There are three competing factors at play here: 1. The effective nuclear charge 2. The size of the atom and the force of attraction according to Coulomb's law 3. A pair of electrons in an orbital The first ionization energy is the energy required to completely remove the first electron from the atom. The higher in energy an electron is to start with, the less additinal energy will be required to remove it, which translates to a lower ionization energy. By the same token, an electron arrangement which is lower in energy will require more energy to remove an electron.

Answer:

water is everywhere, its in the air and the clouds, in the earth too!

it isnt always liquid form. like when it snows or hails.

Explanation:

Answer:

2 CO(g) + O₂(g) → 2 CO₂(g)

Explanation:

Let's consider the combination reaction between carbon monoxide and oxygen to form carbon dioxide.

CO(g) + O₂(g) → CO₂(g)

We have an odd number of atoms of C on each side, so we multiply CO(g) and CO₂(g) by 2.

2 CO(g) + O₂(g) → 2 CO₂(g)

Now, the equation is balanced.

The combination reaction where carbon monoxide combines with oxygen to form carbon dioxide can be represented by the balanced chemical equation: 2CO + O₂ → 2CO₂.

The balanced equation for the combination reaction where carbon monoxide (CO) combines with oxygen (O₂) to form carbon dioxide (CO₂) can be represented as follows:

2CO + O₂ → 2CO₂

In this reaction, two molecules of carbon monoxide react with one molecule of oxygen to produce two molecules of carbon dioxide. It's important to remember that in balancing chemical equations, one must ensure the same number of each type of atom is represented on both the reactant and product side of the equation.

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Complete Question

The complete question is shown on the first uploaded image

Answer:

The diagram of the mechanism of this reaction is shown on the second uploaded image

The structure of the enolate Ion 1 is shown on the third uploaded image

Explanation:

The aldol condensation of 2,5-heptanedione involves several steps of proton transfer and structural changes to yield stable products. These steps showcase the dynamic nature of chemical reactions and examples of sequential proton transfers seen in polyprotic acids.

The aldol condensation of 2,5-heptanedione yielding a mixture of enone products is a chain of reactions involving the transfer of protons. Iterating the process you described, it starts with hydroxide ion adding to the double bond to form intermediate enolate ion 1, followed by proton transfer resulting in tetrahedral intermediate 2. The ring opening process then forms another enolate ion (3), which after protonation, yields the initial 2,5-heptanedione. A deprotonation at C-6 subsequently yields enolate ion 5, which attacks C-2 to generate tetrahedral intermediate 6. Protonation at this stage will yield aldol addition product 7. Dehydration of this product will finally yield the more stable product. This sequence is an example of sequential proton transfers often seen in polyprotic acids.

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Answer:

The calculations are in the explanation below.

The steps are:

Explanation:

To make 100 mililiter of the 3.0M solution of sulfuric acid, first you must calculate the volume of the 12.0M stock solution that contains the same number of moles as the diluted solution.

For that, you use the dilution formula:

Then, the steps are:

1. Using a graduated pipette, accurately take 25mL of the 12.0M stock solution.

2. Pour the 25mL of stock solution into a 100 mL volumetric flask

3. Add distilled water up to the mark

4. Cap the flask with the stopper

5. Stirr by gently rotating the flask.

Answer:

16 moles

Explanation:

16 moles of NH₃ are required to produce 12 moles of NH₄Cl

Stoichiometry helps us use the balanced chemical equation to measures quantitative relationships and it is to calculate the amount of products and reactants that are given in a reaction.

The balanced chemical equation is the equation in which the number of atoms on the reactant side is equal to the number of atoms on the product side in an equation.

First we have to write the balanced chemical equation.

8NH₃ + 3Cl₂ → 6NH₄Cl + N₂

Here 8 moles of NH₃ produce 3 moles of Cl₂ to form 6 moles of NH₄Cl.

So,

12 mole NH₄Cl × [tex]\frac{8\ \text{mole}\ NH_3}{6\ \text{mole}\ NH_4Cl}[/tex]

= 16 moles NH₃

Thus, we can say that 16 moles of NH₃ are required to produce 12 moles of NH₄Cl.

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Answer:

There is 0.92 g of glucose in 100 mL of the final solution.

Explanation:

Initially, 11.5 g of glucose is added to the volumetric flask

Water is then added to 100 mL Mark,

The flask was then shaken until the solution was uniform.

The shaking of the mixture makes the concentration of glucose to become uniform all through the solution.

At this point, the concentration of this solution in g/mL is (11.5/100) = 0.115 g/mL

A 40.0 mL sample of this glucose solution was diluted to 0.500 L.

40.0 mL of the already mixed solution is then diluted to 0.500 L.

The mass of glucose in 40.0 mL of the mixed solution with concentration 0.115 g/mL is then given as

Mass = (conc in g/mL) × (volume) = 0.115 × 40 = 4.6 g

So, this mass is then diluted to 0.500 L mark.

New concentration = (mass)/(conc In mL) = (4.6/500) = 0.0092 g/mL

How many grams of glucose are in 100. mL of the final solution

Mass = (conc in g/mL) × (Volume in mL) = 0.0092 × 100 = 0.92 g

Hope this Helps!!!

Answer:

0.459 gram

Explanation:

Find the attachment

Answer:

See explanation

Explanation:

the compound that gives the fastest SN2 reaction with sodium methoxide- 1-bromohexane

the compound that gives the fastest SN1 reaction- 3-bromo-3-methylpentane

the compound(s) that undergo an SN1 reaction to give rearranged products- 1-bromo-2,2-dimethylbutane

the compound that is least reactive to sodium methoxide in methanol -

3-bromo-3-methylpentane

the compound(s) that can exist as diastereomers - 3-bromo-3-methylpentane

the compound(s) that can exist as enantiomers- 3-bromo-2-methylpentane

Complete Question:

t-Butyl alcohol (TBA) is an important octane enhancer that is used to replace lead additives in gasoline [Ind. Eng. Chem. Res., 27, 2224 (1988)]. TBA was produced by the liquid-phase hydration (W) of isobutene (I) over an Amberlyst-15 catalyst. The system is normally a multiphase mixture of hydrocarbon, water, and solid catalysts. However, the use of cosolvents or excess TBA can achieve reasonable miscibility. The reaction mechanism is believed to be

I + S ⇄ I*S

W + S ⇄ W*S

W*S + I*S ⇄ TBA * S * S

TBA * S ⇄ TBA + S

Derive a rate law assuming:

(a) The surface reaction is rate limiting

(b) The adsorption of isobutene is limiting

(c) The reaction follows Eley-rideal Kinetics

I*S+W ⇄ TBA * S

and surface reaction is limiting

(d) Isobutene (I) and water (W) are adsorbed on different sites

I + S₁ ⇄ I*S₁

W + S₂ ⇄ W*S₂

TBA is not on the surface, and the surface reaction is rate-limiting

[tex][Ans: r'_{TBA}=-r'_1=\frac{k[C_1C_w-C_{TBA/K_C}]}{(1+K_WC_W)(1+K_1C_1)} ][/tex]

(e) What generalizations can you make by comparing rate laws derived from part (a) through (d)?

Answer and explanation:

The mechanism for the production of t-butyl alcohol is as follows:

the reaction and rate law for the adsorption of isobutene over the amberlyst-15 is as follows:

I + S ⇄ I * S                                        [tex]-r_{ADI} = k_I(C_1C_v-\frac{C_{I.S}}{K_I} )[/tex]

where [tex]C_V[/tex] is the concentration of vacant site

[tex]K_I[/tex] is the equilibrium constant of the adsorption

[tex]k_I[/tex] is the rate constant for forward

[tex]C_I,C_{I.S}[/tex] are concentration of isobutene and site filled with isobutene

The reaction and rate law for the adsorption of water (W) over the amberlyst-15 catalyst catalyst is as follows

W + S ⇄ W.S                                      [tex]-r_{ADW} = k_W(C_WC_V-\frac{C_{W.S}}{K_W} )[/tex]

The reaction and rate law for the surface reaction on the catalyst is as follows

W.S + I.S ⇄ TBA . S + Sn                         [tex]-r_s = k_s(C_{W.S}C_{I.S}-\frac{C_{TBA.S}C_V}{K_s} )[/tex]

The reaction and rate law for the desorption of TBA from catalyst is as follows

TBA . S ⇄ TBA + S                             [tex]-r_{D TBA} = k_{DTBA}(C_{TBA.S}-\frac{C_{TBA}C_V}{K_{DTBA}} )[/tex]

the attached image below gives the remaining steps    

TBA, an octane enhancer, is produced by the hydration of isobutene over an Amberlyst-15 catalyst, resulting in a multiphase mixture that can be made miscible with the help of cosolvents or excess TBA.

The production of t-Butyl Alcohol (TBA) involves a liquid-phase hydration (W) of isobutene (I) over an Amberlyst-15 catalyst.  The question provides background information on the reaction mechanism and mentions the use of cosolvents or excess TBA to achieve reasonable miscibility in the multiphase mixture. This process results in a multiphase mixture of hydrocarbon, water, and solid catalysts. However, the use of cosolvents or excess TBA can aid in achieving miscibility. Essentially, the production of TBA serves as a safer alternative to lead additives in gasoline, enhancing octane levels.

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Answer: (a) The solubility of CuCl in pure water is [tex]1.1 \times 10^{-3} M[/tex].

(b) The solubility of CuCl in 0.1 M NaCl is [tex]9.5 \times 10^{-3} M[/tex].

Explanation:

(a)  Chemical equation for the given reaction in pure water is as follows.

           [tex]CuCl(s) \rightarrow Cu^{+}(aq) + Cl^{-}(aq)[/tex]

Initial:                         0            0

Change:                    +x           +x

Equilibm:                   x             x

[tex]K_{sp} = 1.2 \times 10^{-6}[/tex]

And, equilibrium expression is as follows.

          [tex]K_{sp} = [Cu^{+}][Cl^{-}][/tex]

       [tex]1.2 \times 10^{-6} = x \times x[/tex]

             x = [tex]1.1 \times 10^{-3} M[/tex]

Hence, the solubility of CuCl in pure water is [tex]1.1 \times 10^{-3} M[/tex].

(b)  When NaCl is 0.1 M,

       [tex]CuCl(s) \rightarrow Cu^{+}(aq) + Cl^{-}(aq)[/tex],  [tex]K_{sp} = 1.2 \times 10^{-6}[/tex]

   [tex]Cu^{+}(aq) + 2Cl^{-}(aq) \rightleftharpoons CuCl_{2}(aq)[/tex],  [tex]K = 8.7 \times 10^{4}[/tex]

Net equation: [tex]CuCl(s) + Cl^{-}(aq) \rightarrow CuCl_{2}(aq)[/tex]

               [tex]K' = K_{sp} \times K[/tex]

                          = 0.1044

So for, [tex]CuCl(s) + Cl^{-}(aq) \rightarrow CuCl_{2}(aq)[/tex]

Initial:                     0.1                 0

Change:                -x                   +x

Equilibm:            0.1 - x                x

Now, the equilibrium expression is as follows.

              K' = [tex]\frac{CuCl_{2}}{Cl^{-}}[/tex]

         0.1044 = [tex]\frac{x}{0.1 - x}[/tex]

              x = [tex]9.5 \times 10^{-3} M[/tex]

Therefore, the solubility of CuCl in 0.1 M NaCl is [tex]9.5 \times 10^{-3} M[/tex].

Final answer:

The solubility of CuCl in pure water and in 0.100 M NaCl solution both turn out to be 1.1 x 10^-3 M when formation of CuCl2- is ignored, determined using the provided Ksp.

Explanation:

To calculate the solubility of CuCl in pure water, we can use the solubility product constant (Ksp). The dissociation of CuCl can be represented as:

CuCl(s) ⇌ Cu+(aq) + Cl-(aq)

Let the solubility of CuCl be 's' moles per liter. At equilibrium, the concentration of Cu+ and Cl- ions will both be 's' M. So, the Ksp expression for CuCl is:

Ksp = [Cu+][Cl-] = (s)(s) = s²

Giving us:

s = √(1.2 x 10^-6) = 1.1 x 10^-3 M

This is the solubility of CuCl in pure water.

For the solubility of CuCl in 0.100 M NaCl solution, we have to consider the common ion effect. In this case, Cl- is the common ion. With the presence of 0.100 M NaCl, the concentration of Cl- ions at equilibrium will be higher. However, since we ignore the formation of CuCl2-, the solubility will still be governed by the Ksp of CuCl. The calculation will remain the same as in pure water, due to the assumption of ignoring CuCl2- formation:

s = 1.1 x 10^-3 M

Therefore, the presence of NaCl does not affect the solubility under the given conditions for this specific case.

Answer:

A. pH using molar concentrations = 2.56

B. pH using activities                      = 2.46

C. pH of mixture                              = 2.56

Explanation:

A. pH using molar concentrations

ClCH₂COOH + H₂O ⇌ ClCH₂COO⁻ + H₃O⁺

        HA        + H₂O ⇌          A⁻         + H₃O⁺

We have a solution of 0.08 mol HA and 0.04 mol A⁻

We can use the Henderson-Hasselbalch equation to calculate the pH.

[tex]\begin{array}{rcl}\text{pH} & = & \text{pK}_{\text{a}} + \log \left(\dfrac{[\text{A}^{-}]}{\text{[HA]}}\right )\\\\& = & 2.865 +\log \left(\dfrac{0.04}{0.08}\right )\\\\& = & 2.865 + \log0.50 \\& = &2.865 - 0.30 \\& = & \mathbf{2.56}\\\end{array}[/tex]

B. pH using activities

(i) Calculate [H⁺]

pH = -log[H⁺]

[tex]\text{[H$^{+}$]} = 10^{-\text{pH}} \text{ mol/L} = 10^{-2.56}\text{ mol/L} = 2.73 \times 10^{-3}\text{ mol/L}[/tex]

(ii) Calculate the ionic strength of the solution

We have a solution of 0.08 mol·L⁻¹ HA, 0.04 mol·L⁻¹ Na⁺, 0.04 mol·L⁻¹ A⁻, and 0.00273 mol·L⁻¹ H⁺.

The formula for ionic strength is  

[tex]I = \dfrac{1}{2} \sum_{i} {c_{i}z_{i}^{2}}\\\\I = \dfrac{1}{2}\left [0.04\times (+1)^{2} + 0.04\times(-1)^{2} + 0.00273\times(+1)^{2}\right]\\\\= \dfrac{1}{2} (0.04 + 0.04 + 0.00273) = \dfrac{1}{2} \times 0.08273 = 0.041[/tex]

(iii) Calculate the activity coefficients

[tex]\ln \gamma = -0.510z^{2}\sqrt{I} = -0.510(-1)^{2}\sqrt{0.041} = -0.510\times 0.20 = -0.10\\\gamma = 10^{-0.10} = 0.79[/tex]

(iv) Calculate the initial activity of A⁻

a = γc = 0.79 × 0.04= 0.032

(v) Calculate the pH  

[tex]\begin{array}{rcl}\text{pH} & = & \text{pK}_{\text{a}} + \log \left(\dfrac{a_{\text{A}^{-}}}{a_{\text{[HA]}}}\right )\\\\& = & 2.865 +\log \left(\dfrac{0.032}{0.08}\right )\\\\& = & 2.865 + \log0.40 \\& = & 2.865 -0.40\\& = & \mathbf{2.46}\\\end{array}\\[/tex]

C. Calculate the pH of the mixture

The mixture initially contains 0.08 mol HA, 0.04 mol Na⁺, 0.04 mol A⁻, 0.05 mol HNO₃, and 0.06 mol NaOH.

The HNO₃ will react with the NaOH to form 0.05 mol Na⁺ and 0.05 mol NO₃⁻.

The excess NaOH will react with 0.01 mol HA to form 0.01 mol Na⁺ and 0.01 mol A⁻.

The final solution will contain 0.07 mol HA, 0.10 mol Na⁺, 0.05 mol A⁻, and 0.05 mol NO₃⁻.

(i) Calculate the ionic strength

[tex]I = \dfrac{1}{2}\left [0.10\times (+1)^{2} + 0.05 \times(-1)^{2} + 0.05\times(-1)^{2}\right]\\\\= \dfrac{1}{2} (0.10 + 0.05 + 0.05) = \dfrac{1}{2} \times 0.20 = 0.10[/tex]

(ii) Calculate the activity coefficients

[tex]\ln \gamma = -0.510z^{2}\sqrt{I} = -0.510(-1)^{2}\sqrt{0.10} = -0.510\times 0.32 = -0.16\\\gamma = 10^{-0.16} = 0.69[/tex]

(iii) Calculate the initial activity of A⁻:

a = γc = 0.69 × 0.05= 0.034

(iv) Calculate the pH

[tex]\text{pH} = 2.865 + \log \left(\dfrac{0.034}{0.07}\right ) = 2.865 + \log 0.49 = 2.865 - 0.31 = \mathbf{2.56}[/tex]

Answer:

Explanation:

Compounds derived from Phosphatidyl choline are referred to as Lysolecithins.  These compounds are  amphiphatic in nature and have both hydrophilic and hydrophobic regions.

Choline, glycerol, and phosphate represent the hydrophyilic portion of lysolecithins,while the fatty acid on C1 is hydrophobic in nature.

Glycerol, choline and phosphate act as a polar tail whereas the fatty acid acts as a long polar head which represents an amphipathic molecule like detergents.

Answer: 1. n

2. n

3. [tex]m_s[/tex]

4. l

Explanation:

Principle Quantum Numbers : It describes the size of the orbital and the energy level. It is represented by n. Where, n = 1,2,3,4....

Azimuthal Quantum Number : It describes the shape of the orbital. It is represented as 'l'. The value of l ranges from 0 to (n-1).For l = 0,1,2,3... the orbitals are s, p, d, f...

Magnetic Quantum Number : It describes the orientation of the orbitals. It is represented as [tex]m_s[/tex] . The value of this quantum number ranges from -l to +l.

Spin Quantum number : It describes the direction of electron spin. This is represented as s.

To determine the energy of an electron in a many-electron atom, the principal and angular momentum quantum numbers are needed (n and l). The principal quantum number (n) primarily determines the size of an orbital, while the magnetic quantum number (ml) is needed for its orientation. The angular momentum quantum number (l) is responsible for the general shape of an orbital.

To determine the energy of an electron in a many-electron atom, the following quantum numbers are needed:

The most important information in determining the size of an orbital is:

To determine the orientation of an orbital, the quantum number needed is:

The quantum number needed to determine the general shape of an orbital is: I (angular momentum quantum number), which describes the shape or type of the orbital.

Each electron also has a spin quantum number, ms, which determines the spin of an electron and can have a value of either +1/2 or -1/2.

10 litres = 0.01 cubic meter

Answer:

Mine drainage Sample 1:   [tex][Fe(II)] sample 1 = \frac{121 \mu gFe(II)}{1ml} = 121 \frac{\mu g}{ml}[/tex]

Mine drainage Sample 2:   [tex][Fe(II)] sample 2 = \frac{127 \mu gFe(II)}{1ml} = 127 \frac{\mu g}{ml}[/tex]

Explanation:

Answer:

The approximate mass of the water is 80kg

Explanation: Heat lost=heat gained

M1c1(Ʃ)=M2c2(Ʃ)

M1 is mass of aluminum

M2 is the mass of water

C1 is specific heat capacity of aluminum

C2 is specific heat capacity of water

Ʃ is change in temperature.

60 x0.897 x(55-25)=M2 x 4.18 x (25-20.15)

1614.6=20.27M2

M2=79.65

M2=80kg

Answer:

Mass of NaHCO₃ required for the neutralization = 0.143 g

Explanation:

The reaction between HCl and NaHCO₃ is given as

HCl + NaHCO₃ → NaCl + H₂O + CO₂

The fluid in the stomach of a man suffering from indigestion is considered to be 50 mL of a 0.034 M HCl solution. The mass of NaHCO₃ he would need to ingest to neutralize this much HCl.

We forst need to calculate the number of moles of HCl in 50.0 mL of 0.034 M HCl

(Number of moles) = (Conc in mol/L) × (Volume in L)

Conc in mol/L = 0.034 M

Volume in L = (50/1000) = 0.05 L

Number of moles of HCl = 0.034 × 0.05 = 0.0017 moles

From the stoichiometric balance of the reaction,

1 mole of HCl requires 1 mole of NaHCO₃

0.0017 moles of HCl will require 0.0017 moles of NaHCO₃.

So, we can then.calculate the mass of NaHCO₃ required for this neutralization.

Mass = (Number of moles) × (Molar mass)

Molar mass of NaHCO₃ = 84.007 g/mol

Mass of NaHCO₃ required for this neutralization = 0.0017 × 84.007 = 0.1428119 g = 0.143 g to 3 s.f because calculated values usually have 1 more significant figure than the given parameters for the calculations.

Hope this Helps!!!

Answer:

Electrospray ionization

Explanation:

Electrospray ionization Is a soft ionization technique used in producing ions from macromolecules, it is employed especially in spectrometry where high voltage is used to create an aerosol from a liquid.It can be employed in Knowing molecular weights of molecules and biological macromolecules such as Peptides and proteins. Therefore, electrospray ionization is the method typically requires analyte ions to be in solution prior to reaching the interface between the column in liquid chromatography and the mass spectrometer

Answer:

V= 250ml

Explanation:

From n= CV

3= 12×V

V= 0.25L= 250ml

Final answer:

To find the number of moles of nitrogen in a 16,500 mL sample at STP, convert the volume to liters and divide by the molar volume of 22.4 L/mol, resulting in approximately 0.7366 moles of nitrogen.

Explanation:

To calculate the number of moles of nitrogen in a 16,500 mL sample of nitrogen at STP (Standard Temperature and Pressure), we should use the molar volume of a gas at STP, which is 22.4 L/mol. This means that at STP, 1 mole of any gas occupies 22.4 liters.

First, we need to convert the volume of nitrogen from milliliters to liters:

16,500 mL × (1 L / 1,000 mL) = 16.5 L

Then, we divide the volume of nitrogen by the molar volume:

16.5 L / 22.4 L/mol = 0.7366 moles

Therefore, the sample contains approximately 0.7366 moles of nitrogen gas.

Final answer:

To find the volume of the sample after the given reaction, Avogadro's law is used to show that the volume of gases at constant temperature and pressure is directly proportional to the number of moles. The balanced equation indicates that two times the volume of NH3 gas is produced from one volume of N2 gas. The final volume of the sample is calculated to be 10.25 L after the reaction.

Explanation:

To determine the volume of the sample after the reaction between N2 and H2, we must first understand the stoichiometry of the reaction. The balanced chemical equation for the synthesis of ammonia is:

N2(g) + 3H2(g) → 2NH3(g)

According to Avogadro's law, at constant temperature and pressure, equal volumes of gases contain an equal number of molecules. Thus, in our reaction, one volume of N2 reacts with three volumes of H2 to produce two volumes of NH3. In this case, we begin with 0.1100 mol of N2 and 0.3300 mol of H2. Since H2 is present in excess (needed only 3 times the amount of N2), all of the N2 will be consumed first.

The stoichiometry tells us that 1 mol of N2 reacts with 3 mol of H2 to form 2 mol of NH3. So 0.1100 mol of N2 would produce 0.2200 mol of NH3. Since we are assuming the temperature and pressure are constant, we can use the ratio of moles to determine the change in volume. Initially, there are 0.1100 + 0.3300 = 0.4400 mol of gases and after reaction we have 0.2200 mol of NH3.

The initial volume is 20.5 L. With the moles reducing from 0.4400 to 0.2200, the volume occupied by the gases after the reaction is expected to be half of the initial volume, given the relationship V1/n1 = V2/n2 where V is volume and n is the number of moles. Therefore, the volume of the sample after the reaction is 10.25 L.

Final answer:

By applying Avogadro's law, we determine that all of the initial N2 and H2 reacts to form NH3. Because equal volumes of any gas at the same temperature and pressure have the same number of molecules, we understand that the volume of NH3 produced will be equivalent to the volume of N2 reactant consumed plus three times this volume due to 3H2 reacting. Therefore, the final volume should be less than the initial volume since 2 moles of NH3 will be produced from 4 moles of combined reactants.

Explanation:

Understanding Reaction Volumes and Avogadro's Law:

Based on the balanced chemical equation N2(g) + 3H2(g) → 2NH3(g), we can apply Avogadro's law to determine the change in volume when the reaction occurs at constant temperature and pressure.

At the onset, we have 0.1100 mol of N2(g) and 0.3300 mol of H2(g) occupying a combined volume of 20.5 L. Assuming the reaction goes to completion, we start by identifying the limiting reactant, the reactant that will be completely consumed in the reaction. The stoichiometry of the reaction indicates that for every 1 mol of N2, 3 mol of H2 are required.

For 0.1100 mol of N2, we would need 0.3300 mol of H2 to fully react based on the stoichiometry of 1:3. Since we have exactly 0.3300 mol of H2, it means N2 is the limiting reactant and all of it will be converted into NH3.

Now, according to Avogadro's law, if one mole of N2 gas occupies a certain volume and reacts to form two moles of NH3 at the same conditions of temperature and pressure, the volume of NH3 produced will double that of the N2 because two moles of NH3 contain double the number of molecules compared to one mole of N2. However, since H2 also takes up volume and we have three moles of H2 reacting for every mole of N2, the total volume initially is the volume of N2 plus three times the volume of N2 (which is the volume of H2).

The stoichiometry tells us that 1 mol of N2 reacts with 3 mol of H2 to form 2 mol of NH3. So 0.1100 mol of N2 would produce 0.2200 mol of NH3. Since we are assuming the temperature and pressure are constant, we can use the ratio of moles to determine the change in volume. Initially, there are 0.1100 + 0.3300 = 0.4400 mol of gases and after reaction we have 0.2200 mol of NH3.

The initial volume is 20.5 L. With the moles reducing from 0.4400 to 0.2200, the volume occupied by the gases after the reaction is expected to be half of the initial volume, given the relationship V1/n1 = V2/n2 where V is volume and n is the number of moles. Therefore, the volume of the sample after the reaction is 10.25 L.

A Sentence that I Used:

The position of Met seems incorrect. The amino acid sequences of all proteins begin with Met because it is the amino acid that is attached to the anticodon for the AUG start codon. It looks like the student might have worked in a backward direction for transcription.

Answer:

a) ii

b)iii

c)iii

Explanation:

three atoms directly bonded then only it is possible to achieve trigonal planar

trigonal bipyramidal means five atoms should attach to central atom

for octahedral six atoms must directly connected to central atom

Answer:

Check the explanation

Explanation:

The hydroxyl radical, •OH, is the hydroxide ion (OH−) when in neutral form of the Hydroxyl radicals they are extremely reactive (easily becoming hydroxy groups) and as a result are short-lived; however, they form a significant part of radical chemistry. The hydroxyl radical composition is also highly reactive towards oxidative reactions.

Kindly check the attached image below to see the step by step explanation to the question above.

Answer:

the ionic radius of the anion [tex]r^- = 312.52 \ pm[/tex]

Explanation:

From the diagram shown below :

The anion [tex]Cl^-[/tex] is located at the corners

The cation [tex]Cs^+[/tex] is located at the body center

The Body diagonal length =  [tex]\sqrt{3 \ a }[/tex]

∴ [tex]2 \ r^+ \ + 2r^- \ = \sqrt{3 \ a} \\ \\ r^+ +r^- = \frac{\sqrt{3}}{2} a[/tex]

Given that :

[tex]\frac{r^+}{r^-} =0.84[/tex]   (i.e the  ratio of the ionic radius of the cation to the ionic radius of

                 the anion )

[tex]0.84r^- \ + r^- \ = \frac{\sqrt{3}}{2}a \\ \\ 1.84 r^- = \frac{3}{2}a \\ \\ r^- = \frac{\sqrt{3}}{2*1.84}a[/tex]

Also ; a =  664 pm

Then :

[tex]r^- = \frac{\sqrt{3} }{2*1.84}*664 \ pm\\ \\ r^- = 312.52 \ pm[/tex]

Therefore,  the ionic radius of the anion [tex]r^- = 312.52 \ pm[/tex]

The ionic radius of the anion  [tex]r^-=312.52pm[/tex]

The anion is placed on the corners and the cation  is placed on the frame center.

The Body diagonal length =  [tex]\sqrt{3a}[/tex]

[tex]2r^++2r^-=\sqrt{3a} \\\\r^++r^-=\sqrt{3}/2a }[/tex]

Given:

Ratio=  0.840

[tex]\frac{r^+}{r^-}=0.840[/tex]

[tex]0.84r^-+r^-=\sqrt{3}/2a \\\\1.84r^-=3/2a\\\\r^-=\sqrt{3}/2*1.84a[/tex]

Also ; a =  664 pm

Then : [tex]r^-[/tex] =312.52 pm

Therefore,  the ionic radius of the anion = 312.52 pm

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Answer:

Explanation:

The rate of diffusion of nickle in is higher in liquid state than solid state which is affect the ease of equilibrium of microstructure.

When peritectic composition of 4.5% nickle is called from peritectic temperature due to high rate of diffusion of nickle into iron we get fine microstructure containing more nickle atoms in the iron.

Due to high rate of diffusion more no. Of microstructure created from where new grain is generated. So the microstructure will get equilibrium soon after cooling.

Answer:

Explanation:

The rate of diffusion of nickle in is higher in liquid state than solid state which is affect the ease of equilibrium of micro structure.

When peritectic composition of 4.5% nickle is called from peritectic temperature due to high rate of diffusion of nickle into iron we get fine micro structure containing more nickle atoms in the iron.

Due to high rate of diffusion more no. Of micro structure created from where new grain is generated. So the micro structure will get equilibrium soon after cooling.

Answer:

                    SEPARATION SCHEME FOR  CATIONS

GIVEN  CATIONS : [tex]Ag^{+} \ , Fe^{3+} , Cu^{2+}, Ni^{2+}[/tex]

    Step 1:   Add [tex]6mol/dm^3[/tex] of [tex]HCl[/tex] to the mixture solution

    Result : This would cause a precipitate of [tex]AgCl[/tex] to be formed

    Reaction :  [tex]Ag^{+} _{(aq)} + Cl^{-} _{(aq)} ---------> AgCl(ppt)[/tex]

    Step 2 : Next is to remove the precipitate and add [tex]H_2S[/tex] to the remaining          

                 solution in the presence of [tex]0.2 \ mol/dm^3[/tex] of HCl

     Result : This would cause a precipitate of [tex]CuS[/tex] to be formed

     Reaction :  [tex]Cu^{2+}_{(aq)} + S^{2-}_{(aq)} ------> Cu_2S(ppt)[/tex]

     Step 3: Next remove the precipitate then add [tex]6 \ mol/dm^3[/tex] of aqueous      

                 [tex]NH_3 (NH_3 \cdot H_2 O)[/tex] , process the solution in a centrifuge,when the  

                 process  is done then sort out the  precipitate from the  solution

                 Now this precipitate is   [tex]Fe(OH)_3[/tex] and the remaining solution

                contains  [tex](Ni (NH_3)_6)[/tex]

                 Next take out the precipitate to a different beaker and add HCl

                to it   this will dissolve it, then add a drop of [tex]NH_4SCN[/tex] this will

                form  a precipitate  [tex]Fe(SCN)_{6}^{3-}[/tex] which will have the color of

                 blood  indicating the presence of [tex]Fe^{3+}[/tex]

   Reaction :   [tex]F^{3+}_{(aq)} + 30H^-_{(aq)} --------->Fe(OH)_3_{(aq)}[/tex]

                        [tex]Fe (OH)_{(s)} _3 + 3H^{+}_{aq} -------> Fe^{3+}_{aq} + 3H_2O_{(l)}[/tex]

                         [tex]Fe^{3+} + 6SCN^{-} -----> Fe(SCN)_6 ^{3-}[/tex]

                      Now the remaining mixture contains [tex]Ni^{2+}[/tex]

Explanation:

The starting alkyne is 3-hexyne, and after the ozonolysis process and treatment with water, the resulted product is hexanoic acid.

In the given question, an alkyne with the molecular formula C6H10 is treated with ozone followed by water, to produce one type of carboxylic acid via the process of ozonolysis. The starting alkyne for this reaction probably is 3-hexyne. During ozonolysis, the alkyne triple bond is cleaved, forming two equivalent aldehydes. But these aldehydes are further oxidized into carboxylic acids when water is used as second reagent. The produced product, hence, is hexanoic acid.

Remember, in the process of ozonolysis, alkynes are oxidized and cleaved into smaller molecules. These molecules usually have carbonyl groups such as aldehydes and ketones. But in this scenario, because of the hydration step, we end up with a carboxylic acid.

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Answer:

0.35 atm

Explanation:

It seems the question is incomplete. But an internet search shows me these values for the question:

" At a certain temperature the vapor pressure of pure thiophene (C₄H₄S) is measured to be 0.60 atm. Suppose a solution is prepared by mixing 137. g of thiophene and 111. g of heptane (C₇H₁₆). Calculate the partial pressure of thiophene vapor above this solution. Be sure your answer has the correct number of significant digits. Note for advanced students: you may assume the solution is ideal."

Keep in mind that if the values in your question are different, your answer will be different too. However the methodology will remain the same.

First we calculate the moles of thiophene and heptane, using their molar mass:

Total number of moles = 1.63 + 1.11 = 2.74 moles

The mole fraction of thiophene is:

Finally, the partial pressure of thiophene vapor is:

Partial pressure = Mole Fraction * Vapor pressure of Pure Thiophene

Final answer:

The partial pressure of thiophene vapor above an ideal solution can be determined by calculating the mole fraction of thiophene and then applying Raoult's Law, which involves multiplying the mole fraction by the vapor pressure of pure thiophene.

Explanation:

To calculate the partial pressure of thiophene vapor above the solution, we can utilize Raoult's Law, which pertains to ideal solutions. According to Raoult's Law, the partial pressure of a component in a solution is equal to the vapor pressure of the pure component multiplied by its mole fraction in the solution (mole fraction). To find the mole fraction of thiophene, we will sum up the total moles of both thiophene and acetyl bromide and use their respective amounts to calculate the mole fractions for each.

First, we calculate the mole fraction of thiophene (Xthiophene) in the solution:

The partial pressure of thiophene vapor can therefore be obtained, ensuring we keep consistent units and consider significant digits as per the given values in the question.

To produce a solution with [H+]= 3.5×10−11 M, 0.14 mol of solid NaOH must be added to 1.0 L of a 0.14 M H2CO3 solution.

To calculate the amount of solid NaOH needed, we need to use the balanced chemical equation for the reaction between NaOH and H2CO3. The equation is:

NaOH + H2CO3 -> Na2CO3 + H2O

From the equation, we can see that the ratio between NaOH and H2CO3 is 1:1. Therefore, the amount of solid NaOH needed is equal to the molarity of H2CO3 multiplied by the volume, which is:

Amount of solid NaOH = 0.14 M * 1.0 L = 0.14 mol NaOH

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Answer:

-42556.5 J

Explanation:

From gas law,

The work done by gas is given as,

W = PΔV......................... Equation 1

Where W = Work done on the gas mixture, P = Pressure of the gas mixture, ΔV = Change in volume of the gas mixture.

Given: P = 15 atm = (15×101325) N/m² = 1519875 N/m², ΔV = 68-96 = -28 L = -28/1000 = -0.028 m³

Substitute into equation 2

W = 1519875(-0.028)

W = -42556.5 J

Hence the work done by the gas mixture = -42556.5 J

The work performed on the gas mixture of krypton and neon when compressed at a constant pressure of 15.0 atm from a volume of 96.0L to 68.0L is -4.26 x 10⁴ joules.

The subject question asks to compute the work done on a gas mixture comprising krypton and neon as it's compressed from a volume of 96.0L to 68.0L, with a constant pressure of 15.0 atm. The calculation of work done on gas under constant pressure relies on the formula W = -P ΔV, where W is work, P represents pressure, and ΔV is the change in volume. In this problem, P = 15.0 atm, which we will convert to pascals (1 atm = 1.01 × 10⁵ Pa). The change in volume ΔV = Vf - Vi = 68.0L - 96.0L = -28.0L, which we will convert to cubic meters (1L = 1.0 × 10-³ m³). Applying these values, W = -P ΔV = -(15.0atm) * (-28.0L) = 420 L*atm. To convert this to joules, we can use the conversion factor 101.3 J = 1 L*atm, which results in a final answer of -4.26 x 10⁴ J. The result is negative as it indicates the work is done on the gases.

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