Which of the following species has
(a) equal numbers of neutrons and electrons;
(b) protons, neutrons, and electrons in the ratio 9:11:8;
(c) a number of neutrons equal to the number of protons plus one-half the number of electrons?
24Mg2+, 47Cr, 60Co3+, 35Cl-, 124Sn2+, 2266Th, 90Sr Petrucci, Ralph H.. General Chemistry (p. 63). Pearson Education. Kindle Edition.

Answer:

[tex]\boxed{\text{0.780 atm}}[/tex]

Explanation:

Hermione is pretty smart. She realizes that, according to Dalton's Law of Partial Pressures, each gas exerts its pressure independently of the others, as if the others weren't even there.

She shows Ron how to use the Ideal Gas Law to solve the problem.

pV = nRT

She collects the data:

V = 1.00 L; n = 0.0319 mol; T = 25.0 °C

She reminds him to convert the temperature to kelvins

T = (25.0 +273.15) K = 298.15 K

Then she shows him how to do the calculation.

[tex]p \times \text{1.00 L} = \text{0.0319 mol} \times \text{L}\cdot\text{atm}\cdot\text{0.082 06 K}^{-1}\text{mol}^{-1} \times \text{298.15 K}\\\\1.00p = \text{0.7805 atm}\\\\p = \textbf{0.780 atm}\\\\\text{The partial pressure of the nitrogen is } \boxed{\textbf{0.780 atm}}[/tex]

Isn't she smart?

The partial pressure of N2 is 0.78 atm.

The following are information contained in the question;

Volume (V) =  1.00 L

Total number of moles of the gases(n) = Number of moles of N2 + Number of moles of O2 + Nuber of moles of Ar = 0.0319 mol + 0.00856 mol + 0.000381 mol = 0.041 moles

Temperature(T) = 25.0◦C + 273 = 298 K

Using PV = nRT

Where;

P = pressure of the gas (the unknown)

V = volume of the sample = 1.00 L

T = absolute temperature = 298K

R = molar gas constant = 0.082 atmLK-1Mol-1

n = total number of moles present = 0.041 moles

Making P the subject of the formula and substituting values;

P = nRT/V

P =  0.041 moles × 0.082 atmLK-1Mol-1  × 298 K/1.00 L

P = 1 atm

Recall that partial pressure = mole fraction × total pressure

Mole fraction of N2 = 0.00856 mol /0.00856 mol  + 0.0319 mol + 0.000381 mol =

Partial pressure of N2 =0.0319 mol /0.041 moles ×  1 atm

Partial pressure of N2 = 0.78 atm

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Explanation:

Moles of nitrogen gas = [tex]n_1=\frac{1.20 g}{28 g/mol}=0.0428 mol[/tex]

Moles of oxygen gas = [tex]n_2=\frac{0.77 g}{32 g/mol}=0.0240 mol[/tex]

Mole fraction of nitrogen gas=[tex]\chi_1=\frac{n_1}{n_1+n_2}[/tex]

[tex]\chi_1=\frac{0.0428 mol}{0.0428 mol+0.0240 mol}=0.6407\approx 0.64[/tex]

Mole fraction of oxygen gas=[tex]\chi_2=1-\chi_1=1-0.6407=0.3593\approx 0.36[/tex]

Total  umber of moles in container :

n =[tex]n_1+n_2[/tex]= 0.0428 mol + 0.0240 mol = 0.0668 mol

Volume of the container = V = 1.65 L

Temperature of the container = T = 15°C = 288.15 K

Total pressure in the container = P

Using an ideal gas equation:

[tex]PV=nRT[/tex]

[tex]P=\frac{0.0668 mol\times 0.0821 atm L/mol k\times 288.15 K}{1.65 L}[/tex]

P = 0.9577 atm

Partial pressure of nitrogen gas = [tex]p^{o}_1[/tex]

Partial pressure of nitrogen gas = [tex]P^{o}_2[/tex]

Partial pressure of nitrogen gas and oxygen gas can be calculated by using Dalton's law of partial pressure:

[tex]p^{o}_i=p_{total}\times \chi_i[/tex]

[tex]p^{o}_1=P\times \chi_1=0.6135 atm\approx 0.61 atm[/tex]

[tex]p^{o}_2=P\times \chi_2=0.3441 atm\approx 0.34 atm[/tex]

Answer: The correct answer is Option B.

Explanation:

To calculate the final pressure of the system, we use the equation given by Gay-Lussac Law. This law states that pressure of the gas is directly proportional to the temperature of the gas at constant volume.

Mathematically,

[tex]\frac{P_1}{T_1}=\frac{P_2}{T_2}[/tex]        (at constant volume)

where,

[tex]P_1\text{ and }T_1[/tex] are the initial pressure and temperature of the gas.

[tex]P_2\text{ and }T_2[/tex] are the final pressure and temperature of the gas.

We are given:

Conversion factor:  [tex]T(K)=T(^oC)+273[/tex]

[tex]P_1=1.85atm\\T_1=25^oC=(25+273)K=298K\\P_2=?atm\\T_2=7.5^oC=(7.5+273)K=280.5[/tex]

Putting values in above equation, we get:

[tex]\frac{1.85atm}{298K}=\frac{P_2}{280.5K}\\\\P_2=1.74atm[/tex]

Hence, the correct answer is Option B.

Final answer:

Using Gay-Lussac's Law, after converting the temperatures to Kelvin and applying the given initial pressure and temperatures, the new pressure of the sports ball when the temperature drops to 7.5 °C is calculated to be B) 1.74 atm.

Explanation:

The problem you've presented involves the concept of gas laws, specifically Gay-Lussac's Law, which states that the pressure of a gas varies directly with its absolute temperature, provided the volume does not change. This law can be mathematically represented as P1/T1 = P2/T2, where P1 and P2 are the initial and final pressures, and T1 and T2 are the initial and final temperatures in Kelvin.

To solve for the new pressure (P2), we first convert the temperatures from °C to Kelvin: T1 = 25 °C + 273.15 = 298.15 K, and T2 = 7.5 °C + 273.15 = 280.65 K. Then we rearrange the formula to solve for P2: P2 = P1 * (T2/T1). Substituting the given values, P2 = 1.85 atm * (280.65 K / 298.15 K) = 1.74 atm.

Answer : The number of moles of [tex]H_2O[/tex] produced are, 0.66 mole.

Explanation : Given,

Given moles of [tex]NH_3[/tex] = 0.44 mole

The given balanced chemical reaction is,

[tex]4NH_3(g)+5O_2(g)\rightarrow 4NO(g)+6H_2O(g)[/tex]

From the given balanced chemical reaction, we conclude that

As, 4 moles of [tex]NH_3[/tex] react to give 6 moles of [tex]H_2O[/tex]

So, 0.44 moles of [tex]NH_3[/tex] react to give [tex]\frac{6}{4}\times 0.44=0.66[/tex] moles of [tex]H_2O[/tex]

Therefore, the number of moles of [tex]H_2O[/tex] produced are, 0.66 mole.

Temperature is defined as  a measure of the average kinetic energy of the individual atoms or molecules composing a substance.

Answer: [tex][Al^{3+}][/tex] = 1.834 M

[tex][F^-][/tex] =  0.004 M

[tex][AlF_6^{3-}][/tex] = 0.166 M

Explanation:

[tex]Al^{3+}+6F^-\rightleftharpoons AlF_6^{3-}[/tex]

Initial concentration of [tex]Al^{3+}[/tex] = 0.15 M

Initial concentration of [tex]F^-[/tex] = 2.0 M

The given balanced equilibrium reaction is,

                           [tex]Al^{3+}+6F^-\rightleftharpoons AlF_6^{3-}[/tex]

Initial conc.           2 M           0.15 M                         0

At eqm. conc.    (2-x) M     (1-6x) M                     (x) M

The expression for equilibrium constant for this reaction will be,

[tex]K_f=\frac{[AlF_6^{3-}]}{[Al^{3+}][F^-]^6}[/tex]

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

[tex]4.0\times 10^{19}=\frac{(x)}{(2-x)\times (1-6x)^6}[/tex]

By solving the term 'x', we get :

[tex]x=0.166[/tex]

[tex][Al^{3+}][/tex] = (2-x) = 2-0.166 = 1.834 M

[tex][F^-][/tex] = (1-6x) = 1-6(0.1660)=  0.004 M

[tex][AlF_6^{3-}][/tex] = x = 0.166 M

Answer:

Cohesion

Explanation:

Think of it like this. The water molecules STICK TOGETHER, so they COoperate.

COhesion     COoperate

Cohesion is the tendency of water molecules to stick together, due to hydrogen bonding. It is a unique property of water that plays a vital role in living organisms and the environment.

The tendency of water molecules to stick together is referred to as cohesion. This process occurs due to hydrogen bonding between the water molecules, where the slightly positive hydrogen of one water molecule is attracted to the slightly negative oxygen of a neighboring water molecule. Thus, creating a force that holds these molecules together. It is one of the unique properties of water that contributes to its important role in living organisms and the environment. Some other terms related to water are adhesion, which is the tendency of water to stick to other substances; polarity, which is the property of having oppositely charged ends; transpiration, which is the process by which water evaporates from the leaves of plants; and evaporation, which is the change of state from liquid to gas.

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Answer:

In osmosis, the water has a net movement to the side with lower water concentration.

Explanation:

It moves in the direction of a solution with higher solute ( therefore  lower water) concentration.

Answer:

Exhibit a net movement to the side with lower water concentration.

Explanation:

Hello,

Osmosis is a process by which the equilibrium between the concentration of a solute placed at two sides separated by a permeable membrane is reached by moving the solvent's molecules.

For the considered example, it is seen that the water will exhibit a net movement to the side with lower water concentration as long as the place with more water will have a higher solute's concentration which implies that the water move from such side to other one in order to equal both the solutions concentrations.

Best regards.

Answer: The correct answer is Option D.

Explanation:

To calculate the pressure of the Helium gas, we use the equation:

[tex]p_i=\chi \times P[/tex]

where,

[tex]p_i[/tex] = partial pressure of the gas

[tex]\chi[/tex] = mole fraction of the gas

P = total pressure

We are given:

Sum of all the mole fraction is always equal to 1.

[tex]\chi_{Ne}=0.47\\\chi_{Ar}=0.23\\\chi_{He}=(1-(0.47+0.23))=0.3\\P=7.85atm[/tex]

Putting values in above equation, we get:

[tex]p_i=0.3\times 7.85=2.4atm[/tex]

Hence, the correct answer is Option D.

To find the pressure of He in the mixture, calculate the mole fraction of He by subtracting the mole fractions of Ne and Ar from 1. Then, use Dalton's law of partial pressures to find the pressure of He by multiplying the total pressure of the mixture by the mole fraction of He.

To find the pressure of He in the mixture, we need to first calculate the mole fraction of He. Since the mole fractions of Ne and Ar are given, we can calculate the mole fraction of He by subtracting their mole fractions from 1.

Therefore, the mole fraction of He is

1 - 0.47 - 0.23 = 0.3.

Next, we can use Dalton's law of partial pressures to find the pressure of He. According to Dalton's law, the total pressure of a mixture of gases is equal to the sum of the partial pressures of each gas. Since we know the total pressure of the mixture is 7.85 atm, we can set up the equation:

Pressure of He = Total pressure of mixture × Mole fraction of He = 7.85 atm × 0.3 = 2.355 atm.

Therefore, the pressure of He is approximately 2.4 atm (option D).

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Answer: The [tex]\Delta G[/tex] for the reaction is 54.425 kJ/mol

Explanation:

For the given balanced chemical equation:

[tex]CO_2(g)+CCl_4(g)\rightleftharpoons 2COCl_2(g)[/tex]

We are given:

[tex]\Delta G^o_f_{CO_2}=-394.4kJ/mol\\\Delta G^o_f_{CCl_4}=-62.3kJ/mol\\\Delta G^o_f_{COCl_2}=-204.9kJ/mol[/tex]

To calculate [tex]\Delta G^o_{rxn}[/tex] for the reaction, we use the equation:

[tex]\Delta G^o_{rxn}=\sum [n\times \Delta G_f(product)]-\sum [n\times \Delta G_f(reactant)][/tex]

For the given equation:

[tex]\Delta G^o_{rxn}=[(2\times \Delta G^o_f_{(COCl_2)})]-[(1\times \Delta G^o_f_{(CO_2)})+(1\times \Delta G^o_f_{(CCl_4)})][/tex]

Putting values in above equation, we get:

[tex]\Delta G^o_{rxn}=[(2\times (-204.9))-((1\times (-394.4))+(1\times (-62.3)))]\\\Delta G^o_{rxn}=46.9kJ=46900J[/tex]

Conversion factor used = 1 kJ = 1000 J

The expression of [tex]K_p[/tex] for the given reaction:

[tex]K_p=\frac{(p_{COCl_2})^2}{p_{CO_2}\times p_{CCl_4}}[/tex]

We are given:

[tex]p_{COCl_2}=0.735atm\\p_{CO_2}=0.140atm\\p_{CCl_4}=0.185atm[/tex]

Putting values in above equation, we get:

[tex]K_p=\frac{(0.735)^2}{0.410\times 0.185}\\\\K_p=20.85[/tex]

To calculate the gibbs free energy of the reaction, we use the equation:

[tex]\Delta G=\Delta G^o+RT\ln K_p[/tex]

where,

[tex]\Delta G[/tex] = Gibbs' free energy of the reaction = ?

[tex]\Delta G^o[/tex] = Standard gibbs' free energy change of the reaction = 46900 J

R = Gas constant = [tex]8.314J/K mol[/tex]

T = Temperature = [tex]25^oC=[25+273]K=298K[/tex]

[tex]K_p[/tex] = equilibrium constant in terms of partial pressure = 20.85

Putting values in above equation, we get:

[tex]\Delta G=46900J+(8.314J/K.mol\times 298K\times \ln(20.85))\\\\\Delta G=54425.26J/mol=54.425kJ/mol[/tex]

Hence, the [tex]\Delta G[/tex] for the reaction is 54.425 kJ/mol

The change in free energy for the reaction is 54.4  kJ/mol.

The change in free energy under nonstandard conditions can be obtained from the chage in free energy under standard conditions using the formula;

ΔG = ΔG° + RTlnK

Now ΔG° is obtained from;

ΔG°reaction = 2[−204.9kJ/mol] - [(−394.4kJ/mol) + (−62.3kJ/mol)]

ΔG°reaction =(-409.8) + 456.7

ΔG°reaction = 46.9 kJ/mol

Q =PCOCl2^2/ PCO2 * PCCl4

Q = (0.735)^2/ 0.140 * 0.185

Q = 20.8

ΔG = 46.9 * 10^3 + [8.314 * 298 * ln(20.8)]

ΔG = 54.4  kJ/mol

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Answer:

Kc = 9.52.

Explanation:

A + 2B ⇌ C,

Kc = [C]/[A][B]²,

Concentration:     [A]                [B]              [C]

At start:               0.3 M         1.05 M        0.55 M

At equilibrium:   0.3 - x        1.05 - 2x     0.55 + x

                            0.14 M        1.05 - 2x      0.71 M

∵ 0.3 M - x = 0.14 M.

∴ x = 0.3 M - 0.14 M = 0.16 M.

∴ [B] at equilibrium = 1.05 - 2x = 1.05 M -2(0.16) = 0.73 M.

∵ Kc = [C]/[A][B]²

∴ Kc = (0.71)/(0.14)(0.73)² = 9.5166 ≅ 9.52.

Answer:

-667Kj see attached

Explanation:

Final answer:

To find the lattice energy for CsCl, we sum the given energies related to sublimation, bond dissociation, ionization, and electron affinity, then subtract the overall energy of formation. The magnitude of lattice energy for CsCl is calculated to be 624 kJ/mol.

Explanation:

To calculate the lattice energy for CsCl, we can use the provided enthalpy values in a Born-Haber cycle. We have:

Heat of sublimation for Cs: +76 kJ/mol

Bond dissociation energy for 1/2Cl₂: +121 kJ/mol

Ionization energy (Ei1) for Cs: +376 kJ/mol

Electron affinity (Eea) for Cl:
349 kJ/mol

Overall energy for the formation of CsCl:
443 kJ/mol

The lattice energy is the remaining term that balances the Born-Haber cycle equation, which summarizes the energy changes that occur when an ionic solid forms. Thus, we calculate the lattice energy (U) using the equation:

U = Sublimation energy + Bond dissociation energy  + Ionization energy + Electron affinity + Formation energy

U = 76 kJ/mol + 121 kJ/mol + 376 kJ/mol - 349 kJ/mol - 443 kJ/mol

U = 624 kJ/mol, which is the magnitude of the lattice energy for CsCl.

Try this suggested solution (the figures are not provided).

The answer is marked with red colour.

Answer: The specific heat of substance A is 1.1 J/g°C

Explanation:

When substance A is mixed with substance B, the amount of heat released by substance B (initially present at high temperature) will be equal to the amount of heat absorbed by substance A (initially present at low temperature)

[tex]Heat_{\text{absorbed}}=Heat_{\text{released}}[/tex]

The equation used to calculate heat released or absorbed follows:

[tex]Q=m\times c\times \Delta T=m\times c\times (T_{final}-T_{initial})[/tex]

[tex]m_1\times c_1\times (T_{final}-T_1)=-[m_2\times c_2\times (T_{final}-T_2)][/tex]       ......(1)

where,

q = heat absorbed or released

[tex]m_1[/tex] = mass of substance A = 6.07 g

[tex]m_2[/tex] = mass of substance B = 26.1 g

tex]T_{final}[/tex] = final temperature = 47.0°C

[tex]T_1[/tex] = initial temperature of substance A = 20.7°C

[tex]T_2[/tex] = initial temperature of substance B = 52.8°C

[tex]c_1[/tex] = specific heat of substance A = ?

[tex]c_2[/tex] = specific heat of substance B = 1.17 J/g°C

Putting values in equation 1, we get:

[tex]6.07\times c_1\times (47-20.7)=-[26.1\times 1.17\times (47-52.8)][/tex]

[tex]c_1=1.1J/g^oC[/tex]

Hence, the specific heat of substance A is 1.1 J/g°C

Answer:

A compressed spring

Explanation:

A compressed spring has potential energy only and no kinetic energy.

This is because kinetic energy is only possessed by particles in motion.

Energy in a compressed spring= -1/2kx² where x is the displacement.

In this equation there is no velocity so there is no kinetic energy.

Answer:

A compressed spring

Explanation:

Option C is correct. The potential energy is the energy stored in a compressed spring. This potential energy depends on the spring constant and the distance traveled by the spring as it is stretched. The work that is done in stretching a spring gets stored in the compressed spring as potential energy.

Option A is incorrect. As sound wave is a mechanical wave that carries both potential and kinetic energy.  

Option B is incorrect. Arrow shot from a bow has kinetic energy.  

Option D is incorrect. A vibrating atom has vibrational energy.  

Answer:

[tex]\boxed{1.19 \times 10^{-4} \text{ s}^{-1}}[/tex]

Explanation:

1. Determine the order of reaction

The question gives us a hint: the units of k are s⁻¹. This suggests a first order rate law.

To confirm, we plot ln(p) vs t.  We should get a straight line with slope = -k.

Here are your data with the pressures converted to natural logarithms.

[tex]\begin{array}{rcc}\textbf{t/s} & \textbf{p/mmHg} &\textbf{ln(p)}\\0 & 400 & 5.99\\2000 & 316 & 5.76\\4000 & 248 & 5.51\\6000 & 196 & 5.28\\8000 & 155 & 5.04\\10000 & 122 & 4.80\\\end{array}[/tex]

We get the graph shown below.

2. Determine the rate constant

The points fit so well that we can just use the end points to determine the slope.

[tex]\text{slope} = \dfrac{y_{2} - y_{1}}{ x_{2} - x_{1} } = \dfrac{4.80 - 5.99}{10 000 - 0} = -1.19 \times 10^{-4} \text{ s}^{-1}}\\\\k = \boxed{1.19 \times 10^{-4} \text{ s}^{-1}}[/tex]

The value of the rate constant for the reaction based on the given pressures  =  [tex]1.19 * 10^{-4} s^{-1}[/tex]

First step : determine the order of reaction

The reaction is a first-order reaction because the S.I. unit of K = s⁻¹  in the question

next step : Plot the value of  In( p ) vs Time

Where:  P = pressure ( mmHg )

            In ( p ) =  natural Logarithm of P values

Graph is attached below

Final step : calculate the value of the slope of the graph

slope = Δ y / Δ x

         = ( 4.8 - 5.99 ) / ( 10000 - 0 )

         = -1.19 / 10000  

∴ The value of  K ( rate constant )  = 1.19  *  10^{-4} s^{-1}

Hence we can conclude that the The value of the rate constant for the reaction based on the given pressures  =  [tex]1.19 * 10^{-4} s^{-1}[/tex]

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Answer: The amount of heat released is 56 MJ.

Explanation:

To calculate the number of moles, we use the equation:

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

Given mass of [tex]C_2H_6[/tex] = 12 kg = 12000 g    (Conversion factor: 1 kg = 1000 g)

Molar mass of [tex]C_2H_6[/tex] = 30 g/mol

Putting values in above equation, we get:

[tex]\text{Moles of }C_2H_6=\frac{12000g}{30g/mol}=400mol[/tex]

The chemical reaction for hydrogenation of ethene follows the equation:

[tex]C_2H_4+H_2\rightarrow C_2H_6[/tex]

By Stoichiometry of the reaction:

When 1 mole of ethane releases 140 kJ of heat.

So, 400 moles of ethane will release = [tex]\frac{140}{1}\times 400=56000kJ[/tex] of heat.

Converting this into Mega joules, using the conversion factor:

1 MJ = 1000 kJ

So, [tex]\Rightarrow 56000kJ\times (\frac{1MJ}{1000kJ})=56MJ[/tex]

Hence, the amount of heat released is 56 MJ.

Answer : The mass of copper produced will be, 11.796 grams

Explanation : Given,

Mass of [tex]Al[/tex] = 5 g

Molar mass of [tex]Al[/tex] = 26.98 g/mole

Molar mass of [tex]Cu[/tex] = 63.66 g/mole

First we have to calculate the moles of [tex]Al[/tex].

[tex]\text{Moles of }Al=\frac{\text{Mass of }Al}{\text{Molar mass of }Al}=\frac{5g}{26.98g/mole}=0.185moles[/tex]

Now we have to calculate the moles of [tex]Cu[/tex].

The balanced chemical reaction is,

[tex]2Al+3CuSO_4\rightarrow Al_2(SO_4)_3+3Cu[/tex]

From the balanced reaction we conclude that

As, 2 moles of [tex]Al[/tex] react to give 3 moles of [tex]Cu[/tex]

So, 0.185 moles of [tex]Al[/tex] react to give [tex]\frac{3}{2}\times 0.185=0.2775[/tex] moles of [tex]Cu[/tex]

Now we have to calculate the mass of [tex]Cu[/tex].

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

[tex]\text{Mass of }Cu=(0.2775mole)\times (63.66g/mole)=17.66g[/tex]

The theoretical yield of Cu = 17.66 grams

Now we have to calculate the actual yield of Cu.

[tex]\%\text{ yield of }Cu=\frac{\text{Actual yield of }Cu}{\text{Theoretical yield of }Cu}\times 100[/tex]

Now put all the given values in this formula, we get the actual yield of Cu.

[tex]63.4=\frac{\text{Actual yield of }Cu}{17.66}\times 100[/tex]

[tex]\text{Actual yield of }Cu=11.796g[/tex]

Therefore, the mass of copper produced will be, 11.796 grams

Answer: The correct answer is Option B.

Explanation:

Precipitate is defined as insoluble solid substance that emerges when two different aqueous solutions are mixed together. It usually settles down at the bottom of the solution after sometime.

For the given chemical equation:

[tex]CaCl_2(aq.)+K_2CO_3(aq.)\rightarrow CaCO_3(s)+2KCl(aq.)[/tex]

The products formed in the reaction are calcium carbonate and potassium chloride. Out of the two products, one of them is insoluble which is calcium carbonate. Thus, it is considered as a precipitate.

Hence, the correct answer is Option B.

In the double displacement reaction between CaCl₂ and K₂CO₃, CaCO₃ is the precipitate (B).

Let's consider the following double displacement reaction.

CaCl₂(aq) + K₂CO₃(aq) ⟶ CaCO₃(s) + 2 KCl(aq)

Regarding solubility rules, we know that:

With this information, we can conclude that CaCO₃ is a precipitate.

In the double displacement reaction between CaCl₂ and K₂CO₃, CaCO₃ is the precipitate (B).

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Answer:

Case I => %C-14 remaining = 77% => Age of artifact = 2200 yrs

Case II => %C-14 remaining = 6.2% => Age of artifact = 23,000 yrs

Explanation:

Given:

Half-Life C-14 = 5730 yrs

=> Rate Constant = k = 0.693/t(1/2) = (0.693/5730)yrs⁻¹ = 1.2 x 10⁻⁴ yrs⁻¹

NOTE => All radioactive decay is 1st order kinetics.

=> A = A₀eˉᵏᵗ  (classic 1st order decay equation)

- A = remaining activity

-A₀ = initial activity

- k = rate constant

- t = time of decay (or, age of object of interest; i.e., not everything is organic but the 1st order decay equation is good for non-organic objects (rocks) also. Analysts just use a different decay standard => K-40 → Ar-40 + β).

Solving the decay equation for time (t) ...

t = ln(A/A₀)/-k

Applying to problem cases...

Case I => %C-14 remaining = 77%

t = ln(A/A₀)/-k = ln(77/100)/-1.2x10⁻⁴ years = 2178 yrs ~ 2200 yrs

Case II => %C-14 remaining = 6.2%

t = ln(A/A₀)/-k = ln(6.2/100)/-1.2x10⁻⁴ years = 23,172 yrs ~ 23,000 yrs

Answer:

[tex]\boxed{\text{a) 2160 yr ago; b) 23 000 yr ago}}[/tex]

Explanation:

Two important equations in radioactive decay are

[tex](1) \qquad \ln \dfrac{N_{0} }{N_{t}} = kt\\\\(2) \qquad t_{\frac{1}{2}} = \dfrac{\ln2}{k }[/tex]

We use them for carbon dating.

a) The dye

Data:

[tex]t_{\frac{1}{2}} = \text{5730 yr}\\\\N_{t} = 0.77 N_{0}[/tex]

Calculations:

[tex]\text{From Equation (2)}\\\\t_{\frac{1}{2}} = \dfrac{\ln2}{\text{5730 yr}} = 1.21 \times 10^{-4} \text{ yr}^{-1}\\\\\text{From Equation (1)}\\\\\ln \dfrac{N_{0} }{0.77N_{0}} = 1.21 \times 10^{-4}t \text{ yr}^{-1}\\\\\ln\dfrac{1}{0.77} = 1.21 \times 10^{-4}t \text{ yr}^{-1}\\\\-\ln0.77 = 0.261 = 1.21 \times 10^{-4}t \text{ yr}^{-1}\\\\t = \dfrac{0.261}{ 1.21 \times 10^{-4} \text{ yr}^{-1}} = \textbf{2160 yr}\\\\\text{The cloth was painted } \boxed{\textbf{2160 yr}}\text{ ago}[/tex]

b) The wood

Data:

[tex]N_{t} = 0.062 N_{0}[/tex]

Calculations:

[tex]\text{From Equation (1)}\\\\\ln \dfrac{N_{0} }{0.062N_{0}} = 1.21 \times 10^{-4}t \text{ yr}^{-1}\\\\\ln\dfrac{1}{0.0.062} = 1.21 \times 10^{-4}t \text{ yr}^{-1}\\\\-\ln0.062 = 2.78 = 1.21 \times 10^{-4}t \text{ yr}^{-1}\\\\t = \dfrac{2.78}{ 1.21 \times 10^{-4} \text{ yr}^{-1}} = \textbf{23 000 yr}\\\\\text{The wood was cut} \boxed{\textbf{23 000 yr}}\text{ ago}[/tex]

Answer: The molarity of calcium hydroxide in the solution is 0.1 M

Explanation:

To calculate the concentration of base, we use the equation given by neutralization reaction:

[tex]n_1M_1V_1=n_2M_2V_2[/tex]

where,

[tex]n_1,M_1\text{ and }V_1[/tex] are the n-factor, molarity and volume of acid which is [tex]HBr[/tex]

[tex]n_2,M_2\text{ and }V_2[/tex] are the n-factor, molarity and volume of base which is [tex]Ca(OH)_2[/tex]

We are given:

[tex]n_1=1\\M_1=0.120M\\V_1=27.5mL\\n_2=2\\M_2=?M\\V_2=16.5mL[/tex]

Putting values in above equation, we get:

[tex]1\times 0.120\times 27.5=2\times M_2\times 16.5\\\\M_2=0.1M[/tex]

Hence, the molarity of [tex]Ca(OH)_2[/tex] in the solution is 0.1 M.

Answer: The correct answer is Option B.

Explanation:

To calculate the number of moles, we use the equation:

[tex]\text{Number of moles}=\frac{\text{Given mass}}{\text{Molar mass}}[/tex]   ....(1)

Given mass of nitrogen gas = 10 g

Molar mass of nitrogen gas = 28 g/mol

Putting values in above equation, we get:

[tex]\text{Moles of iron oxide}=\frac{10g}{28g/mol}=0.357mol[/tex]

The given chemical reaction follows:

[tex]N_2+O_2\rightarrow 2NO[/tex]

As, oxygen gas is present in excess. Thus, it is considered as an excess reagent and nitrogen is considered as a limiting reagent because it limits the formation of products.

By Stoichiometry of the reaction:

1 mole of nitrogen gas produces 2 moles of nitrogen oxide.

So, 0.357 moles of nitrogen gas will produce = [tex]\frac{2}{1}\times 0.357=0.714mol[/tex] of nitrogen oxide.

Now, calculating mass of nitrogen oxide by putting values in equation 1, we get:

Moles of nitrogen oxide = 0.714 mol

Molar mass of nitrogen oxide = 30 g/mol

Putting values in equation 1, we get:

[tex]0.714mol=\frac{\text{Mass of nitrogen oxide}}{30g/mol}\\\\\text{Mass of nitrogen oxide}=21.4g[/tex]

Hence, the correct answer is Option B.

Answer: The correct answer is Option A.

Explanation:

We are given:

4.5 wt % of Pb means that 4.5 grams of lead is present in 100 g of alloy.

95.5 wt % of Sn means that 95.5 grams of tin is present in 100 g of alloy.

To calculate the atom percent of any compound in a mixture, we use the equation:

[tex]\text{atom }\%=\frac{\text{Moles of compound}\times N_A}{\text{Total number of moles of mixture}\times N_A}\times 100[/tex]

where,

[tex]N_A[/tex] = Avogadro's number

Moles of a compound is given by the formula:

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

Given mass of lead = 4.5 g

Molar mass of lead = 207.19 g/mol

[tex]\text{Atom percent of lead}=\left(\frac{\frac{4.5g}{207.17g/mol}\times N_A}{(\frac{4.5g}{207.17g/mol}+\frac{95.5g}{118.71g/mol})\times N_A}\right)\times 100\\\\\text{Atom percent of lead}=2.6\%[/tex]

Given mass of tin = 95.5 g

Molar mass of tin = 118.71 g/mol

[tex]\text{Atom percent of Tin}=\left(\frac{\frac{95.5g}{118.71g/mol}\times N_A}{(\frac{4.5g}{207.17g/mol}+\frac{95.5g}{118.71g/mol})\times N_A}\right)\times 100\\\\\text{Atom percent of Tin}=97.4\%[/tex]

Hence, the correct answer is Option A.

The composition, in atom percent, of an alloy consisting of 4.5 wt% Pb and 95.5 wt% Sn is 2.6 at% Pb and 97.4 at% Sn. The correct answer is (A).

The atomic weights for Pb and Sn are 207.19 g/mol and 118.71 g/mol, respectively.

To determine the atom percent, we need to follow these steps:

Moles of Pb: 4.5 g / 207.19 g/mol = 0.0217 mol

Moles of Sn: 95.5 g / 118.71 g/mol = 0.8047 mol

Total moles = 0.0217 mol (Pb) + 0.8047 mol (Sn) = 0.8264 mol

Atom percent of Pb: (0.0217 mol / 0.8264 mol) * 100 ≈ 2.6 at% Pb

Atom percent of Sn: (0.8047 mol / 0.8264 mol) * 100 ≈ 97.4 at% Sn

Thus, the correct answer is (A) 2.6 at% Pb and 97.4 at% Sn.

To find the number of moles of CO needed, we use the balanced equation and convert the mass of Fe2O3 to moles. The number of moles of CO needed is 75.12 mol. To find the number of moles of each product formed, we use the same approach and find that 50.08 moles of Fe and 75.12 moles of CO2 are formed.

To find the number of moles of CO needed to react with 4.00 kg of Fe2O3, we can use the balanced equation:

Fe2O3 + 3CO --> 2Fe + 3CO2

The molar mass of Fe2O3 is 159.69 g/mol. Converting 4.00 kg to grams gives us 4000 g. Using the molar mass of Fe2O3, we can calculate the number of moles of Fe2O3 as follows:

moles of Fe2O3 = mass of Fe2O3 / molar mass of Fe2O3

moles of Fe2O3 = 4000 g / 159.69 g/mol = 25.04 mol

Since the ratio of Fe2O3 to CO in the balanced equation is 1:3, we can use this ratio to find the number of moles of CO:

moles of CO = moles of Fe2O3 x (3 mol CO / 1 mol Fe2O3)

moles of CO = 25.04 mol x (3 mol CO / 1 mol Fe2O3) = 75.12 mol CO

Therefore, 75.12 moles of CO are needed to react with 4.00 kg of Fe2O3.

To find the number of moles of each product formed, we can use the same approach. Since the balanced equation tells us that the ratio of Fe2O3 to Fe is 1:2, and the ratio of Fe2O3 to CO2 is 1:3, the number of moles of Fe and CO2 will be twice the number of moles of Fe2O3:

moles of Fe = 2 x 25.04 mol = 50.08 mol

moles of CO2 = 3 x 25.04 mol = 75.12 mol

Therefore, 50.08 moles of Fe and 75.12 moles of CO2 are formed.

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(a) If 4.00 kg FeO3 are available to react then 37.43 moles of CO are needed. (b) 49.90 moles of Fe and 37.43 moles of CO₂ are formed.

a) First, we need to convert the mass of Fe₂O₃ to moles. The molar mass of Fe₂O₃ is approximately 159.69 g/mol, so 4.00 kg of Fe₂O₃ is about 24.95 moles.

The balanced chemical equation for the reaction is:

2Fe₂O₃ + 3CO → 4Fe + 3CO₂

From this equation, we can see that 2 moles of Fe₂O₃ react with 3 moles of CO. Therefore, the number of moles of CO needed is:

moles of CO = moles of Fe₂O₃ × (moles of CO / moles of Fe₂O₃) = [tex]24.95 * \frac{3}{2} = 37.43 moles[/tex]

b) From the balanced chemical equation, we can see that 2 moles of Fe₂O₃ produce 4 moles of Fe and 3 moles of CO₂. Therefore, the number of moles of each product formed is:

moles of Fe = moles of Fe₂O₃ × (moles of Fe / moles of Fe₂O₃) = [tex]24.95 * \frac{4}{2} = 49.90 moles[/tex]

moles of CO₂ = moles of Fe₂O₃ × (moles of CO₂ / moles of Fe₂O₃) = [tex]24.95 * \frac{3}{2} = 37.43 moles[/tex]

Therefore, 4.00 kg of Fe₂O₃ can react with 37.43 moles of CO to produce 49.90 moles of Fe and 37.43 moles of CO₂.

Answer:

E = 1.602v

Explanation:

Use the Nernst Equation => E(non-std) = E⁰(std) – (0.0592/n)logQc …

             Zn⁰(s) => Zn⁺²(aq) + 2 eˉ

2Ag⁺(aq) + 2eˉ=> 2Ag⁰(s)          

_____________________________

Zn⁰(s) + 2Ag⁺(aq) => Zn⁺²(aq) + 2Ag(s)

Given E⁰ = 1.562v

Qc = [Zn⁺²(aq)]/[Ag⁺]² = (1 x 10ˉ³)/(0.150)² = 0.044

E = E⁰ -(0.0592/n)logQc = 1.562v – (0.0592/2)log(0.044) = 1.602v

Answer:

E = 1.602 V

Explanation:

Let's consider the following galvanic cell.

Zn(s) | Zn²⁺(aq, 1.00 × 10⁻³ M) || Ag⁺(aq, 0.150 M) | Ag(s)

The corresponding half-reactions are:

Zn(s) → Zn²⁺(aq, 1.00 × 10⁻³ M) + 2 e⁻

2 Ag⁺(aq, 0.150 M) + 2 e⁻ → 2 Ag(s)

The overall reaction is:

Zn(s) + 2 Ag⁺(aq, 0.150 M) → Zn²⁺(aq, 1.00 × 10⁻³ M) + 2 Ag(s)

We can find the cell potential (E) using the Nernst equation.

E = E° - (0.05916/n) . log Q

where,

E°: standard cell potential

n: moles of electrons transferred

Q: reaction quotient

E = E° - (0.05916/n) . log [Zn²⁺]/[Ag⁺]²

E = 1.562 V - (0.05916/2) . log (1.00 × 10⁻³)/(0.150)²

E = 1.602 V

Answer:

The value of the dissociation constant will be:[tex]3.94\times 10^{-4}[/tex].

Explanation:

                [tex]AsH\rightleftharpoons As^++H^+[/tex]

At ,t= 0      c              0     0

At eq'm   (c-x)            x     x

Concentration of aspirin = c

[tex]c=\frac{2.00 g}{180 g/mol\times 0.600 L}=0.01851 M [/tex]

Expression for dissociation constant will be given as:

[tex]K_a=\frac{[H^+][As^+]}{[AsH]}=\frac{x\times c}{(c-x)}=\frac{x^2}{(c-x)}[/tex]..(1)

The pH of the solution  = 2.60

The pH of the solution is due to free hydrogen ions whcih come into solution after partial dissociation of aspirin.

[tex]pH=2.60=\log[H^+]=-\log[x][/tex]

[tex]x=0.002511 M[/tex]

Putting value of x in (1).

[tex]K_a=\frac{x^2}{(c-x)}=\frac{(0.002511 M)^2}{(0.01851 M-0.002511 M)}[/tex]

[tex]K_a=3.94\times 10^{-4}[/tex]

The value of the dissociation constant will be:[tex]3.94\times 10^{-4}[/tex].

Final answer:

The theoretical yield of MnO2, given 2 moles of Mn and 2 moles of O2, is calculated using stoichiometry and is found to be approximately 1.33 moles based on O2 being the limiting reactant.

Explanation:

To calculate the theoretical yield of MnO₂ from the reaction 2 Mn(s) + 3 O₂ (g) → MnO₂(s), with the initial quantities of 2 mol Mn and 2 mol O₂, we will use stoichiometry. First, we write the balanced chemical equation:

2 Mn(s) + 3 O₂(g) → 2 MnO₂(s)

This equation tells us that 2 moles of Mn react with 3 moles of O₂ to produce 2 moles of MnO₂. Therefore, Mn and O₂ react in a 2:3 mole ratio to produce MnO₂.

The stoichiometry shows the molar ratio of Mn to MnO₂ is 1:1. Since we have 2 moles of Mn, we can produce 2 moles of MnO₂, assuming Mn is the limiting reactant. However, we must also consider O₂. With 2 moles of O₂, the stoichiometry suggests every 3 moles of O₂ produce 2 moles of MnO₂. The limiting reactant is O₂ since it will limit the formation of MnO₂ to 4/3 moles (which is the amount of MnO₂ formed from 2 moles of O₂ based on the 3:2 ratio of O₂ to MnO₂).

Therefore, the theoretical yield of MnO₂ in moles is 4/3 moles or approximately 1.33 moles. This is based on the stoichiometric calculations from the balanced equation taking into account the initial quantities of both reactants and identifying the limiting reactant.

Answer: The correct answer is Option D.

Explanation:

Atomic mass of an atom is defined as the sum of number of neutrons and number of protons that are present in an atom. It is represented as 'A'.

Atomic number = Number of protons + Number of neutrons

We are given:

Number of protons = 6

Number of neutrons = 6

Number of electrons = 6

Atomic mass = 6 + 6 = 12

Hence, the correct answer is Option D.

Answer: The mass of butane reacting with oxygen gas is 9.76 grams.

Explanation:

To calculate the number of moles, we use the equation:

[tex]\text{Number of moles}=\frac{\text{Given mass}}{\text{Molar mass}}[/tex]    .....(1)

Given mass of oxygen gas = 35.1 g

Molar mass of oxygen gas = 32 g/mol

Putting values in equation 1, we get:

[tex]\text{Moles of oxygen gas}=\frac{35.1g}{32g/mol}=1.096mol[/tex]

For the given chemical reaction:

[tex]2C_4H_{10}+13O_2\rightarrow 8CO_2+10H_2O[/tex]

By stoichiometry of the reaction:

13 moles of oxygen gas is reacting with 2 moles of butane.

So, 1.096 moles of oxygen gas will react with = [tex]\frac{2}{13}\times 1.096=0.168moles[/tex] of butane.

Now, calculating the mass of butane from equation 1, we get:

Molar mass of butane = 58.12 g/mol

Moles of butane = 0.168 moles

Putting values in equation 1, we get:

[tex]0.168mol=\frac{\text{Mass of butane}}{58.12g/mol}\\\\\text{Mass of butane}=9.76g[/tex]

Hence, the mass of butane reacting with oxygen gas is 9.76 grams.

Answer : The equilibrium constant [tex]K_c[/tex] for the reaction is, 0.1133

Explanation :

First we have to calculate the concentration of [tex]Br_2[/tex].

[tex]\text{Concentration of }Br_2=\frac{\text{Moles of }Br_2}{\text{Volume of solution}}[/tex]

[tex]\text{Concentration of }Br_2=\frac{1.35moles}{0.780L}=1.731M[/tex]

Now we have to calculate the dissociated concentration of [tex]Br_2[/tex].

The balanced equilibrium reaction is,

                              [tex]Br_2(g)\rightleftharpoons 2Br(aq)[/tex]

Initial conc.         1.731 M      0

At eqm. conc.      (1.731-x)    (2x) M

As we are given,

The percent of dissociation of [tex]Br_2[/tex] = [tex]\alpha[/tex] = 1.2 %

So, the dissociate concentration of [tex]Br_2[/tex] = [tex]C\alpha=1.731M\times \frac{1.2}{100}=0.2077M[/tex]

The value of x = 0.2077 M

Now we have to calculate the concentration of [tex]Br_2\text{ and }Br[/tex] at equilibrium.

Concentration of [tex]Br_2[/tex] = 1.731 - x  = 1.731 - 0.2077 = 1.5233 M

Concentration of [tex]Br[/tex] = 2x = 2 × 0.2077 = 0.4154 M

Now we have to calculate the equilibrium constant for the reaction.

The expression of equilibrium constant for the reaction will be :

[tex]K_c=\frac{[Br]^2}{[Br_2]}[/tex]

Now put all the values in this expression, we get :

[tex]K_c=\frac{(0.4154)^2}{1.5233}=0.1133[/tex]

Therefore, the equilibrium constant [tex]K_c[/tex] for the reaction is, 0.1133

The equilibrium constant (Kc) for the dissociation reaction of Br₂ into 2Br at high temperature, given an initial amount of 1.35 moles in a 0.780 L flask and 3.60% dissociation, is calculated to be approximately 0.0093.

You've been tasked with calculating the equilibrium constant (Kc) for the dissociation of bromine into bromine atoms at high temperature using the given data: An initial amount of 1.35 moles of Br₂ in a 0.780 L flask with 3.60 percent dissociation.

Determine the initial concentration of Br₂ by dividing moles by volume: CBr₂(initial) = moles / volume.

Calculate the amount dissociated by multiplying the initial concentration by the percentage dissociated.

Determine concentrations at equilibrium using the stoichiometry of the reaction.

Use the formula Kc = [Br]² / [Br₂] to find the equilibrium constant.

Let's calculate it:

CBr₂(initial) = 1.35 moles / 0.780 L = 1.731 moles/L.

Amount dissociated = 1.731 moles/L x 3.60% = 0.06232 moles/L.

At equilibrium, [Br₂] = 1.731 - 0.06232 = 1.6687 moles/L, and [Br] = 2 x 0.06232 moles/L = 0.12464 moles/L.

The equilibrium constant Kc = (0.12464)^2 / 1.6687 = 0.00930628672.

The equilibrium constant Kc for the given reaction is approximately 0.0093.

Answer:

The 1st functional group is secondary amine and the 2nd fun. group is tertiary amine.

Explanation:

Lidocaine does not contain amide functional group in its composition as nitrogen is associated only with carbon.

In lidocaine, Functional group 1 is a secondary amine because it has two hydrocarbon groups attached to the nitrogen atom, and Functional group 2 is an amide due to the presence of a carbonyl group bonded to the nitrogen atom.

To classify the nitrogen-containing functional groups in lidocaine, it is important to understand the structure of amines and amides. Amines are classified as primary, secondary, or tertiary by the number of hydrocarbon groups attached to the nitrogen atom, with a primary amine having one alkyl or aryl group, a secondary amine having two, and a tertiary amine having three. An amide is a functional group with a carbonyl group (C=O) bonded to a nitrogen atom. In the structure of lidocaine, Functional group 1 is a secondary amine because it has two carbon atoms directly bonded to the nitrogen atom. Functional group 2 is an amide, identifiable by its carbonyl group bonded to the nitrogen atom.