Which is an acceptable Lewis structure for a diatomic nitrogen molecule?

The molarity of the solution is 0.279 M.

To find the molarity of the solution, we need to calculate the number of moles of glucose and the volume of the solution in liters. The molarity is defined as moles of solute per liter of solution.

First, we calculate the number of moles of glucose:

Moles of glucose = mass of glucose / molar mass of glucose

Moles of glucose = 5.10 g / 180 g/mol = 0.028 moles

Next, we calculate the volume of the solution in liters:

Volume of solution = 100.5 ml / 1000 = 0.1005 L

Finally, we plug in the values into the molarity formula:

Molarity = moles of glucose / volume of solution

Molarity = 0.028 moles / 0.1005 L = 0.279 M

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J.J. Thomson's experiment did not disprove the theory that atoms are indivisible. Instead, his experiment demonstrated the presence of subatomic particles, specifically electrons, within atoms.

The atom's indivisibleness was not refuted by J. J. Thomson's experiment. Instead, his research demonstrated that electrons, a type of subatomic particle, are present in atoms. The "plum pudding" model of the atom was created as a result of Thomson's research from the late 19th and early 20th centuries, which advanced knowledge of atomic structure.

Thomson studied the behavior of electrically charged particles (electrons) inside a vacuum tube in his well-known cathode ray tube experiment. A stream of negatively charged particles (electrons) traveled from the cathode (negative electrode) to the anode (positive electrode) when a voltage was applied across the tube. Thomson came to the conclusion that these particles were the basic building blocks of atoms.

The old belief that atoms were indestructible was refuted by Thomson's discovery of electrons within them, which also supported the notion of subatomic particles inside the atom. His "plum pudding" concept proposed that atoms had a neutral overall charge because electrons were contained within a positively charged "pudding" or matrix.

Later investigations, like those by Ernest Rutherford, helped to clarify our understanding of atomic structure and revealed the existence of a positively charged nucleus that contains protons as well as neutral particles known as neutrons. The existence of indivisible atoms was therefore not refuted by Thomson's experiment, but it did introduce the idea of subatomic particles within atoms, particularly electrons.

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Answer:

b. Acid rain falling on sidewalks

Explanation:

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Acid rain contains majorly carbonic acid [tex]H_2CO_3[/tex] which could react with the concrete that is used to make sidewalks. This chemical reaction, although varies based on the concrete's composition, usually gives off carbon dioxide owing to the acid's instability and leads to the weathering since the sidewalks start to wear out and subsequently break down.

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Answer:

Electrical energy is produced from oxidation reactions.

Explanation:

In fuel cells elecric energy is produced from the oxidation of reactants, that fuel is often Hydrogen, that is storaged in the fuel cell and then it just grabs oxygen from the air and converts that chemical reaction of oxidation in electric current.

Final answer:

It takes two half-lives, or 2.6 billion years, for 75% of Potassium-40 to decay to Argon, making (b) 2.6 billion years the correct option.

Explanation:

The decay of Potassium-40 (K-40) to Argon (Ar-40) follows the principles of radioactive decay and the concept of half-lives. The half-life is the time it takes for half of the original quantity of a radioactive isotope to decay. In this case, K-40 has a half-life of approximately 1.3 billion years. After one half-life, there would be 6 grams of K-40 and 6 grams of Ar-40. After two half-lives, which is 2.6 billion years, there would be 3 grams of K-40 and 9 grams of Ar-40. Since the question asks for the time it would take for 75% of the potassium-40 to be replaced by argon, we are looking for the time it takes to have only 25% of the original K-40 remaining.

Starting with 12 grams of K-40, after the first half-life, we would be left with 6 grams of K-40, which is 50%. After the second half-life, we would be left with 3 grams of K-40, which is 25% of the original amount. Therefore, it would take two half-lives for 75% of the potassium-40 to decay to argon, which equates to 2.6 billion years. The correct option is therefore (b) 2.6 billion years.

Answer:

false

Explanation:

Final answer:

Thermal expansion is the increase or decrease in size of a body due to a change in temperature. Solid metals undergo greater thermal expansion than liquids. This is because the closely packed atoms or molecules in solid metals are pushed farther apart by the increase in temperature, resulting in a larger size for the whole body.

Explanation:

Thermal expansion: Thermal expansion is the increase, or decrease, of the size (length, area, or volume) of a body due to a change in temperature. It occurs in all dimensions - length, area, volume - and is not limited to solid metals. However, solid metals undergo greater thermal expansion than liquids do. The increased thermal expansion in solid metals can be attributed to their closely packed atoms or molecules, which are pushed farther apart by the increase in temperature, resulting in a larger size for the whole body.

Answer:

Au3+

Explanation:

The standard cell notation for an electrolytic cell with aluminum and gold electrodes  Au(s)| Au³⁺  ||   Al³⁺| Al (s)

A device in which electrical energy is converted into chemical energy or chemical energy is converted into electric energy is called an Electrolytic cell

The electrolytic cell consists of two metallic electrodes and an electrolyte.

In this cell nomenclature, the electrode to the left of the salt bridge is always assumed to be the anode, and the accompanying half-equation is always stated as an oxidation , while right side is cathode and the half equation is Reduction.

Reaction at Anode: Au(s) → Au³⁺(aq) + 3e⁻  ..........(oxidation)

Reaction at Cathode: Au³⁺(aq) + 3e⁻ →Au(s) ..............(reduction)

The standard cell notation for an electrolytic cell with aluminum and gold electrodes

                         Au(s)| Au³⁺  ||   Al³⁺| Al (s)

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the scattering of light by particles in a mixture

Answer:The correct answer is option:'the scattering of light by particles in a mixture'.

Explanation:

Tyndall effect is defined as scattering of the light by the particles present in the mixture. A beam of the light passing through these mixture are visible to the human eyes. Generally colloidal mixture displays this type of effect. The name of his effect is named after the physicist named John Tyndall.

Hence, the correct answer is option:'the scattering of light by particles in a mixture'.

In the formation of one molecule of aluminum oxide (Al2O3), a total of 6 electrons are transferred from two aluminum atoms to three oxygen atoms to maintain electrical neutrality.

The formation of one molecule of aluminum oxide (Al2O3) involves the transfer of electrons between aluminum atoms and oxygen atoms. Each aluminum atom loses three electrons, becoming Al3+ ions, while each oxygen atom gains two electrons to become O2- ions. To maintain electrical neutrality, the compound must have equal numbers of positive and negative charges.

Therefore, to form one molecule of Al2O3, two aluminum atoms (2 Al) will lose a total of 6 electrons (2 Al × 3 e-), and three oxygen atoms will gain a total of 6 electrons (3 O × 2 e-) during the electron transfer process. The complete transfer involves 12 electrons changing places but, in effect, the number of electrons transferred is the total on one side of the reaction which is 6.

Answer:

The balanced equation for the reaction that occurs when Mg(OH)2 and HCl react together is:

Mg(OH)2+2HCl -------->MgCl2+2H20

Final answer:

The combustion of 1.00 mol of CH4 produces 44.01 grams of CO2, as one mole of methane combusts to create one mole of carbon dioxide, and the molar mass of CO2 is 44.01 g/mol.

Explanation:

The mass of CO2 produced by the combustion of 1.00 mol of CH4 can be calculated by looking at the balanced chemical equation:

CH4(g) + 2O2(g) → CO2(g) + 2H2O(l)

From the equation, it is clear that one mole of methane (CH4) produces one mole of carbon dioxide (CO2) upon combustion. To convert moles of CO2 to grams, we use the molar mass of CO2, which is 44.01 g/mol.

Calculation:

1.00 mol CH4 × (44.01 g CO2 / 1 mol CO2) = 44.01 g CO2

Therefore, the combustion of 1.00 mol of CH4 will produce 44.01 grams of CO2.

Answer: After 20 seconds, 16 grams of unobtanium will be present, after 40 seconds, 8 grams of unobtanium will be present after 60 seconds, 4 grams of unobtanium will be present, after 80 seconds, 2 grams of unobtanium will be present and after 100 seconds, 1 grams of unobtanium will be present.

Explanation: Half life is the time in which half of the reaction is completed. Thus the half of the substance will be decomposed and half of it will remain.

Amount of the substance left after n half lives will be=[tex]\frac{A}{2^n}[/tex]

where A= initial amount of substance

n=no of half lives=[tex]\frac{\text{given time}}{\text{half life}}[/tex]

a) t= 20 seconds

no of half lives=[tex]\frac{20}{20}=1[/tex]

amount of the substance left after 1 half life will be=[tex]\frac{32}{2^1}[/tex]=16 g.

b)  t= 40 seconds

no of half lives=[tex]\frac{40}{20}=2[/tex]

amount of the substance left after 2 half lives will be=[tex]\frac{32}{2^2}[/tex]=8g.

c) t= 60 seconds

no of half lives=[tex]\frac{60}{20}=3[/tex]

amount of the substance left after 3 half lives will be=[tex]\frac{32}{2^3}=4g[/tex]

d) t= 80 seconds

no of half lives=[tex]\frac{80}{20}=4[/tex]

amount of the substance left after 4 half lives will be=[tex]\frac{32}{2^4}=2g[/tex]

e) t= 100 seconds

no of half lives=[tex]\frac{100}{20}=5[/tex]

amount of the substance left after 5 half lives will be=[tex]\frac{32}{2^5}=1g.[/tex]

The half-life of a radioactive element is defined as the time required by the specific isotope to decrease by half of its original value. The unobtanium after given time will be present as:

Half-life is the time required by the unobtanium is the half of the reaction is completed. Half of the substance will be decomposed, such that:

Amount of substance left n half-lives = [tex]\dfrac{\text A}{{2}^{\text n}}[/tex]

where A= initial amount of substance

Now,

n = number of half-lives = given time /half-life

Given,

1. Time = t = 20 seconds

2.Time = t = 40 seconds

3.Time = t = 60 seconds

4.Time = t = 80 seconds

5.Time = t = 100 seconds

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"11.46" moles of gas occupy 98 L at 2.8 atm pressure.

The equation characterizing the stages of hypothetical gasses stated mathematically involving combinations of empirical as well as physiological constants, is considered as Ideal gas equation.

According to the question,

Volume occupied, V = 98

Temperature, T = 292 k

Pressure, P = 2.8 atm

By using ideal gas equation, we get

→ PV = nRT

or,

→ n = [tex]\frac{PV}{RT}[/tex]

By substituting the above values, we get

      = [tex]\frac{2.8\times 98}{0.082\times 292}[/tex]

      = [tex]\frac{274.4}{23.944}[/tex]

      = [tex]11.46[/tex]

Thus the above answer is appropriate.

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Q = m*C*dT

m = mass

C = specific heat capacity

dT = Temperature change

Q = heat evolved

Heat lost by metal is equal to the sum of heat taken up by water and vessel. Since water is taken in the vessel so

the initial and final temperatures would be same for vessel and water...

Q = 94.7 *0.237 *(22.63 - 348.25) = 7308.18 Joules = 7.3 KJ

Heat lost by silver = 7.3 KJ

Heat absorbed by water = 143.6*4.18*(22.63 - 13.97) = 5.2 KJ

Gibbs free energy (G) determines if reaction will proceed spontaneously.
ΔG = ΔH - T·ΔS.
ΔG - changes in Gibbs free energy.
ΔH - changes in enthalpy.
ΔS - changes in entropy.
T is temperature in Kelvins.
When ΔS < 0 (negative entropy change) and ΔH > 0 (endothermic reaction), the process is never spontaneous (ΔG> 0).

Answer:

reaction is nonspontaneous under standard conditions at all temperatures.

Explanation:

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