Write the symbol for each of the following ions: (a) the ion with a 3+ charge, 28 electrons, and a mass number of 71 (b) the ion with 36 electrons, 35 protons, and 45 neutrons (c) the ion with 86 electrons, 142 neutrons, and a 4+ charge (d) the ion with a 2+ charge, atomic number 38, and mass number 87

Answer: The [tex]\Delta H^o_{rxn}[/tex] for the reaction is 15.3 kJ.

Explanation:

Hess’s law of constant heat summation states that the amount of heat absorbed or evolved in a given chemical equation remains the same whether the process occurs in one step or several steps.

According to this law, the chemical equation is treated as ordinary algebraic expressions and can be added or subtracted to yield the required equation. This means that the enthalpy change of the overall reaction is equal to the sum of the enthalpy changes of the intermediate reactions.

The chemical equation for the reaction of carbon and water follows:

[tex]2C(s)+2H_2O(g)\rightarrow CH_4(g)+CO_2(g)[/tex]      [tex]\Delta H^o_{rxn}=?[/tex]

The intermediate balanced chemical reaction are:

(1) [tex]C(s)+H_2O(g)\rightarrow CO(g)+H_2(g)[/tex]    [tex]\Delta H_1=131.3kJ[/tex]    ( ×  2)

(2) [tex]CO(g)+H_2O(g)\rightarrow CO_2(g)+H_2(g)[/tex]     [tex]\Delta H_2=-41.2kJ[/tex]

(3) [tex]CH_4(g)+H_2O(g)\rightarrow 3H_2(g)+CO(g)[/tex]     [tex]\Delta H_3=206.1kJ[/tex]

The expression for enthalpy of the reaction follows:

[tex]\Delta H^o_{rxn}=[2\times \Delta H_1]+[1\times \Delta H_2]+[1\times (-\Delta H_3)][/tex]

Putting values in above equation, we get:

[tex]\Delta H^o_{rxn}=[(2\times (131.3))+(1\times (-41.2))+(1\times (-206.1))]=15.3kJ[/tex]

Hence, the [tex]\Delta H^o_{rxn}[/tex] for the reaction is 15.3 kJ.

Answer:

Molarity = 4.79 M

Explanation:

Mass percentage -

Mass percentage of A is given as , the mass of the substance A by mass of the total solution multiplied by 100.

i.e.

mass % A = mass of A / mass of solution * 100  

Given,

24% by mass of ammonium chloride,

so,

100 g solution contains , 24 g of ammonium chloride,

mass of solution = 100g

and mass of the solute , i.e. , ammonium chloride = 24 g .

Hence,

Moles -

Moles are calculated as the given mass divided by the molecular mass.  

i.e. ,

moles = ( mass / molecular mass )

Given,

The molecular mass of ammonium chloride is 53.50 g /mol

moles of ammonium chloride = 24 g / 53.50 g /mol

moles of ammonium chloride = 0.449 mol

Density -

Density of a substance is given as the mass divided by the volume ,

Density = mass / volume ,

Volume = mass / density

Given ,

Density of ammonium chloride = 1.0764 g /mL

Calculated above , mass of solution = 100 g

volume of solution = 100 g / 1.0764 g/ mL

volume of solution = 93.69 mL

Since , 1 ml = 1/1000 L

volume of solution = 93.69 /1000 L

volume of solution = 0.09369 L

Molarity -

Molarity of a solution is given by the moles of solute per liter of the solution

Hence,  

M = moles of solute / volume of solution (in L)

As calculated above,

moles of ammonium chloride = 0.449 mol

volume of solution = 0.09368 L

Putting in the above formula

Molarity = 0.449 mol / 0/09368 L

Molarity = 4.79 M

The molarity of ammonium chloride in the solution is 4.79 M

The number of moles of solute dissolved in one liter of solution is the molarity (M) of the solution.

Calculation of molarity:

Given,

The mass of the solution is 24.0%

Density is 1.0674 g/ml

The weight of NH4Cl is 53.50 g/mol

Step 1: Convert Mass % into gram

Considering the mass of solution = 100g

24% of 100g

Mass is 24 gram

Step 2: Calculate the mole compound

Moles = mass divided from molecular mass

The molecular mass of ammonium chloride is 53.50 g /mol

Thus,

[tex]\bold{Moles = \dfrac{24}{53.50} = 0.449 mol}[/tex]

Step 3: Calculating the volume

[tex]\bold{Volume = \dfrac{mass}{density} }[/tex]

[tex]\bold{Volume = \dfrac{ 100}{1.0674 g/m} = 93.69 ml}[/tex]

[tex]\bold{Volume\; of \;solution= \dfrac{ 93.69}{1000 L} = 0.09369 L}[/tex]

Step 4: Now, Molarity of the compound is

[tex]\bold{Molarity = \dfrac{moles\; of\; solute}{volume\; of \;solution (in L)}}[/tex]

Mole of ammonium chloride = 0.449 mol

Volume of solution = 0.09368 L

By formula,

[tex]\bold{Molarity = \dfrac{0.449 mol}{0.09368 L} = 4.79 m}[/tex]

Thus, the Molarity of ammonium chloride is  = 4.79 m.

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Answer:Kindly find the structure of A and B in attachment.

Explanation:

Lindlars catalyst is basically a palladium metal based catalyst which reduces specifically the alkynes to just alkenes and only reduce them in cis manner.

The palladium catalyst is poisoned by lead or quinoline so that the reduction reaction can be stopped at a point when alkynes are just reduced to alkenes because palladium in presence of hydrogen reduces the alkyne completely to alkane.

So lindlars catalys is very specific in its action and even in terms of stereochemistry as it only reduces alkynes to alkenes and the stereochemistry of reduced alkyne is cis.

The general formula of lindlars catalyst is : 5%Pd-CaCO3,Pb(OCOCH3)2 and quinoline.

A chiral alkyne would have all 4 different substituents present at the carbon next to triple bond.

since the reduction of chiral alkyne A would be done using Lindlars catalyst hence the reduced product formed would have Cis -stereochemistry.

The structures of A&B are drawn in attachments. Kindly find in attachment.

The chiral alkyne is 2-hexyne and when it's reduced using H2 and Lindlar catalyst, it forms cis-2-hexene which has the R configuration at its stereogenic center.

The molecule A is a chiral alkyne with the molecular formula C6H10. This indicates that this alkyne molecule contains a chiral center. The most likely structure is 2-hexyne (CH3CH2C≡CCH2CH3), which features a triple bond between the 2nd and 3rd carbons.

When reduced with H2 and Lindlar catalyst, the molecule A is converted into molecule B. The Lindlar catalyst is used specifically to reduce alkynes to cis-alkenes. Thus, molecule B would be cis-2-hexene (CH3CH2CH=CHCH2CH3) as this is the alkene version with a chiral center.

It is specified that molecule B has the R configuration at its stereogenic center. The R or S configuration can be determined by the Cahn-Ingold-Prelog (CIP) priority rules. In the case of cis-2-hexene, assuming the hydrogen atom is bonded to the chiral carbon, a clockwise (R) configuration can be achieved.

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Answer : The molality, mass/mass percent, and mass/volume percent are, 0.0381 mole/Kg, 25.67 % and 32.086 % respectively.

Solution : Given,

Density of solution = 1.25 g/ml

Molar mass of [tex]MgCl_2[/tex] (solute) = 95.21 g/mole

3.37 M magnesium chloride means that 3.37 gram of magnesium chloride is present in 1 liter of solution.

The volume of solution = 1 L = 1000 ml

Mass of [tex]MgCl_2[/tex] (solute) = 3.37 g

First we have to calculate the mass of solute.

[tex]\text{Mass of }MgCl_2=\text{Moles of }MgCl_2\times \text{Molar mass of }MgCl_2[/tex]

[tex]\text{Mass of }MgCl_2=3.37mole\times 95.21g/mole=320.86g[/tex]

Now we have to calculate the mass of solution.

[tex]\text{Mass of solution}=\text{Density of solution}\times \text{Volume of solution}=1.25g/ml\times 1000ml=1250g[/tex]

Mass of solvent = Mass of solution - Mass of solute = 1250 - 320.86 = 929.14 g

Now we have to calculate the molality of the solution.

[tex]Molality=\frac{\text{Mass of solute}\times 1000}{\text{Molar mass of solute}\times \text{Mass of solvent}}=\frac{3.37g\times 1000}{95.21g/mole\times 929.14g}=0.0381mole/Kg[/tex]

The molality of the solution is, 0.0381 mole/Kg.

Now we have to calculate the mass/mass percent.

[tex]\text{Mass by mass percent}=\frac{\text{Mass of solute}}{\text{Mass of solution}}\times 100=\frac{320.86}{1250}\times 100=25.67\%[/tex]

The mass/mass percent is, 25.67 %

Now we have to calculate the mass/volume percent.

[tex]\text{Mass by volume percent}=\frac{\text{Mass of solute}}{\text{Volume of solution}}\times 100=\frac{320.86}{1000}\times 100=32.086\%[/tex]

The mass/volume percent is, 32.086 %

Therefore, the molality, mass/mass percent, and mass/volume percent are, 0.0381 mole/Kg, 25.67 % and 32.086 % respectively.

Answer:

The percent recovery from re crystallization for both compounds A and B is 69.745 and 81.44 % respectively.

Explanation:

Mass of compound A in a mixture  = 119 mg

Mass of compound A after re-crystallization = 83 mg

Percent recovery from re-crystallization :

[tex]\frac{\text{Mass after re-crystallization}}{\text{Mass before re-crystallization}}\times 100[/tex]

Percent recovery of compound A:

[tex]\frac{83 mg}{119 mg}\times 100=69.74\%[/tex]

Mass of compound B in a mixture  = 97 mg

Mass of compound B after re-crystallization = 79 mg

Percent recovery of compound B:

[tex]\frac{79 mg}{97 mg}\times 100=81.44\%[/tex]

Answer : The rate of change of the total pressure of the vessel is, 10.5 torr/min.

Explanation : Given,

[tex]\frac{d[NO]}{dt}[/tex] =21 torr/min

The balanced chemical reaction is,

[tex]2NO(g)+Cl_2(g)\rightarrow 2NOCl(g)[/tex]

The rate of disappearance of [tex]NO[/tex] = [tex]-\frac{1}{2}\frac{d[NO]}{dt}[/tex]

The rate of disappearance of [tex]Cl_2[/tex] = [tex]-\frac{d[Cl_2]}{dt}[/tex]

The rate of formation of [tex]NOCl[/tex] = [tex]\frac{1}{2}\frac{d[NOCl]}{dt}[/tex]

As we know that,

[tex]\frac{d[NO]}{dt}[/tex] =21 torr/min

So,

[tex]-\frac{d[Cl_2]}{dt}=-\frac{1}{2}\frac{d[NO]}{dt}[/tex]

[tex]\frac{d[Cl_2]}{dt}=\frac{1}{2}\times 21torr/min=10.5torr/min[/tex]

And,

[tex]\frac{1}{2}\frac{d[NOCl]}{dt}=\frac{1}{2}\frac{d[NO]}[/tex]

[tex]\frac{d[NOCl]}{dt}=\frac{d[NO]}=21torr/min[/tex]

Now we have to calculate the rate change.

Rate change = Reactant rate - Product rate

Rate change = (21 + 10.5) - 21 = 10.5 torr/min

Therefore, the rate of change of the total pressure of the vessel is, 10.5 torr/min.

The rate of change of the total pressure of the vessel is 10.5 torr/min

The given reaction is expressed as:

[tex]\mathbf {2O_{(g)} + Cl_{2(g)} \to 2NOCl_{(g)}}}[/tex]

From chemical kinetics, the average rate (r) can be expressed as:

[tex]\mathbf{r = -\dfrac{1}{2}\dfrac{d[NO]}{dt}= -\dfrac{d[Cl_2]}{dt}=\dfrac{1}{2}\dfrac{d[NOCl]}{dt} }[/tex]

where;

∴

We are being told that the partial pressure of NO is decreasing at 21 torr/min

i.e.

and we know that:

[tex]\mathbf{\dfrac{-d[Cl_2]}{dt}= -\dfrac{1}{2} \dfrac{d[NO]}{dt}}}[/tex]

∴

Similarly;

Now, we need to determine the rate of change of the total pressure at which these substances are decreasing;

Rate change = rate of reactant  - rate of product.

[tex]\mathbf{Rate \ change =} \mathbf{\mathbf{ \dfrac{d[NO]}{dt}} +\dfrac{d[Cl_2]}{dt} - \dfrac{d[NOCl]}{dt} }[/tex]

[tex]\mathbf{Rate \ change =} \mathbf{(21 \ torr/min) +(10.5 \ torr/min) -( 21 \ torr/min})[/tex]

Rate change = 10.5 torr/min

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Answer: NO is the limiting reagent in the given reaction and 0.857 moles of [tex]NO_2[/tex] will be produced.

Explanation:

Limiting reagent is defined as the reagent which is present in less amount and it limits the formation of products.

Excess reagent is defined as the reagent which is present in large amount.

For the given chemical reaction:

[tex]2NO(g)+O_2(g)\rightarrow 2NO_2(g)[/tex]

We are given:

Moles of NO = 0.857 mol

Moles of oxygen = 0.498 mol

By stoichiometry of the reaction:

If 2 moles of NO reacts with 1 mole of oxygen gas.

So, 0.857 moles of NO will react with = [tex]\frac{1}{2}\times 0.857=0.4285mol[/tex] of [tex]O_2[/tex]

As, the given amount of oxygen gas is more than the required amount. So, it is considered as an excess reagent.

Thus, NO is considered as the limiting reagent because it limits the formation of products.

By Stoichiometry of the reaction:

If 2 moles of NO produces 2 moles of nitrogen dioxide gas.

So, 0.857 moles of NO will produce = [tex]\frac{2}{2}\times 0.857=0.857mol[/tex] of [tex]NO_2[/tex]

Hence, NO is the limiting reagent in the given reaction and 0.857 moles of [tex]NO_2[/tex] will be produced.

Answer:

The main difference between suspension and emulsion polymerization is that suspension polymerization requires a dispersing medium, monomer(s), stabilizing agents and initiators whereas emulsion polymerization requires water, monomer and a surfactant.

Explanation:

The molar solubility of Zn(CN)2 in a solution with a given pH and Ksp can be calculated using principles of acid-base equilibria and solubility. However, without exact initial concentrations, a complete calculation can't be provided. Similar applications of these principles are seen in the examples of Cadmium Sulfide (CdS) or mercury chloride mentioned previously.

The question involves the determination of the molar solubility of Zinc Cyanide (Zn(CN)2) in a solution with a given pH. The main principle involved is the understanding of acid-base equilibria and solubility. The pH value provided implies an [H3O+] = 10^-1.33. The Ka for Hydrogen Cyanide (HCN) is given which can be used to calculate [CN-]. After these concentrations are calculated, they can be utilized to find the molar solubility of Zn(CN)2 using the given Ksp.

Based on the information provided, some calculations similar to those mentioned but applied to Zn(CN)2 will have to be performed. However, we do not have certain required values like the exact initial concentration of the solution. Therefore, a complete solution can't be provided

However, similar stoichiometry-based calculations are applied to other salts' equilibria for determining molar solubility like Cadmium Sulfide (CdS) and Dissolution stoichiometry of mercury chloride in the provided data. These applications demonstrate how such problems are typically approached and solved.

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The concentration of S in the 10.0 mL solution is calculated by considering the initial 8.48 mM concentration and the dilution factor due to the increase in volume to 10.0 mL. The final concentration of S is found to be 0.848 mM.

To determine the concentration of S in the 10.0 mL solution, you must take into account the initial concentration of S and how it changes with dilution. Initially, 1.00 mL of 8.48 mM (millimolar) S was added to the solution. The dilution can be calculated using the formula C1V1 = C2V2, where C1 is the initial concentration, V1 is the initial volume, C2 is the final concentration, and V2 is the final volume after dilution.

The initial volume of S (V1) is 1.00 mL and the final volume of the diluted solution (V2) is 10.0 mL. Therefore, using the initial concentration of S (C1) as 8.48 mM, we can solve for the final concentration (C2) as follows:

C1V1 = C2V2
(8.48 mM)(1.00 mL) = (C2)(10.0 mL)

Solving for C2 gives us:

C2 = (8.48 mM)(1.00 mL) / (10.0 mL)
C2 = 0.848 mM

The final concentration of S in the 10.0 mL solution is 0.848 mM (millimolar).

Answer:

0.112eV/atom

Explanation:

since

p=m/v

then

pv=pv

7.81*0.97=67.81*V

V=7.58/67.81

V= 0.112eV/atom

A 0.1375-g sample of solid magnesium is burned in a constant-volume bomb calorimeter (heat capacity of 3024 J/°C), causing a temperature increase of 1.126°C. The heat given off by the burning Mg is -24.76 kJ/g and -601.9 kJ/mol.

When a sample of magnesium is burned in a constant-volume bomb calorimeter that has a heat capacity (C) of 3024 J/°C, the temperature increases by 1.126°C (ΔT). We can calculate the heat absorbed by the calorimeter (Qc) using the following expression.

[tex]Qc = C \times \Delta T = \frac{3024J}{\° C} \times 1.126 \° C \times \frac{1kJ}{1000J} = 3.405 kJ[/tex]

According to the law of conservation of energy, the sum of the heat absorbed by the calorimeter and the heat released by the reaction (Qr) is zero.

[tex]Qc + Qr = 0\\\\Qr = -Qc = -3.405 kJ[/tex]

3.405 kJ are released by the combustion of 0.1375 g of Mg. The heat released per gram of Mg is:

[tex]\frac{-3.405kJ}{0.1375g} = -24.76 kJ/g[/tex]

Finally, we will convert -24.67 kJ/g to kJ/mol using the molar mass of Mg (24.31 g/mol).

[tex]\frac{-24.76kJ}{g} \times \frac{24.31g}{mol} = -601.9 kJ/mol[/tex]

A 0.1375-g sample of solid magnesium is burned in a constant-volume bomb calorimeter (heat capacity of 3024 J/°C), causing a temperature increase of 1.126°C. The heat given off by the burning Mg is -24.76 kJ/g and -601.9 kJ/mol.

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Answer: The atomic weight of the second isotope is 64.81 amu.

Explanation:

Average atomic mass of an element is defined as the sum of atomic masses of each isotope each multiplied by their natural fractional abundance

Formula used to calculate average atomic mass follows:

[tex]\text{Average atomic mass }=\sum_{i=1}^n\text{(Atomic mass of an isotopes)}_i\times \text{(Fractional abundance})_i[/tex]     .....(1)

We are given:

Let the mass of isotope 2 be 'x'

Mass of isotope 1 = 62.9 amu

Percentage abundance of isotope 1 = 69.1 %

Fractional abundance of isotope 1 = 0.691

Mass of isotope 2 = 'x'

Percentage abundance of isotope 2 = 30.9%

Fractional abundance of isotope 2 = 0.309

Average atomic mass of copper = 63.5 amu

Putting values in equation 1, we get:

[tex]\text{Average atomic mass of copper}=[(62.9\times 0.691)+(x\times 0.309)][/tex]

[tex]x=64.81amu[/tex]

Hence, the atomic weight of second isotope will be 64.81 amu.

By using the weighted average formula and the given details, we can determine the atomic weight of the second naturally occurring isotope of copper approximately to be 64.93 amu.

The atomic weight of an isotope is calculated by adding the products of the abundance percentages and the atomic weights of each isotope. For copper (Cu), one of its isotopes is Copper-63, which makes up 69.1% of naturally occurring copper, and it has an atomic weight of 62.9 amu. Therefore, we can calculate the atomic weight of the second isotope using the given average atomic weight of copper (63.5 amu) as follows:

Average atomic weight = (abundance of Copper-63 * atomic weight of Copper-63) + (abundance of Copper-65 * atomic weight of Copper-65)

63.5 = (0.691*62.9) + (0.309 * x)

After we calculate the first part, we subtract it from 63.5 to solve for the atomic weight (x) of the second isotope, known as Copper-65.

Therefore, the atomic weight of the second isotope of copper is approximately 64.93 amu.

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Final answer:

Adding more acid to tooth enamel causes increased solubility of enamel and may lead to cavities. The added acid reacts with hydroxide ions in the enamel, driving the reaction forward. Fluoride in dental products can help protect enamel by reducing solubility in acid.

Explanation:

When more acid, which in chemical terms is a source of H+ ions, is added to the solution where tooth enamel, chemically known as calcium hydroxyapatite Ca5(PO4)3(OH), is present, it results in the reaction shifting to the right according to Le Chatelier's principle. This process increases the solubility of the tooth enamel in acid, leading to enamel dissolution and potentially to the formation of dental cavities. The reaction with acid produces 5Ca2+(aq), 3HPO42-(aq), and OH-(aq). Hydroxide ions (OH-) react with added H+ ions to form water (2H2O), driving the reaction forward and increasing enamel solubility. To mitigate this effect, toothpastes and mouth rinses may contain fluoride compounds, replacing the strong base hydroxide in the enamel with the weaker base fluoride. This renders the enamel more resistant to acid attack by reducing the extent to which the equilibrium shifts upon acid addition.

Answer:

None of the above

Explanation:

The (−OH) group on phenol can form hydrogen bonds, and the −CH3 group on toluene cannot.

Phenol has only one hydrogen on the −OH group available to form hydrogen bonds, so the hydrogen bond is stronger. In toluene, the hydrogen bond is spread over all three hydrogens on the methyl group, so the interaction is weaker overall.

Phenol has a higher molecular mass than toluene.

Answer:

a. The (−OH) group on phenol can form hydrogen bonds, and the −CH3 group on toluene cannot.

Explanation:

Hello,

We firs must consider that the hydroxyl functional group is present in phenol as a highly polar section into its structure. Thus, phenol molecules are strongly associated by the presence of hydrogen bonds which toluene does not have due to its apolarity.

Consequently, since associating interactions are present in the phenol but absent in the toluene, more energy must be supplied to the phenol to melt it down, that is why phenol's melting point is higher than toluene's that one.

Best energy

Answer:

[tex]_{6}^{12}\text{C}[/tex]

Explanation:

A particle with two protons and two neutrons is a helium nucleus.

Your unbalanced nuclear equation is:

[tex]_{8}^{16}\text{O} \longrightarrow \, _{x}^{y}\text{Z} + \, _{2}^{4}\text{He}[/tex]

The main point to remember in balancing nuclear equations is that the sums of the superscripts and of the subscripts must be the same on each side of the equation.  

Then

8 = x + 2, so x =  8 - 2 =  6

16 = y + 4, so y = 16 - 4 =12

Element 6 is carbon, so the nuclear equation becomes

[tex]_{\ 8}^{16}\text{O} \longrightarrow \, _{\ 6}^{12}\text{C} + \, _{2}^{4}\text{He}[/tex]

Answer :

(a) The maximum efficiency of the engine is, 62.5 %

(b) The maximum work done is, 0.625 KJ.

(c) The heat discharge into the cold sink is, 0.375 KJ.

Explanation : Given,

Temperature of hot body [tex]T_h[/tex] = 800 K

Temperature of cold body [tex]T_c[/tex] = 300 K

(a) First we have to calculate the maximum efficiency of the engine.

Formula used for efficiency of the engine.

[tex]\eta =1-\frac{T_c}{T_h}[/tex]

Now put all the given values in this formula, we get :

[tex]\eta =1-\frac{300K}{800K}[/tex]

[tex]\eta =0.625\times 100=62.5\%[/tex]

(b) Now we have to calculate the maximum work done.

Formula used :

[tex]\eta =\frac{Q_h-Q_c}{Q_h}=\frac{w}{Q_h}[/tex]

where,

[tex]Q_h[/tex] = heat supplied by hot source = 1 KJ

[tex]Q_c[/tex] = heat supplied by hot source

w = work done = ?

Now put all the given values in this formula, we get :

[tex]\eta =\frac{w}{Q_h}[/tex]

[tex]0.625=\frac{w}{1KJ}[/tex]

[tex]w=0.625KJ[/tex]

(c) Now we have to calculate the heat discharge into the cold sink.

Formula used :

[tex]w=Q_h-Q_c[/tex]

[tex]Q_c=Q_h-w[/tex]

[tex]Q_c=1-0.625[/tex]

[tex]Q_c=0.375KJ[/tex]

Therefore, (a) The maximum efficiency of the engine is, 62.5 %

(b) The maximum work done is, 0.625 KJ.

(c) The heat discharge into the cold sink is, 0.375 KJ.

Answer:

The boiling point of a solution of 500.0 g of ethylene glycol dissolved in 500.0 g of water is 108.258°C.

Explanation:

Elevation in boiling point : [tex]\Delta T_b[/tex]

[tex]\Delta T_b=T_b-T[/tex]

[tex]\Delta T_b=K_b\times m[/tex]

[tex]T_b[/tex] = Boiling point of the solution

T = Boiling point of pure solvent

[tex]K_b[/tex]= Molal elevation constant of solvent

m = molality of the solution

Molality of the  ethylene glycol solution:

[tex]molality=\frac{\text{Moles of solute}}{\text{Mass of solvent in kg}}[/tex]

Moles of ethylene glycol = [tex]\frac{500.0 g}{62 g/mol}=8.0645 mol[/tex]

Mass of solvent that uis water = 500.0 g = 0.5000 kg

[tex]m=\frac{8.0645 mol}{0.5000 kg}=16.1290 m[/tex]

Molal elevation constant of water =[tex]K_b=0.512^oC/m[/tex]

[tex]\Delta T_b=0.512^oC/m\times 16.1290 m=8.258^oC[/tex]

Boiling point of the solution =[tex]T_b[/tex]

Boiling point of pure water = T = 100°C

[tex]T_b=T+\Delta T_b=100^oC+8.258^oC=108.258^oC[/tex]

The boiling point of a solution of 500.0 g of ethylene glycol dissolved in 500.0 g of water is 108.258°C.

Final answer:

To calculate the boiling point of the solution, use the equation ΔT = Kb * molality, where ΔT is the boiling point elevation, Kb is the boiling point elevation constant, and molality is the molal concentration of the solution. Calculate the molality by dividing the number of moles of ethylene glycol by the mass of water. Substitute the molality into the equation to calculate the boiling point elevation, and add this elevation to the boiling point of pure water (100°C) to find the boiling point of the solution.

Explanation:

To calculate the boiling point of the solution, we need to use the equation:

ΔT = Kb * molality

Where ΔT is the boiling point elevation, Kb is the boiling point elevation constant, and molality is the molal concentration of the solution.

First, we need to calculate the molality of the solution by dividing the number of moles of ethylene glycol by the mass of water. The number of moles of ethylene glycol can be found by dividing the mass of ethylene glycol by its molar mass, and the mass of water is given as 500.0 g.

Once we have the molality, we can substitute it into the equation to calculate the boiling point elevation. Finally, we add this elevation to the boiling point of pure water (100°C) to find the boiling point of the solution.

Answer:Option c is incorrect

Explanation:

Diels-Alder reaction is a 4+2 cycloaddition reaction .

The reaction occurs between a diene and a dieneophile .

Generally In the Diels-alder reaction HOMO of the diene and LUMO of the dienophile react with proper orbital symmetry. But vice-versa can also be used.

HOMO-Highest occupied molecular orbital

LUMO-Lowest unoccupied molecular orbital

The primary driving force for the diels alder reaction is is the conversion of 2pi bonds into 2 sigma bonds. The sigma bonds are energetically more favorable than pi bonds.

The diels alder reaction happens through orbital interaction and hence the substituents on either the diene or dienophile do not change there stereochemistry in the product so  it is a stereospecific reaction.Since predominantly only isomer would be produced. so a is correct.

The Diels alder reaction is a concerted( more  bonds form at a time) reaction which means it is just a one step reaction. so statement b is correct.

The option c is incorrect as diels alder reaction occurs through orbital interaction in a pericyclic manner. Since Diels alder reactions are pericyclic in nature and occur through orbital symmetry they do not involve polar intermediates like carbocation or radicals.

The dienes must be conjugated as on account of conjugation stability of a diene also increases. Also since we know that due to conjugation the energy of LUMO decreases and that of HOMO increases and so HOMO is more reactive and generally we involve HOMO of the diene and LUMO of the dienophile. So conjugated dienes are important.

So for a bond formation to take place in a  Diels-Alder reaction HOMO and LUMO with proper symmetry must overlap.

Answer:

The correct answer is: Dynamic equilibrium in a chemical reaction is the condition in which the rate of the forward reaction equals the rate of the reverse reaction.

Explanation:

Dynamic equilibrium is a chemical equilibrium between froward reaction and backward or reverse reaction where rate of reaction going forwards is equal to the rate of reaction going backward (reverse).  

Some other properties of dynamic equilibrium are:

Answer:

B: At dynamic equilibrium, the rate of the forward reaction is higher than the rate of the reverse reaction.

hey there!:

Volume in liters ( V ) = 111 mL / 1000 => 0.111 L

Pressure in atm ( P )  = 734 / 760 => 0.965789 atm

temperature in Kelvin ( K )  = 34+273.15 => 307.15 K

Molar gas constant ( R ) = 0.0826 atm*L/mol*K

ideal gas  equation :

p*V = n*R*T

moles of gas:

n =  p*v / R*T

n = 0.965789 * 0.111 / 0.0826 * 307.15

n = 0.107202 / 25.37059

n = 0.004225 moles

Therefore:

Molar mass =  mass / moles of gas

molar mass = 0.168 / 0.004225

molar mass = 39.76 g/mol

Hope this helps!

The molar mass of the gas was calculated by applying the ideal gas law, rearranging it for molar mass, and using the given quantities in the problem. Conversions to appropriate units were made, and the molar mass was found to be 31.1 g/mol.

The molar mass of a gas can be calculated by applying the ideal gas law, PV = nRT. By rearranging this to solve for the molar mass, using known quantities from the problem, and converting units appropriately, we find:

Applying these steps, we find that the molar mass of the gas is approximately 31.1 g/mol.

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An 894.0 g sample with a specific heat capacity of 2.35 × 10⁻⁴ kJ/g.° C, increases its temperature from -5.8 °C to 17.5 °C when absorbing 4.90 kJ of heat.

A chemist has a sample with a mass of 894.0 g. When it absorbs 4.90 kJ of heat its temperature increases from -5.8 °C to 17.5 °C. The chemist can calculate the specific heat capacity of the substance using the following expression.

[tex]Q = c \times m \times \Delta T[/tex]

where,

[tex]Q = c \times m \times \Delta T\\\\c = \frac{Q}{m \times \Delta T} = \frac{4.90 kJ}{894.0 g \times (17.5 \° C - (-5.8 \° C))} = 2.35 \times 10^{-4} kJ/g\° C[/tex]

An 894.0 g sample with a specific heat capacity of 2.35 × 10⁻⁴ kJ/g.° C, increases its temperature from -5.8 °C to 17.5 °C when absorbing 4.90 kJ of heat.

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The specific heat capacity of the substance is approximately 0.234 J/g°C. This was found by applying the formula for specific heat capacity (q = mcΔT) and doing the necessary calculations with the given values.

To determine the specific heat capacity of the substance, we can use the formula q = mcΔT, where q is the heat energy absorbed, m is the mass of the substance, c is the specific heat capacity, and ΔT is the change in temperature. Given that q equals 4.90 kJ (or 4900 J to match the unit of specific heat capacity), m equals 894.0g and ΔT is 17.5°C - (-5.8°C) = 23.3°C, we can rearrange the formula to solve for c: c = q / (mΔT).

Substituting the given values, we find c = 4900 J / (894.0g * 23.3°C), yielding a specific heat capacity of approximately 0.234 J/g°C to three significant figures.

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Answer:

75 mg

Explanation:

We can write the extraction formula as

x = m/[1 + (1/K)(Vaq/Vo)], where

x = mass extracted

m = total mass of solute

K = distribution coefficient

Vo = volume of organic layer

Vaq = volume of aqueous layer

Data:

m = 75 mg

K = 1.8

Vo = 0.90 mL

Vaq = 1.00 mL

Calculations:

For each extraction,

1 + (1/K)(Vaq/Vo) = 1  + (1/1.8)(1.00/0.90) = 1 + 0.62 = 1.62  

x = m/1.62 = 0.618m

So, 61.8 % of the solute is extracted in each step.

In other words, 38.2 % of the solute remains.

Let r = the amount remaining after n extractions. Then  

r = m(0.382)^n.

If n = 7,

r = 75(0.382)^7 = 75 × 0.001 18 = 0.088 mg

m = 75 - 0.088 = 75 mg

After seven extractions, 75 mg (99.999 %) of the solute will be extracted.

Hey there!

HC2H3O2(aq) + H2O(l) → H3O⁺(aq) + C2H3O2⁻(aq)

↓                             ↓              ↓                      ↓

acid                     base             acid            base

If we consider the only forward reaction H3O⁺is the conjugate acid of the base H2O .  For reversse reaction CH3COOH  is the conjugate acid of the base  CH3COO⁻.

Hope this helps!

In the given reaction, after water (H2O) accepts a proton (H+) from acetic acid (HC2H3O2), it forms H3O+ (hydronium ion), which is the conjugate acid.

In this reaction, the conjugate acid is the species that forms after a base has accepted a proton. So, here, the base is H2O and it accepts a proton, H+, from HC2H3O2 to become H3O+. Thus, in the reaction HC2H3O2(aq) + H2O(l) ⇌ H3O+ + C2H3O−2(aq), the conjugate acid that forms is H3O+ (hydronium ion).

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Answer:

Explanation:

Mixing Ammonia gas into a solution of Copper(II) Sulfate will give Ammonium Sulfate and a precipitate of Copper(II) Hydroxide (Cu(OH)₂). The Ksp of Cu(OH)₂ is published => 2.2 x 10⁻²². Such gives a solubility* of the Cu(OH)₂ to be ~1.77 x 10⁻⁷M =>  [Cu⁺²] ~1.77 x 10⁻⁷M and [OH⁻] = 2(1.77 x 10⁻⁷)M = 3.53 x 10⁻⁷M.  The reaction of Ammonium Hydroxide and Copper(II) Sulfate will generate 1 x 10⁻⁴ mole Cu(OH)₂ as a precipitate but only 1.77 x 10⁻⁷ mole of the hydroxide will remain in  1 Liter of solution b/c of extreme limited solubility.

*Solubility of 1:2 ionization ratio salts = CubeRt(Ksp/4).

Answer:

For a: The balanced chemical equation is given below.

For b: The mass of carbon dioxide produced will be [tex]1.07\times 10^3g[/tex]

Explanation:

Every balanced chemical equation follows law of conservation of mass.

This law states that mass can neither be created nor can be destroyed but it can only be transformed from one form to another form.

This law also states that the total number of individual atoms on the reactant side must be equal to the total number of individual atoms on the product side.

For the given reaction, the balance chemical equation follows:

[tex]C_3H_8(g)+5O_2(g)\rightarrow 3CO_2(g)+4H_2O(g)[/tex]

All the substances are present in gaseous state.

By Stoichiometry of the reaction:

1 mole of propane gas produces 3 moles of carbon dioxide gas.

So, 8.11 moles of propane gas will produce = [tex]\frac{3}{1}\times 8.11=24.33mol[/tex] of carbon dioxide gas.

Now, calculating the mass of carbon dioxide using equation:

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

Molar mass of carbon dioxide = 44 g/mol

Moles of carbon dioxide = 24.33 mol

Putting values in above equation, we get:

[tex]24.33mol=\frac{\text{Mass of carbon dioxide}}{44g/mol}\\\\\text{Mass of carbon dioxide}=1070.52g[/tex]

Hence, the amount of [tex]CO_2[/tex] produced in the given reaction and expressed in scientific notation is [tex]1.07\times 10^3g[/tex]

Answer: 161.8 torr

Explanation:

According to Raoult's law, the vapor pressure of a component at a given temperature is equal to the mole fraction of that component multiplied by the vapor pressure of that component in the pure state.

[tex]p_1=x_1p_1^0[/tex] and [tex]p_2=x_2P_2^0[/tex]

where, x = mole fraction

[tex]p^0[/tex] = pressure in the pure state

According to Dalton's law, the total pressure is the sum of individual pressures.

[tex]p_{total}=p_1+p_2[/tex][tex]p_{total}=x_Ap_A^0+x_BP_B^0[/tex]

[tex]x_{A}=\frac{\text {moles of A}}{\text {moles of A+moles of B}}=\frac{5.50}{5.50+8.50}=0.39[/tex],

[tex]x_{B}=\frac{\text {moles of B}}{\text {moles of A+moles of B}}=\frac{8.50}{5.50+8.50}=0.61[/tex],

[tex]p_{A}^0=264torr[/tex]

[tex]p_{B}^0=96.5torr[/tex]

[tex]p_{total}=0.39\times 264+0.61\times 96.5=161.8torr[/tex]

The total vapor pressure above the solution is 161.8 torr.

Answer: The mass of calcium hydroxide that are present in the solution is 0.3256 grams.

Explanation:

To calculate the moles of a solute, we use the equation:

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

We are given:

Volume of hydrochloric acid = 42.7mL = 0.0427 L   (Conversion factor: 1 L = 1000 mL)

Molarity of the solution = 0.208 moles/ L

Putting values in above equation, we get:

[tex]0.208mol/L=\frac{\text{Moles of hydrochloric acid}}{0.0427L}\\\\\text{Moles of hydrochloric acid}=0.0088mol[/tex]

For the given chemical reaction:

[tex]Ca(OH)_2(aq.)+2HCl\rightarrow CaCl_2(aq.)+2H_2O(l)[/tex]

By Stoichiometry of the reaction:

2 moles of hydrochloric acid reacts with 1 mole of calcium hydroxide.

So, 0.0088 moles of hydrochloric acid will react with = [tex]\frac{1}{2}\times 0.0088=0.0044mol[/tex] of calcium hydroxide.

To calculate the mass of calcium hydroxide, we use the equation:

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

Moles of calcium hydroxide = 0.0044 moles

Molar mass of calcium hydroxide = 74 g/mol

Putting values in above equation, we get:

[tex]0.0044mol=\frac{\text{Mass of calcium hydroxide}}{74g/mol}\\\\\text{Mass of calcium hydroxide}=0.3256g[/tex]

Hence, the mass of calcium hydroxide that are present in the solution is 0.3256 grams.

0.325 grams of Ca(OH)₂ must be in the solution of HCl to neutralize a solution.

Molarity of any solution is defined as:

M = n/V, where

n = no. of moles

V = volume

Given chemical reaction is:

Ca(OH)₂(aq) + 2HCl → CaCl₂(aq) + 2H₂O(l)

From the stoichiometry of the reaction, it is clear that:
2 moles of HCl = react with 1 mole of Ca(OH)₂

1 mole of HCl = react with 1/2 mole of Ca(OH)₂

Moles of HCl will be calculated by using the molarity formula and given data as:

Given concentration of HCl = 0.208M

Given volume of HCl = 42.7mL = 0.0427L

Moles of HCl = 0.208 × 0.0427 = 0.0088 moles

0.0088 moles of HCl = react with 0.0088 × 1/2 = 0.0044moles of Ca(OH)₂

Mass of Ca(OH)₂ will be calculated by using the formula:

n = W/M, where

W = required mass

M = molar mass = 72g/mole

W = 0.0044mole × 72g/mole = 0.325 grams

Hence, 0.325 grams of Ca(OH)₂ will be in the solution.

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Answer : The entropy change of the system is, 19.5 J/K

Solution :

First we have to calculate the moles of benzene.

[tex]\text{Moles of }C_6H_6=\frac{\text{Mass of }C_6H_6}{\text{Molar mass of }C_6H_6}=\frac{17.5g}{78.11g/mole}=0.224moles[/tex]

Now we have to calculate the entropy change of the system.

Formula used :

[tex]\Delta S=\frac{n\times \Delta H_{vap}}{T_b}[/tex]

where,

[tex]\Delta S[/tex] = entropy change of the system = ?

[tex]\Delta H[/tex] = enthalpy of vaporization = 30.7 kJ/mole

n = number of moles of benzene  = 0.224 mole

[tex]T_b[/tex] = normal boiling point of benzene = [tex]80.1^oC=273+80.1=353.1K[/tex]

Now put all the given values in the above formula, we get the entropy change of the system.

[tex]\Delta S=\frac{0.224mole\times (30.7KJ/mole)}{353.1K}=0.0195kJ/K=0.0195\times 1000=19.5J/K[/tex]

Therefore, the entropy change of the system is, 19.5 J/K

Answer:

False

Explanation: