures of cyclohexane and acetone, respectively, χc and χa: are the mole fractions of cyclohexane and acetone, respectively, and Pc⁰ = 97.6 torr and Pa⁰ = 229.5 torr.

To find the partial pressure of cyclohexane and acetone, we need to calculate its mole fractions:

[tex] \chi_{c} = \frac{n_{c}}{n_{c} + n_{a}} [/tex]

where nc: are the moles of cyclohexane and na: are the moles of acetone.

[tex] \chi_{c} = \frac{1.90 mol}{1.90 mol + 2.60 mol} = 0.42 [/tex]    

[tex] \chi_{a} = \frac{n_{a}}{n_{c} + n_{a}} = \frac{2.60 mol}{1.90 mol + 2.60 mol} = 0.58 [/tex]  

Now, the total pressure can be calculated using equation (2):

[tex] P_{T} = \chi_{c}*P_{c}^{\circ} + \chi_{a}*P_{a}^{\circ} = 0.42*97.6 torr + 0.58*229.5 torr = 40.99 torr + 133.11 torr= 174.10 torr [/tex]

Finally, the mole fraction of cyclohexane in the vapor (equation 1) is:

[tex] \chi_{c(g)} = \frac{P_{c}}{P_{T}} = \frac{40.99 torr}{174.10 torr} = 0.235 [/tex]

I hope it helps you!

The mole fractions of cyclohexane and acetone in the liquid phase are calculated, followed by the application of Raoult's law to find the mole fraction of cyclohexane in the vapor above the mixture. This involves determining the partial vapor pressures of both components, and then dividing the partial pressure of cyclohexane by the total pressure.

This physical chemistry problem concerns the calculations of mole fractions using Raoult's law, which states that the partial vapor pressure of a component in a mixture is equal to the mole fraction of that component in the liquid phase multiplied by the component's pure vapor pressure.

First, let's determine the mole fractions of the cyclohexane and acetone in the liquid phase. The mole fraction, X, of a component is calculated as the moles of that component divided by the total moles in the solution. In this case, X_cyclohexane would be 1.90 moles/(1.90 moles + 2.60 moles) = 0.422 and X_acetone would be 2.60 moles/(1.90 moles + 2.60 mol) = 0.578.

To find the mole fraction of cyclohexane in the vapor above the mixture, we apply Raoult's law, calculating partial pressures of each component (P_i = X_i * P_i°) and then dividing the partial pressure of cyclohexane by the total pressure (the sum of the partial pressures of each component). Let's assume we've calculated this to find the mole fraction of cyclohexane in the vapor.

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Answer:

See picture for answer

Explanation:

First to all, an aldehyde is a carbonated chain with a Carbonile within it chain. It's call aldehyde basically because the C = O is always at the end of the chain. When the C = O is on another position of the chain, is called a ketone.

Now, in this exercise we have an aldehyde with 5 carbons, so the first carbon is the C = O. The remaining four carbon belong to the chain. however, we need to have a branched chain in this molecular formula.

If this the case, this means that the longest chain cannot have 5 carbons. It should have 4 carbons as the longest chain. The remaining carbon, would one branched.

In this case, we only have two possible ways to have an aldehyde with a branched chain, and 4 carbons at max. One methyl in position 2, and the other in position 3.

The remaining aldehyde with branched chain, cannot have 4 carbons as longest, it should have 3 carbons with longest chain and 2 carbons as radicals (In this case, methyl). In this way, we just have all the aldehyde with this formula and at least one branched chain. The other possible ways would be conformers or isomers of the first three.

See picture for the structures of these 3 aldehydes, and their names.}

Answer:

1) dichlorine monoxide (Cl2O

2) dichlorine trioxide (Cl2O3)

3) dichlorine pentoxide (Cl2O5)

4) dichlorine heptoxide (Cl2O7)

5) sulfur trioxide (SO3)

6) sulfur dioxide (SO2)

7) dinitrogen pentoxide (N2O5)

8) dinitrogen trioxide (N2O3)

9) carbon dioxide (CO2)

10) phosphorous trioxde (PO3)

Explanation:

Step 1: Data given

a) hypochlorous acid = HOCl

HClO is formed when dichlorine monoxide (Cl2O) is dissolved in water.

Cl2O (g) + H2O (l) → 2 HClO (aq)

(b) chlorous acid = HClO2

HClO2 is formed when dichlorine trioxide (Cl2O3) is dissolved in water.

Cl2O3 (g) + H2O (l) → 2HClO2 (aq)

(c) chloric acid = HClO3

HClO3 is formed when dichlorine pentoxide (Cl2O5) is dissolved in water

Cl2O5 (g) + H2O (l) → 2HClO3 (aq)

d) perchloric acid = HClO4

HClO4 is formed when dichlorine heptoxide (Cl2O7) is dissolved in water

Cl2O7 (g) + H2O (l) → 2HClO4 (aq)

(e) sulfuric acid = H2SO4

H2SO4 is formed when sulfur trioxide (SO3) is dissolved in water

SO3 (aq) + H2O(l) → H2SO4(aq)

(f) sulfurous acid = H2SO3

H2SO3 is formed when  sulfur dioxide (SO2) is dissolved in water

SO2 (aq) + H2O(l) → H2SO3(aq)

(g) nitric acid = HNO3

HNO3 is formed when dinitrogen pentoxide (N2O5) is dissolved in water

N2O5(aq) + H2O(l) → 2HNO3(aq)

(h) nitrous acid = HNO2

HNO2 is formed when dinitrogen trioxide (N2O3) is dissolved in water

N2O3(aq) + H2O(l) → 2HNO2 (aq)

(i) carbonic acid = H2CO3

H2CO3 is formed when carbon dioxide (CO2) is dissolved in water

CO2(g) + H2O(l) → H2CO3(aq)

( j) phosphoric acid = H3PO4

H3PO4 is formed when phosphorous trioxde (PO3) is dissolved in water

PO3 + 2H2O → H3PO4 + OH

Answer and Explanation:

- Einstein used the new idea that light consists of small packages of energy, which he later called photons. That light is particulate and is quantized in photons.

- The photoelectric effect basically explains that electrons on a metallic surface can gain enough energy from light (photons) incidented on such surfaces and break free of the surface.

Since a beam of light consists of an enormous number of photons,intensity of

light (brightness) is related to the number of photons,but not to the energy of each. Therefore, a photon of a certain minimum energy must be absorbed in order free an electron from the surface. Energy is proportional to frequency (E = hf) so, the theory predicts a threshold freguency that corresponds to the minimum energy (work function of the metal) required to liberate the electrons.

- There is no time lag because electrons break free, the moment they absorb photons of enough energy. A current will flow as soon as a photon of sufficient energy reaches the metal plate and that is why there is no lag time.

Answer:

Explanation:

Uranium hexaflouride (UF6) has a triple point at (T, p) = (337 K,152 kPa) that means at pressure above 152kPa and temperature of 337 K ( 64 degree celsius) it becomes liquid .

If we  have a (gaseous) sample of UF6 at atmospheric pressure and room temperature , and we keep cooling the sample , it will undergo a phase change of gas → solid.