. If 84 grams of sodium chloride reacts with an excess amount of magnesium oxide, how many grams of sodium oxide will be produced? Question 2 options: 23.2 g Na20 45g MgCl2 107g MgO 44.5g Na20

approximately 132.03 grams of carbon dioxide is produced.

To solve this problem, we first need to write the balanced chemical equation for the combustion of ethanol [tex](\(C_2H_5OH\))[/tex]:

[tex]\[ C_2H_5OH + O_2 \rightarrow H_2O + CO_2 \][/tex]

Now, we can balance the equation:

[tex]\[ C_2H_5OH + 3O_2 \rightarrow 2H_2O + 2CO_2 \][/tex]

From the balanced equation, we can see that 1 mole of ethanol [tex](C_2H_5OH\))[/tex] reacts with 3 moles of oxygen [tex](\(O_2\))[/tex] to produce 2 moles of water [tex](\(H_2O\))[/tex] and 2 moles of carbon dioxide [tex](\(CO_2\))[/tex].

Given:

- Mass of ethanol [tex](\(C_2H_5OH\)):[/tex] 46.0 g

- Mass of water [tex](\(H_2O\))[/tex] produced: 54.0 g

First, we need to calculate the moles of water produced:

[tex]\[ \text{Moles of water} = \frac{\text{Mass of water}}{\text{Molar mass of water}} \][/tex]

[tex]\[ \text{Moles of water} = \frac{54.0 \, \text{g}}{18.015 \, \text{g/mol}} \][/tex]

[tex]\[ \text{Moles of water} \approx 3.0 \, \text{mol} \][/tex]

According to the balanced equation, the ratio of moles of water to moles of carbon dioxide is 2:2. Therefore, the moles of carbon dioxide produced is also approximately 3.0 mol.

Now, to find the mass of carbon dioxide produced:

[tex]\[ \text{Mass of } CO_2 = \text{Moles of } CO_2 \times \text{Molar mass of } CO_2 \][/tex]

[tex]\[ \text{Mass of } CO_2 = 3.0 \, \text{mol} \times 44.01 \, \text{g/mol} \][/tex]

[tex]\[ \text{Mass of } CO_2 = 132.03 \, \text{g} \][/tex]

Therefore, approximately 132.03 grams of carbon dioxide is produced.

Answer:

A = 3.5 moles

Explanation:

In order to do this, we need first to write the innitial conditions. The reaction is as follow:

A(s) <-------> B(g) + C(g)

From here, we can write an expression for the equilibrium constant which is:

Kc = [B]*[C]

We don't take A in the expression, because is solid, and solid and liquids do not contribute in the equilibrium.

We know the concentration of B, which is the same for C, because the moles of C are coming from A when it's decomposed, so if B is 1.3 M we can assume C is the same.

Kc for this innitial condition is:

Kc = (1.3)*(1.3) = 1.69

Now, in the second part of reaction the volume is doubled, which means that concentrations are halved:

A: 4.8/2 = 2.4 M

B and C: 1.3/2 = 0.65 M

So conditions for the second part will be like this:

   A(s) <----> B(g) + C(g)   Kc = 1.69

I:   2.4           0.65   0.65

C:  -x              +x       +x

E: 2.4-x         0.65+x   0.65+x

Replacing in Kc we have:

1.69 = (0.65+x)²   solving for x here

√1.69 = 0.65+x

1.3 = 0.65+x

x = 1.3 - 0.65

x = 0.65 M

Therefore, the remaining moles of A would be:

A = 2.4 - 0.65

[A] = 1.75 M

moles A = 1.75 * 2 = 3.5 moles

Answer: carbonic acid

Explanation:

Answer:

See explanation and picture

Explanation:

Question is incomplete, however, I found this question on several sites and most of them, have the same substances, so I'm gonna do it with that example to give you a hint of how to do it with yours, in case, it's a different substance.

First, we have a ketone and another substance, with MgCl. This is tipically the Grignard reagent, and this is often used to produce a tertiary alcohol.

The mechanism and final product is the following (See attached picture).

When a reaction product is treated with water, different outcomes can occur such as acid-base reactions, hydrolysis reactions, or precipitation reactions. The specific product depends on the reactants and reaction conditions.

Without knowing the specific reactants, it is difficult to provide a detailed answer. In general, when a reaction product is treated with H2O (water), it can lead to various outcomes such as hydrolysis, formation of an acid or base, or precipitation of a solid. Some reactions that occur with water are:

The exact product will depend on the specific reactants and reaction conditions.

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Answer:

The percent yield for the reaction is 63.7%

Explanation:

This problem can be solved, from different rules of three.

The reaction is:

2NH₃(g) + CO₂(g) → CH₄N₂O(s) + H₂O(l)

2 moles of ammonia, produce 1 mol of urea.

Mass / molar mass = moles

6.59g / 17.031 g/m = 0.387 moles

As ratio is 2:1, I will produce half a mole of urea.

(0.387 m . 1m)/ 2m = 0.193 m

Let's find out the mass.

Mass of urea = Moles of urea . molar mass of urea.

Mass = 0.193m .  60.056 g/m = 11.6 g

If the percent yield for the reaction was 100 %, we make 11.6 g, but I only obtained 7.40 g so let's calculate the new percent yield.

11.6 g ____ 100 %

7.40 g ___ (7.40g / 11.6g) .100 = 63.7 %

Answer:

The molecular formula of this compound is C4H4N2O2

Explanation:

Step 1: Data given

Mass of the compound = 84 mg

The compound contains:

36 mg of Carbon

3 mg of hydrogen

21 mg of nitrogen

24 mg of oxygen

Molar mass of carbon = 12.01 g/mol

Molar mass of hydrogen = 1.01 g/mol

Molar mass of nitrogen = 14 g/mol

Molar mass of oxygen = 16 g/mol

Step 2: Calculate number of moles

Moles = mass / molar mass

Moles of carbon = 0.036 g/ 12.01 g/mol = 0.003 moles

Moles of hydrogen = 0.003 g/ 1.01 g/mol = 0.003 moles

Moles of nitrogen = 0.021 g/ 14 g/mol = 0.0015 moles

Moles of oxygen = 0.024 g/ 16 g/mol = 0.0015 moles

Step 3: Calculate mol ratio

We divide by the smallest amount of moles

C: 0.003 / 0.0015 = 2

H: 0.003 / 0.0015 = 2

N = 0.0015/0.0015 = 1

O = 0.0015/0.0015 = 1

The empirical formula is C2H2NO

The molecular mass of this empirical formula is 56 g/mol

Step 4: Calculate the molecular formula

We have to multiply the empirical formula by n

n = 112 g/mol / 56g/mol = 2

We have to multiply the empirical formula by 2

Molecular formula = 2*(C2H2NO) = C4H4N2O2

The molecular formula of this compound is C4H4N2O2

Answer:

Covalent solids: Se8, Si, C

Molecular solids: HBr, CO2, P4O6, SiH4

Explanation:

A covalent solid consists only of one type of atom infinitely linked by covalent bonds to form a three dimensional rigid solid while a molecular solid consists of discreet molecules held together by intermolecular forces.

Molecular Solid are Se8 and So.

Covalent Solid are Hbr ,Sih4, Co2, P4O6 and C.

molecular solid refer to solid that consist of discrete molecules. The corces that bind the molecules together are van der Waals forces, dipole-dipole interactions, quadrupole and so on.

Covalent Solid refer to solid that the atoms are bonded together by Covalent bonds.

Therefore,

Molecular Solid are Se8 and So.

Covalent Solid are Hbr ,Sih4, Co2, P4O6 and C.

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Answer:

Answer in explanation

Explanation:

A catalyst is a substance that alter the rate of a chemical reaction. It either speeds up the rate of the chemical reaction or slows down the rate of the chemical reaction. Hence, we say a catalyst can either work positively or negatively.

A catalyst will bring down the value of the activation energy. It reduces the minimum amount of energy needed for the reaction to kickstart. Hence we say it tends to create an alternative pathway for the chemical reaction to proceed.

When it speeds up the rate, it is otherwise known as a positive catalyst, otherwise it is a negative catalyst.

A catalyst does not have any business with the nature of the products or the reactants. Its work is simple, either hasten or slow down the rate of a chemical reaction.

A catalyst has no effect On the equilibrium position of a chemical reaction. This is to say its addition or subtraction has no effect on the position of a chemical reaction

Catalysis is the process by which a catalyst lowers the activation energy of a chemical reaction, thus increasing the reaction rate without changing the nature of the products. A catalyst does not shift the position of a reaction at equilibrium but enables the system to reach equilibrium more quickly.

What is Catalysis?

Catalysis refers to the process by which a catalyst increases the rate at which a chemical reaction occurs. A catalyst facilitates a chemical reaction without undergoing any permanent chemical change itself. It works by providing an alternative reaction pathway with a lower activation energy (Ea), which is the energy required to initiate the reaction. This lower activation energy means that more reactant molecules can effectively collide and react at a given temperature, thereby speeding up the reaction rate.

Effect on Activation Energy and Reaction Rate

The presence of a catalyst in a chemical reaction results in a lower activation energy barrier. This, in turn, means that a greater percentage of reactant molecules have enough energy to overcome this barrier and form products. Consequently, the reaction rate is increased since the reaction can proceed faster.

Does a Catalyst Change the Nature of the Products?

A catalyst does not affect the energy of the reactants or the products, nor does it alter the overall thermodynamics of the reaction. Therefore, it does not change the nature of the products of the reaction.

Adding a Catalyst to a Reaction in Equilibrium

When a reaction is in equilibrium, adding a catalyst will not shift the equilibrium position or alter the concentrations of reactants and products at equilibrium. Instead, it will increase the rate at which equilibrium is reached by speeding up both the forward and reverse reactions equally.

The question is incomplete, here is the complete question:

Phosgene, [tex]COCl_2[/tex], gained notoriety as a chemical weapon in World War I. Phosgene is produced by the reaction of carbon monoxide with chlorine:  

[tex]CO(g)+Cl_2(g)\rightleftharpoons COCl_2(g)[/tex]

The value of [tex]K_c[/tex] for this reaction is 5.79 at 570 K. What are the equilibrium partial pressures of the three gases if a reaction vessel initially contains a mixture of the reactants in which [tex]p_{CO}=p_{Cl_2}=0.265atm[/tex] and [tex]p_{COCl_2}=0.000atm[/tex] ?

Answer: The equilibrium partial pressure of CO, [tex]Cl_2\text{ and }COCl_2[/tex] is 0.257 atm, 0.257 atm and 0.008 atm respectively.

Explanation:

The relation of [tex]K_c\text{ and }K_p[/tex] is given by:

[tex]K_p=K_c(RT)^{\Delta n_g}[/tex]

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

[tex]K_c[/tex] = Equilibrium constant in terms of concentration = 5.79

[tex]\Delta n_g[/tex] = Difference between gaseous moles on product side and reactant side = [tex]n_{g,p}-n_{g,r}=1-2=-1[/tex]

R = Gas constant = [tex]0.0821\text{ L. atm }mol^{-1}K^{-1}[/tex]

T = Temperature = 570 K

Putting values in above equation, we get:

[tex]K_p=5.79\times (0.0821\times 570)^{-1}\\\\K_p=0.124[/tex]

We are given:

Initial partial pressure of CO = 0.265 atm

Initial partial pressure of chlorine gas = 0.265 atm

Initial partial pressure of phosgene = 0.00 atm

The given chemical equation follows:

                      [tex]CO(g)+Cl_2(g)\rightleftharpoons COCl_2(g)[/tex]

Initial:            0.265      0.265

At eqllm:        0.265-x    0.265-x        x

The expression of [tex]K_p[/tex] for above equation follows:

[tex]K_p=\frac{p_{COCl_2}}{p_{CO}\times p_{Cl_2}}[/tex]

Putting values in above equation, we get:

[tex]0.124=\frac{x}{(0.265-x)\times (0.265-x)}\\\\x=0.0082,8.59[/tex]

Neglecting the value of x = 8.59 because equilibrium partial pressure cannot be greater than initial pressure

So, the equilibrium partial pressure of CO = [tex](0.265-x)=(0.265-0.008)=0.257atm[/tex]

The equilibrium partial pressure of [tex]Cl_2=(0.265-x)=(0.265-0.008)=0.257atm[/tex]

The equilibrium partial pressure of [tex]COCl_2=x=0.008atm[/tex]

Hence, the equilibrium partial pressure of CO, [tex]Cl_2\text{ and }COCl_2[/tex] is 0.257 atm, 0.257 atm and 0.008 atm respectively.

The equilibrium partial pressures of CO, Cl2, and COCl2 are 5.79 atm, 5.79 atm, and 0.10 atm, respectively.

The equilibrium partial pressures of the three gases can be determined using the equilibrium expression and the given information. The equilibrium expression for the phosgene-forming reaction is:

PCOCl2 = (PCO * PCl2) / PCOCl2,eq

Given that the equilibrium constant (Kc) is 5.79, the equilibrium partial pressures can be calculated as follows:

PCO = (PCOCl2,eq / PCl2) * Kc

PCl2 = (PCOCl2,eq / PCO) * Kc

Substituting the given information:

PCO = (0.10 atm / 0.10 atm) * 5.79 = 5.79 atm

PCl2 = (0.10 atm / 0.10 atm) * 5.79 = 5.79 atm

PCOCl2,eq = 0.10 atm

The equilibrium partial pressures of CO, Cl2, and COCl2 are 5.79 atm, 5.79 atm, and 0.10 atm, respectively.

Answer:

I have no idea how to do this question its hard for me

Explanation:

All colors of visible light can eject electrons from cesium due to its low work function. For selenium, only light towards the blue/violet end of the spectrum (short wavelength, high energy) can eject electrons due to its higher work function.

The phenomenon discussed in question involves the photoelectric effect, which occurs when light of a certain wavelength strikes a metal and ejects electrons. The color of light that can eject electrons from a substance is dependent on the substance's work function, the minimum energy necessary to remove an electron from the substance.

Given Cesium's low work function (3.43 × 10^-19 J), it can be activated by a wide range of wavelengths, meaning that all visible colors of light, from red (long wavelength, low energy) to violet (short wavelength, high energy), can eject electrons from it.

However, with Selenium's higher work function (9.5 × 10^-19 J), only light with shorter wavelengths and therefore higher energy, will be able to eject electrons. This means that only light towards the blue/violet end of the spectrum will be able to eject electrons from this element.

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Answer:

It is called an antidiurectic hormone

Answer:

117.3 W is being removed.

Explanation:

The heat removed can be calculated as:

Q = m*c*ΔT

Where m is the mass, c is the specific heat and ΔT is the temperature variation. Because there're two components:

Q = mwater*cwater*ΔT + maluminum*caluminum*ΔT

Q = (mwater*cwater + maluminum*caluminum)*ΔT

Searching in a thermodynamic table:

cwater = 4.184 J/g°C

caluminium = 0.9 J/g°C

In 1 minute, the temperature decreases 2.2°C, so ΔT =  -2.2°C

Q = (700*4.184 + 300*0.9) * (-2.2)

Q = -7037.36 J

The rate of energy is the potency (P), which is the heat divided by the time. So, for 1 minute (60 s):

P = -7037.36/60

P = -117.3 J/s

P = -117.3 W

The minus signal indicates that the energy is being removed.

Answer:

₉₂U²³⁸   →   ₉₀Th²³⁴  + ₂He⁴  + energy

Explanation:

Alpha decay:

Alpha radiations are emitted as a result of radioactive decay. The atom emit the alpha particles consist of two proton and two neutrons. Which is also called helium nuclei. When atom undergoes the alpha emission the original atom convert into the atom having mass number less than 4  and atomic number less than 2 as compared to parent atom the starting atom.

Properties of alpha radiation:

Alpha radiations can travel in a short distance.

These radiations can not penetrate into the skin or clothes.

These radiations can be harmful for the human if these are inhaled.

These radiations can be stopped by a piece of paper.

₉₂U²³⁸   →   ₉₀Th²³⁴  + ₂He⁴  + energy

Answer:

14. B    15. D    16. C     17. B

Explanation:

The spontaneous reaction that occurs when the cell operates is shown below:

[tex]2Ag^{+} + Cd_{(s)}[/tex] ⇒[tex]2Ag_{(s)} + Cd^{2+}[/tex]

We need to select the correct option from the list below for the following questions.

(A) Voltage increases. (B) Voltage decreases but remains > zero. (C) Voltage becomes zero and remains at zero. (D) No change in voltage occurs. (E) Direction of voltage change cannot be predicted without additional information.

14. A 50-milliliter sample of a 2-molar [tex]Cd(NO_{3})_{2}[/tex] solution is added to the left beaker.

If a 50-milliliter sample of a 2-molar [tex]Cd(NO_{3})_{2}[/tex]  solution is added to the left beaker, the voltage decreases but its value remains greater than zero. The correct option is B

15. The silver electrode is made larger.

If the silver electrode is made larger, no change in the value of the voltage since we don't have the idea of the initial value. The correct option is D.

16. The salt bridge is replaced by a platinum wire.

If the salt bridge is replaced by a platinum wire, there will be no passage of electrons because electrons can't pass through a platinum wire. Therefore, the voltage will be zero and remains at zero. The correct option is C.

17. Current is allowed to flow for 5 minutes.

If current is allowed to flow for 5 minutes, the voltage decreases but its value remains greater than zero. The correct option is B.

A galvanic cell produces energy by a spontaneous redox reaction.

In galvanic or voltaic cell, energy is produced via a spontaneous redox reaction. The redox reaction equation of this reaction is;  2Ag^+ + Cd(s) ---> 2 Ag(s) + Cd^2+.

The answers to the questions are as follows;

14) When we add 50-milliliter sample of a 2-molar solution of cadmium nitrate, the voltage will decrease but remains greater than zero.

15) The voltage will remain the same after the increase in the size of the silver electrode because its initial value is unknown.

16) The voltage will remain at zero if the salt bridge is replaced by a platinum wire since current can not pass through

17) The voltage will decrease if current flows for five minutes.

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Answer:

1 M

Explanation:

Magnesium chloride will furnish chloride ions as:

[tex]MgCl_2\rightarrow Mg^{2+}+2Cl^-[/tex]

Given :

Moles of magnesium chloride = 0.20 mol

Thus, moles of chlorine furnished by magnesium chloride is twice the moles of magnesium chloride as shown below:

[tex]Moles =2\times 0.20\ moles[/tex]

Moles of chloride ions by magnesium chloride = 0.40 moles

Potassium chloride will furnish chloride ions as:

[tex]KCl\rightarrow K^{+}+Cl^-[/tex]

Given :

Moles of potassium chloride = 0.10 moles

Thus, moles of chlorine furnished by potassium chloride is same as the moles of potassium chloride as shown below:

Moles of chloride ions by potassium chloride = 0.10 moles

Total moles = 0.40 + 0.10 moles = 0.50 moles

Given, Volume = 500 mL = 0.5 L (1 mL = 10⁻³ L)

Concentration of chloride ions is:

[tex]Molarity=\frac{Moles\ of\ solute}{Volume\ of\ the\ solution}[/tex]

[tex]Molarity_{Cl^-}=\frac{0.50}{0.5}[/tex]

The final concentration of chloride anion = 1 M

The concentration of the chloride ion, Cl¯ in the solution is 1 M

To obtain the answer to the question given above, we'll begin by calculating the number of mole of chloride ion, Cl¯ produced by each compound in the solution. This can be obtained as follow:

MgCl₂(aq) —> Mg²⁺(aq) + 2Cl¯(aq)

From the balanced equation above,

1 mole of MgCl₂ produced 2 moles of Cl¯.

Therefore, 0.2 mole of MgCl₂ will produce = 0.2 × 2 = 0.4 mole of Cl¯

KCl(aq) —> K⁺(aq) + Cl¯(aq)

From the balanced equation above,

1 mole of KCl produced 1 mole of Cl¯

Therefore,

0.1 mole of KCl will also produce 0.1 mole of Cl¯.

Next, we shall determine the total mole of Cl¯ in the solution.

Mole of Cl¯ from MgCl₂ = 0.4 mole

Mole of Cl¯ from KCl = 0.1 mole

Total mole of Cl¯ = 0.4 + 0.1

Finally, we shall determine the concentration of Cl¯ in the solution.

Total mole of Cl¯ = 0.5 mole

Volume = 500 mL = 500 / 1000 = 0.5 L

Concentration = mole / Volume

Concentration of Cl¯ = 0.5 / 0.5

Therefore, the concentration of Cl¯ in the solution is 1 M

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Answer: option A) True

Explanation:

Joseph Proust is the founder of the Law of Definite proportion. This law states that two elements will always combine together to form a chemical compound and this will be in the same proportion by mass.

For Example: 2 moles of Hydrogen (H2) ALWAYS combine with 1 atom of Oxygen (O) to yield water (H2O)

So, the answer is True

Answer:

160 g

Explanation:

The formula for the calculation of moles is shown below:

[tex]moles = \frac{Mass\ taken}{Molar\ mass}[/tex]

For [tex]H_2SO_4[/tex]:-  

Mass of [tex]H_2SO_4[/tex] = 196 g

Molar mass of [tex]H_2SO_4[/tex] = 98 g/mol

The formula for the calculation of moles is shown below:

[tex]moles = \frac{Mass\ taken}{Molar\ mass}[/tex]

Thus,

[tex]Moles= \frac{196\ g}{98\ g/mol}[/tex]

[tex]Moles\ of\ Sulfuric\ acid= 2\ mol[/tex]

According to the given reaction:

[tex]2NaOH+H_2SO_4\rightarrow Na_2SO_4+2H_2O[/tex]

1 mole of sulfuric acid reacts with 2 moles of NaOH

So,  

2 moles of sulfuric acid reacts with 2*2 moles of NaOH

Moles of NaOH must react = 4 moles

Molar mass of NaOH = 40 g/mol

Mass = Moles*molar mass = [tex]4\times 40\ g[/tex] = 160 g

Final answer:

To react completely with 196 grams of H₂SO₄, you would need 80 grams of NaOH. This calculation involves balancing the chemical equation and using stoichiometry.

Explanation:

Step 1: Write and balance the chemical equation:
H₂SO₄ + 2NaOH → Na₂SO₄ + 2H₂O

Step 2: Calculate the molar mass of NaOH (40 g/mol) and H₂SO₄ (98 g/mol).

Step 3: Use stoichiometry to find the moles of NaOH needed to react completely with 196 grams of H₂SO₄. From the balanced equation, 1 mole of H₂SO₄ reacts with 2 moles of NaOH.

Step 4: Calculate the total number of grams of NaOH needed:

(196 g H₂SO₄) x (1 mol NaOH / 98 g H₂SO₄) x (40 g NaOH / 1 mol NaOH) = 80 grams of NaOH

Answer:

The answers are

The warmer temperatures at Zeke's destination caused the pressure in his tires to increase.

The warmer temperatures at Zeke's destination caused the pressure in his tires to increase.

The warmer temperatures at Zeke's destination caused the pressure in his tires to spread out equally.

Explanation:

Explanation:

An ionic solution is when a compound's ions in an aqueous solution have dissociated. As you combine two aqueous solutions, a reaction occurs. This is when you find out whether or not a precipitate is going to form. A precipitate occurs when the ion reaction component in water is insoluble.The formation of a precipitate is an indication that a chemical change has occurred. for example if we mix clear solutions of silver nitrate and sodium chloride, sodium nitrate is formed which is a precipitate.

Answer: the answer should and most definitely be D.

Explanation: I mean think about it after a while only a few radioactive nuclei are left which means it will dye down after a while which also makes it very boring hope this helps :)

Answer:

a,b,c,d,e

Explanation:

just did it on ed 2020

Answer:

Melting point of aqueous solution = -10.32 °C

Explanation:

[tex]\Delta T_f=i \times k_f \times m[/tex]

Where,

ΔT_f = Depression in freezing point

k_f = molal depression constant

m = molality

Formula for the calculation of molality is as follows:

[tex]m=\frac{Mass\ of\ solute\ (kg)}{molecular\ mass\ of\ solute \times mass\ of\ solvent}[/tex]

density of water = 1 g/mL

density = mass/volume

Therefore,

mass = density × volume

volume = 3 L = 3000 mL

Mass of water = 1 g/mL × 3000 mL

                        = 3000 g

[tex]Molality(m)=\frac{100\times1000}{18\times 3000} \\=1.85\ m[/tex]

van't Hoff factor (i) for MgCl2 = 3

Substitute the values in the equation (1) to calculate depression in freezing point as follows:

[tex]\Delta T_f=i \times k_f \times m\\=3\times 1.86 \times 1.85\\=10.32\ °C[/tex]

Melting point of aqueous solution = 0 °C - 10.32 °C

                                                          = -10.32 °C

Answer:

The melting point of the solution is - 1.953 °C

Explanation:

In an ideal solution, the freezing point depression is computed as follows:

[tex]ΔT_f = k_f \times b \times i [/tex]

where:

[tex]ΔT_f[/tex] is the freezing-point depression

[tex]k_f[/tex] is the cryoscopic constant, in this case is equal to 1.86

b is the molality of the solution

i is the van't Hoff factor, number of ion particles per individual molecule of solute, in this case is equal to 3

Molality is defined as follows:

b = moles of solute/kg of solvent

Moles of solute is calculated as follows:

moles of solute = mass of solute/molecular weight of solute

In this case there are 100 g of solute and its molecular weight is 35.5*2 + 24 = 95 g/mole. So, the moles are:

moles of solute = 100 g/(95 g/mol) = 1.05 moles

The mass of solvent is computed as follows:

mass of solvent = density of solvent * Volume of solvent

Replacing with the data of the problem we get:

mass of solvent = 1 kg/L*3 L = 3 kg

Finally, the molality of the solution is:

b = 1.05/3 = 0.35 mol/kg

Then, the freezing-point depression is:

[tex]ΔT_f = 1.86 \times 0.35 \times 3 [/tex]

[tex]ΔT_f = 1.953 C[/tex]

The freezing-point depression is the difference between the melting point of the pure solvent (here water) and the melting point of the solution. We know that the the melting point of water is 0 °C, then:

melting point of water - melting point of the solution = 1.953 °C

melting point of the solution  = 0 °C - 1.953 °C = - 1.953 °C

Answer:

Answer in explanation

Explanation:

A renewable source of energy is an energy source that cannot be depleted. It is an energy source with constant abundance and hence it is always in abundance. What we are saying is that they are energy sources that cannot be used up. Although it might sometimes be that it is unavailable at some instances, this does not take away the fact that it is abundant and cannot be depleted, although the strength at different times may vary. Example of renewable energy sources include solar energy, wind energy, hydroelectric power source etc. These sources are never depleted and are in abundance.

Non renewable source of energy are those sources of energy that can be depleted. A good example of this can be seen in fossil fuels. Fossil fuels are usually burned to produce energy. They are used up in the process and it will require an additional amount of fossil fuel to be restocked for the energy to be continually supplied.

Explanation: Renewable resources can be replenished whenever you want, but non-renewable resources will keep dwindling down till there's nothing. For example, solar power is a renewable resource and will always be there because the sun will keep providing more solar power. Coal, on the other hand, is a non-renewable resource and won't always be there because coal takes a lot longer (300 million years) to form.

Answer:

B) conducts electricity

Explanation:

This answer can be answered by the process of elimination.  Metals are excellent conductors of electricity, which means A is out, and metals are also known to have medium reactivity and have high melting points, meaning C and D are also out.

According to the concept of conduction, the common property of metals is that they conduct electricity .

Conduction is defined as a process as a means of which heat is transferred from the hotter end of the body to it's cooler end.Heat flows spontaneously from a body which is hot to a body which is cold.

In the process of conduction,heat flow is within the body and through itself.In solids the conduction of heat is due to the vibrations and collisions of molecules while in liquids and gases it is due to the random motion of the molecules .

When conduction takes place, heat is usually transferred from one molecule to another as they are in direct contact with each other.There are 2 types of conduction:1) steady state conduction 2) transient conduction.According to the type of energy conduction is of three types:

1) heat conduction

2) electrical conduction

3)sound conduction

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Answer:

Rubber is made from long-chain molecules, called polymers, which are normally all scrunched up. When you stretch a rubber band, you  straighten the molecules and pull them apart, so the rubber gets longer. When you let go, cross-link bonds between the polymers help to snap them back into place. This is what makes an elastic material such as rubber (one that returns to its original shape and size) different from a plastic material (one that changes shape but doesn't go back exactly to how it was), which includes most metals as well as most plastics.

Explanation:

Rubber is made of polymers. When the elastic band is at rest, the molecules are entangled with each other and do not have a particular direction, but when the elastic is stretched, they all align. The molecules of the polymer are not stretched, they are aligned in a different way. Therefore, there is no difference in energy, but there is a difference in entropy. When the elastic band is released, all the polymers are randomly agitated by thermal movement, and lose their alignment, so they return to the tangled state, causing the elastic to contract. This is known as entropic force.

Final answer:

When you stretch a rubber band, you straighten the molecules and pull them apart, so the rubber gets longer. When you let go, cross-link bonds between the polymers help to snap them back into place.

Explanation:

Rubber bands stretch by straightening molecules and snapping back due to cross-link bonds, characteristics unique to polymers. Polymer chains' conformational changes give flexibility and the ability to return to the original shape, influenced by factors like chain length and side groups.

The long-chain structure of polymers makes them behave differently from other materials. These chains can undergo conformational change, providing flexibility and the ability to return to their original shape. The physical properties of a polymer depend on factors like chain length, side groups, branching, and cross-linking, impacting its strength and flexibility.

Answer:

1. The α particles were repelled by electrons.

Explanation:

The gold foil experiment was performed by Rutherford and his research group in 1911 (at the beginning of the 20th century). In this experiment, α particles were bombed to gold foils, and films were placed surround it to collect the particles.

It was observed that most of the particles passed through of the foil undeflected, and for that, Rutherford stated that the atom was a "huge empty". Some particles were deflected, because they're attracted to the electrons at the electrosphere, and a small number of particles were complete deflected to the origin because they chocked with the small positive nuclei.

Thus, the experiment suggested the nuclear model of the atom, called the planetary model, that was improved after by Bohr and other scientists in the quantum model.

The false statement about the gold foil experiment is that α particles were repelled by electrons. In reality, their deflection was due to the encounter with a small, dense, positively charged nucleus, leading to the nuclear model of the atom. Therefore, the correct option is 1.

The α particles were repelled by electrons.

It suggested that atoms are mostly empty space.

It suggested the nuclear model of the atom.

Most of the α particles passed through the foil undeflected.

It was performed by Rutherford and his research group early in the 20th century.

The false statement here is statement 1: The α particles were repelled by electrons. This is inaccurate because α particles are positively charged and were repelled when they encountered the dense, positively charged nucleus, not electrons. The gold foil experiment led to the discovery of the atomic nucleus and overturned the plum pudding model of the atom, which assumed a uniform distribution of mass and charge. The experiment showed that atoms are mostly empty space, with most α particles passing through the foil undeflected, a small number deflected at large angles, and a very few reversing direction, indicating the presence of a small, dense, positively charged nucleus.

Answer:

There are 3 elements (6;12) (19;39) and (82;207)

There are 3 isotopes (6;13) (19;41) and (82;206)

Explanation:

Step 1:

Isotopes have the same atomic number but a different mass number

The element with number 19 is Potassium

Potassium has a mass number of 39 g/mol

This is the element potassium and is not an element

41C has mass number of 41 g/mol and is an isotope

The element with number 6 is carbon

Carbon has a mass number of 12 g/mol

13C has a mass number of 13 g/mol and is an isotope

The element with number 82 is lead

Lead has a mass number of  207 g/mol

206Pb has a mass number of 206 g/mol and is an isotope

There are 3 elements (6;12) (19;39) and (82;207)

There are 3 isotopes (6;13) (19;41) and (82;206)

Ionization energy, also called ionization potential, in chemistry, the amount of energy required to remove an electron from an isolated atom or molecule.

The statement is false because the energy required to remove each subsequent electron from an atom increases due to the increasing electrostatic attraction between the positively charged nucleus and the remaining electrons, making successive ionization energies higher.

The statement that "the same amount of energy is required to remove each electron sequentially from an atom" is false. The process of removing electrons from an atom is called ionization, and the energy required to do so is termed ionization energy. Initially, removing an electron from a neutral atom requires a certain amount of energy.

However, as electrons are removed, the atom becomes more positively charged, increasing the electrostatic attraction between the remaining electrons and the nucleus. This makes each successive electron harder to remove, and hence, requires more energy. Such an increase in ionization energy is evident when comparing the first, second, and subsequent ionization energies of an atom.

Newly formed cations (positively charged ions) hold onto their remaining electrons more tightly than the neutral atom did, which clearly illustrates why successive ionization energies increase. This is further emphasized when attempting to remove core electrons after the valence electrons have been removed, which requires significantly more energy due to the stronger electrostatic attraction to the nucleus.

Answer: Step 1, Isomerase.

Explanation:

Form the version of palmitic acid in the step one by changing the double bond within alpha and beta carbon by Isomerase.

B and C are Isomers, the molecule only differ in configuration.

Answer:

B

Explanation:

All the properties listed above is for carbon ii oxide.

It is odorless, colorless and poisonous

It is formed from the incomplete combustion of fossil fuels

And it can actually interfere with the blood’s ability to carry oxygen

Yes bottom line it is Carbon Monoxide!!! mine was D though (different verion)

Answer:

The difference lies in the kind of bond involved.

Explanation:

An ionic solid is composed of a network of oppositely charged ions such as sodium chloride solid. An atomic solid is formed by covalent linkage of atoms of the same element to form a three dimensional solid structure such as in diamond and graphite. A molecular solid consists of discreet molecules held together by intermolecular forces. Examples of molecular solids include naphthalene and the fullerenes.

Final answer:

Crystalline solids are categorized into ionic, molecular, covalent network, and metallic solids, each with unique properties such as melting points and electrical conductivity. Understanding these categories helps predict material behaviors.

Explanation:

Understanding Crystalline Solids: Ionic, Molecular, Covalent Network, and Metallic

Crystalline solids are distinguished based on their bonding and structural properties. They fall into four main categories: ionic solids, molecular solids, covalent network solids, and metallic solids. Each type exhibits distinct properties in terms of melting point, electrical conductivity, solubility in water, and appearance.

Ionic solids are formed through the electrostatic attraction between ions, have high melting points, and conduct electricity only when melted or dissolved in water.

Molecular solids are composed of molecules held together by van der Waals forces, have relatively low melting points, and are poor conductors of electricity in all states.

Covalent network solids consist of atoms connected by covalent bonds into a continuous 3D network, have very high melting points, and typically do not conduct electricity.

Metallic solids are composed of metal atoms packed closely together, have variable melting points, and are good conductors of electricity and heat due to the free movement of electrons.

Solids can broadly be categorized into amorphous solids and crystalline solids, with the latter being further divided into the types discussed. Understanding these categories and their properties aids in predicting the behavior of different materials under various conditions.