Here, do the following: (1) Name three professions/careers/jobs/situations, where knowing exactly how much of something that you start with and keeping things in balance is extremely important. (2) Name the importance of balance in that job/situation and finally, (3) name one bad thing that can happen if balance is not maintained

Example Job/Situation
Avery adulting with his digital wallet
Importance of Measurement for Job/ Situation 1:
Not doing this well can lead to an eviction, past due bills, and bad credit
What bad thing could happen if things are not kept in balance for Job/Situation 1?
Credit could decrease, he could get evicted, his heat will not work due to non-payment


.
Your Turn:
Job/Situation 1:


Importance of Measurement for Job/ Situation 1:


What bad thing could happen if things are not kept in balance for Job/Situation 1?


Job/Situation 2:


Importance of Measurement for Job/Situation 2:


What bad thing could happen if things are not kept in balance for Job/Situation 2?


Job/Situation 3:


Importance of Measurement for Job/Situation 3:


What bad thing could happen if things are not kept in balance for Job/Situation 3?

Labels for substances containing more than 0.3% of formaldehyde must specifically state that they contains formaldehyde.

This is because formaldehyde is classified as a hazardous substance and exposure to high concentrations can pose health risks. Therefore, substances containing more than 0.3% of formaldehyde must be clearly labeled to inform consumers and users about the presence of this chemical. The label may include phrases such as "Contains formaldehyde" or "Formaldehyde content > 0.3%," ensuring that individuals are aware of its presence and can take appropriate safety precautions.

Hence, substances containing more than 0.3% of formaldehyde must state that they contains formaldehyde.

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As per the given details, none of the statements are true. The correct option is D.

None of the statements supplied accurately describe the strategies or relationships noted.

It is essential to notice that mobile respiration is a complicated metabolic procedure that includes the breakdown of glucose to provide ATP (adenosine triphosphate), the number one strength currency of cells. Vitamin K isn't always a byproduct of cell respiration.

Niacin and riboflavin deficiencies may have diverse results on mobile procedures, however they do no longer especially reason issues in producing electron companies for mobile breathing.

The B-diet family plays essential roles in cellular metabolism, however glycogen synthesis isn't always without delay dependent on B-nutrients. Therefore, not one of the statements furnished are true.

Thus, the correct option is D.

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The methods that are used to extract the following metals ahev been explained as follows:

There are different ways in which metals can be extracted from the soil or other compounds. For instance, Aluminum is a metal that is extracted by electrolysis of a molten ionic compound.

Gold is obtained from the soil in its raw form and iron is extracted by reduction with carbon. Copper oxide is extracted by reduction with hydrogen.

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In the given reaction, hydrogen gas (H₂) and chlorine gas (Cl₂) combine to form hydrogen chloride gas (HCl). The equilibrium constant expression, which helps us determine the concentration of HCl at equilibrium, is written as Kg = [HCl]² / ([H₂][Cl₂]).

In this case, the equilibrium constant (Kg) is given as 50.0. Initially, we have 1.00 mole of H₂ gas and 1.00 mole of Cl₂ gas in a 0.50-liter container. To find the concentration of HCl at equilibrium, we can set up the following equation using the equilibrium constant expression:

50.0 = [HCl]² / ([H₂][Cl₂])

We know that the initial concentrations of H₂ and Cl₂ are both 1.00 mole divided by the volume of the container, which is 0.50 liters, giving us a concentration of 2.00 M.

Substituting these values into the equation, we have:

50.0 = [HCl]² / (2.00 - x)(2.00 - x)

To solve this equation, we can rearrange it as a quadratic equation:

[HCl]² = 50.0 * (2.00 - x)(2.00 - x)

Simplifying further:

[HCl]² = 100.0 * (2.00 - x)(2.00 - x)

To find the value of x, we solve this quadratic equation. The solutions to the equation are x = -1.56 and x = 1.56. However, since a negative value for x does not make physical sense in this context, we can conclude that x = 1.56.

Thus, the concentration of HCl at equilibrium, [HCl], is equal to 2x, which is 2 times 1.56, resulting in [HCl] = 3.12 M.

The connection between increasing carbon dioxide and increasing temperature is: carbon dioxide absorbs heat from the sun and traps it in earth's atmosphere. Since the heat cannot escape, it causes the earth's temperature to increase which is the first option.

When carbon dioxide (CO₂) and other greenhouse gases are present in the atmosphere, they act as a natural blanket, allowing sunlight (solar radiation) to pass through and reach the Earth's surface. Some of this solar radiation is absorbed by the Earth's surface, while the rest is reflected back towards space as heat (infrared radiation). However, greenhouse gases like carbon dioxide have the property of absorbing and re-emitting infrared radiation.

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Answer: Booting up the computer: When you turn on the computer, it requires a burst of energy to start up the various components and initialize the operating system.

Explanation:

Answer:

Explanation:

Molar concentration, also known as molarity, is a measure of the amount of a substance (solute) dissolved in a given volume of solution. It is expressed in moles of solute per liter of solution (mol/L or M).

a) The chemical equation for the dissociation of acetic acid (CH3COOH) in water can be written as:

CH3COOH + H2O ⇌ CH3COO- + H3O+

b) The Ka expression for this reaction represents the acid dissociation constant and can be written as:

Ka = [CH3COO-][H3O+] / [CH3COOH]

In this expression, [CH3COO-] represents the concentration of acetate ions, [H3O+] represents the concentration of hydronium ions (formed from the dissociation of water), and [CH3COOH] represents the concentration of acetic acid.

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The concentration of excess tetraoxosulphate (IV) acid in solution A is 0.192 mol/dm³.

Average titre value = 19.60 cm³

Concentration of NaOH in solution B = 0.096 mol/dm³

Volume of solution B = 25 cm³ = 25/1000 dm³ = 0.025 dm³

The balanced equation for the reaction between NaOH and H₂SO₄ is:

2 NaOH + H₂SO₄ → Na₂SO₄ + 2 H₂O

From the equation, we can see that 2 moles of NaOH react with 1 mole of H₂SO₄.

Therefore, the moles of H₂SO₄ in solution B can be calculated as:

Moles of H₂SO₄ = 2 × Moles of NaOH

= 2 × 0.096 mol/dm³

= 0.192 mol/dm³

Since the average titre value is the volume of solution A needed to react with solution B, the moles of H₂SO₄ in solution A is also 0.192 mol/dm³.

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To determine the concentration of H2SO4, we can use the concept of molarity (M) and the equation:

M1V1 = M2V2

where:

M1 = concentration of NaOH (in this case, 1.90 M)

V1 = volume of NaOH used (in this case, 38.70 cm^3)

M2 = concentration of H2SO4 (what we're trying to find)

V2 = volume of H2SO4 used (in this case, 10.30 cm^3)

Rearranging the equation, we have:

M2 = (M1 * V1) / V2

Substituting the given values:

M2 = (1.90 M * 38.70 cm^3) / 10.30 cm^3

M2 ≈ 7.12 M

Therefore, the concentration of H2SO4 is approximately 7.12 M.

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Answer:

Heat energy will flow from the plastic sphere to the water. This is because heat energy always flows from a warmer object to a cooler object.

Explanation:

In this case, the plastic sphere has a higher temperature of 85 °C, while the water has a lower temperature of 15 °C. Therefore, heat energy will naturally flow from the plastic sphere to the water until both objects reach thermal equilibrium, where they have the same temperature. As a result, the plastic sphere will cool down and the water will warm up until they reach the same temperature.

For the bronze figure that has a volume of 225 mL and a density of 7.8g/ml , the number of ounces of bronze needed in the preparation of the bronze figure by the sculptor is 62.6113 ounces

By using the formula,

ρ = [tex]\frac{M}{V}[/tex]

ρ = Density of the substance in g/ml

M = Substance's mass in g

V = Volume of the substance in ml

Given,

volume of  bronze figure = 225 mL

density of  bronze figure  = 7.8 g/mL

then, the mass of the bronze required to make the bronze  figure in grams

                  = density of  bronze figure ×  volume of   bronze figure    

                  =   7.8 g/mL  ×   225 mL  

                  =    1775 g

1 gram = 0.035274 ounce

then, the mass of the bronze required to make the bronze  figure in ounces,

= 1775 × 0.035274

= 62.6113 ounces

Therefore, the number of ounces of bronze needed in the preparation of the bronze figure by the sculptor  is 62.6113 ounces

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Answer:

Certainly! Here are three reasons why glass apparatus are still widely used in laboratory experiments, despite the fact that they can break easily:

1. Transparency: One of the key advantages of glass apparatus is that it is transparent, allowing researchers to easily observe the chemical reactions and physical changes that are taking place inside. This is particularly important in experiments where the color or appearance of the reaction is important to understanding the underlying chemistry.

2. Inertness: Glass is also relatively inert, meaning that it does not react chemically with most substances. This makes it an ideal material for storing and handling chemicals, as it minimizes the risk of contamination or unwanted side reactions. Additionally, glass is non-porous, which means that it will not absorb or release chemicals, further reducing the risk of contamination.

3. Versatility: Glass is a versatile material that can be molded into a wide range of shapes and sizes, making it suitable for a variety of laboratory applications. Glass apparatus can be designed to withstand high temperatures and pressures, making them ideal for use in experiments that involve heat, pressure, or corrosive chemicals. Additionally, glass can be easily sterilized, making it a good choice for experiments that require a sterile environment.

Answer:

Glass is resistant to high temperatures and many strong chemicals. Also, it is transparent, so you can see reactions as they occur.

Explanation:

Glass is nonreactive, so it is useful for a wide variety of laboratory purposes. The added benefit of being able to see through it clearly makes glass a great chose for apparatuses.

The pH of the solution, determined by the hydrogen electrode coupled with the saturated calomel electrode, is approximately 9.53.

To find the pH of the solution using a hydrogen electrode coupled with a saturated calomel electrode, we can utilize the Nernst equation, which relates the measured cell potential to the concentration of hydrogen ions in the solution. The Nernst equation is given by:

E = E° - (0.0592/n) * log[H+]

Where E is the measured cell potential, E° is the standard cell potential, n is the number of electrons transferred in the half-reaction (which is 2 for the hydrogen electrode), and [H+] is the concentration of hydrogen ions.

In this case, the emf of the combined cell is given as 0.523 V. Since the saturated calomel electrode (SCE) is the reference electrode, we can consider its standard cell potential (E°) to be 0.241 V at 25 degrees Celsius.

0.523 V = 0.241 V - (0.0592/2) * log[H+]

Simplifying the equation:

0.523 V - 0.241 V = -0.0296 * log[H+]

0.282 V = -0.0296 * log[H+]

Dividing both sides by -0.0296:

log[H+] = -0.282 V / -0.0296

log[H+] ≈ 9.53

Taking the antilog (base 10) of both sides:

[H+] ≈ 10^9.53

[H+] ≈ 3.2 × 10^9 M

Therefore, the pH of the solution, determined by the hydrogen electrode coupled with the saturated calomel electrode, is approximately 9.53.

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250 L of 5.0% w/v glucose solution can be prepared using 125 g of glucose.

w/v = [ mass of solute (g) / volume of solution (mL) ] × 100

5.0 % w/v = [ 125 g / volume of solution (mL) ] × 100

volume of solution (mL) = [ 125 g / 5.0 % w/v ] x 100

volume of solution (mL) = [ 125 g / (5.0 / 100) ] x 100

volume of solution (mL) = [ 125 g / 0.05 ] x 100

The approximate mass of CO2 dissolved in the alcoholic drink is approximately 52.81 grams.

To calculate the approximate mass of CO2 dissolved in the alcoholic drink, we need to consider the mole fractions and the molecular weights of water (H2O), ethanol (C2H5OH), and carbon dioxide (CO2).

Given:

Mass of H2O = 216.0 g

Mass of ethanol (C2H5OH) = 9.2 g

Mole fraction of water (H2O) = 0.9

First, let's calculate the moles of water and ethanol in the drink:

Moles of H2O = (mass of H2O) / (molar mass of H2O)

Moles of ethanol (C2H5OH) = (mass of ethanol) / (molar mass of C2H5OH)

Next, we can calculate the moles of CO2 present in the drink using the mole fraction of water:

Moles of CO2 = (moles of H2O) * (mole fraction of CO2)

Finally, we can determine the mass of CO2 by multiplying the moles of CO2 by its molar mass:

Mass of CO2 = (moles of CO2) * (molar mass of CO2)

The molar masses of the compounds are as follows:

Molar mass of H2O = 18.015 g/mol

Molar mass of C2H5OH = 46.069 g/mol

Molar mass of CO2 = 44.01 g/mol

Performing the calculations, we find:

Moles of H2O = 216.0 g / 18.015 g/mol ≈ 11.99 mol

Moles of ethanol (C2H5OH) = 9.2 g / 46.069 g/mol ≈ 0.20 mol

Moles of CO2 = (11.99 mol) * (1 - 0.9) ≈ 1.20 mol

Mass of CO2 = (1.20 mol) * (44.01 g/mol) ≈ 52.81 g

Therefore, the approximate mass of CO2 dissolved in the alcoholic drink is approximately 52.81 grams.

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The Henderson-Hasselbalch equation  can be given as

[tex]p^{H}[/tex] = [tex]pK_{a}[/tex] + log [tex]\frac{[A^{-}] }{[HA]}[/tex]

This equation relates the [tex]p^{H}[/tex] , dissociation constant and concentration of acid and its conjugate base or base and its conjugate acid.

The Henderson-Hasselbalch equation can be derived as,

Let us consider the ionization of weak  acid,

HA  + [tex]H_{2}O[/tex] ⇄ [tex]H^{+}[/tex] + [tex]A^{-}[/tex]

The dissociation constant [tex]K_{a}[/tex] can be given as

[tex]K_{a}[/tex] =   [tex]\frac{[H^{+}][A^{-}] }{[HA]}[/tex]

Rearranging  the equation,

[tex][H^{+}][/tex] = [tex]K_{a}[/tex] ×[tex]\frac{[HA]}{[A^{-}] }[/tex]

Taking log on both sides,

log[tex][H^{+}][/tex] =log{ [tex]K_{a}[/tex] ×[tex]\frac{[HA]}{[A^{-}] }[/tex])

log [tex][H^{+}][/tex] = log [tex]K_{a}[/tex] +log [tex]\frac{[HA]}{[A^{-}] }[/tex]

multiplying the whole equation on both the sides

-log [tex][H^{+}][/tex] = - log [tex]K_{a}[/tex]  - log [tex]\frac{[HA]}{[A^{-}] }[/tex]

we know that -log [tex][H^{+}][/tex] = [tex]p^{H}[/tex] and  - log [tex]K_{a}[/tex]  =p[tex]K_{a}[/tex]  

then, the equation can be rewritten as

[tex]p^{H}[/tex] = p[tex]K_{a}[/tex] - log [tex]\frac{[HA]}{[A^{-}] }[/tex]

[tex]p^{H}[/tex] = p[tex]K_{a}[/tex] + log[tex]\frac{[A^{-}] }{[HA]}[/tex]

[tex][A^-}][/tex] =  Concentration of conjugate base

[HA] = Concentration of weak acid,

So the Henderson-Hasselbalch equation can be modified  as,

[tex]p^{H}[/tex] = [tex]pK_{a}[/tex] + log([Conjugate base]/ [weak acid])

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The mass of the carbon dioxide is  49.72 g from the calculation done.

The phrase "mole fraction," which is often referred to as "molar fraction" or "amount fraction," is used to describe the proportions of a mixture's components. It is an intangible quantity that expresses the proportion between the moles of a given component and the total moles in the combination.

We know that;

Number of moles of ethanol = 9.2/46 g/mol

= 0.2 moles

Now;

Number of moles of water = 216.0 g/18 g/mol

= 12 moles

Mole fraction of water = Number of water/ Total number of moles

0.9 = 12/12 + 0.2 + x

0.9(12.2 + x) = 12

10.98 + 0.9x = 12

x = 1.13 moles

Now;

Moles = mass/Molar mass

1.13 = x/44

x = 49.72 g

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The correct protein pairing is:

Structural proteins provide the body tensile strength. Option B

This pairing is appropriate since structural proteins like collagen and keratin are known for their function in giving tissues and bodily structures stability and strength. They provide the tensile strength of several biological components, such as bones, tendons, ligaments, and skin.

Globular proteins are not specifically active in their secondary structure. Globular proteins have complex three-dimensional structures and are known for their functional diversity.

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If 100 s of heat is added to a system and 0.100 ks of work is done by the system, then the value of ΔE or DE (change in internal energy) is 200 J, which is in option A. This is as per the first rule of thermodynamics.

ΔE = Q - W

ΔE (change in internal energy)

Given that 100 J (joules) of heat is added to the system (Q = 100 J) and 0.100 kJ (kilojoules) of work is done by the system (W = -0.100 kJ), we need to ensure that the units are consistent.

Since 1 kJ = 1000 J, we can convert the work done to joules:

W = -0.100 kJ = -0.100 × 1000 J = -100 J

Now one can substitute the values into the equation:

ΔE = Q - W

= 100 J - (-100 J)

= 100 J + 100 J

= 200 J

Therefore, the value of ΔE (change in internal energy) is 200 J.

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complete question is below

if 100s of heat is added to a system and 0.100ks of work is done by the system, what is the value of DE​

A. 200 j

B.50 j

C.2 j

D. 10000j

If anyone adds 1.65 L of water to 112 grams of sodium acetate) to get 1697 ml of solution. Then, the percent mass by volume (% m/v) of sodium acetate in this solution is 6.59.

The percent mass by volume (% m/v) of sodium acetate in the solution is calculated as below,

the volume of water added to the solution from liters (L) to milliliters (ml): 1.65 L = 1650 ml

mass of sodium acetate by the volume of the solution:

mass of sodium acetate = 112 g

volume of solution = 1697 ml

mass/volume (g/ml) = 112 g / 1697 ml

The % mass by volume (% m/v) by multiplying the mass/volume by 100:

% m/v = (mass/volume) × 100

Here, % m/v = (112 g / 1697 ml) × 100 = 6.59.

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Based on the principle of original horizontality, geologists conclude that layers of sedimentary rock that have been tilted must have been subjected to tectonic forces. Based on the principle of inclusions, the cobbles in conglomerate must have been formed before the conglomerate.

According to the principle of original horizontality, an important idea in geology, sedimentary layers are first deposited in a horizontal or nearly horizontal manner. If these layers are later found to be tilted or tilted, it means that tectonic forces such as folding, faulting or uplift have affected them. Geologists can use this theory to better understand the processes that have shaped the Earth's crust over time and the history of rock formations.

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To solve for x, we will substitute the given values into the equation and perform the calculations:

x = (4.3 × 10^3 M^−2 s^−1) (0.45M)^3

First, let's simplify the expression (0.45M)^3:

(0.45M)^3 = (0.45)^3 * M^3

= 0.091125 * M^3

Now we substitute this value back into the original equation:

x = (4.3 × 10^3 M^−2 s^−1) * (0.091125 * M^3)

Next, we simplify the expression (4.3 × 10^3 M^−2 s^−1) * (0.091125 * M^3):

x = (4.3 × 10^3) * (0.091125) * M^(-2 + 3) * s^(-1)

= (4.3 × 10^3) * (0.091125) * M^1 * s^(-1)

= 391.875 * M * s^(-1)

Thus, the simplified expression for x is:

x = 391.875 * M * s^(-1)

Please note that the unit of x is Molar per second (M/s) since we have multiplied M with s^(-1).

a. Titration Curve:

On the x-axis, label it as "Volume of HCl added (mL)"

On the y-axis, label it as "pH"

b. Equivalence Point:

The equivalence point is the point in the titration where the moles of acid (HCl) added are stoichiometrically equivalent to the moles of base (unknown base) present initially. In the given data, the equivalence point can be estimated to be around 25.0 mL of HCl added. This is where the pH drops dramatically from 7.88 to 5.28, indicating the neutralization of the base.

c. Calculation of Kb Value:

To determine the Kb value, we need to find the pOH at half-neutralization, where half the volume of the equivalent point has been reached. In this case, the half-neutralization volume is 12.5 mL (half of 25 mL).

From the data, we can observe that at 12.5 mL of HCl added, the pH is 9.26.

pOH = 14 - pH = 14 - 9.26 = 4.74

pOH = -log[OH-]

[OH-] = 10^(-pOH)

[OH-] = 10^(-4.74)

To find [OH-] in moles per liter (M), we need to convert mL to L.

[OH-] = 10^(-4.74) mol/L

Now, since we know that at the equivalence point, the concentration of the acid (HCl) is 0.10 M, we can use the stoichiometry of the reaction to determine the concentration of the base (unknown base).

From the balanced equation:

HCl + OH- → H2O + Cl-

1 mole of HCl reacts with 1 mole of OH-

0.10 M (HCl) = [OH-] M (unknown base)

Therefore, Kb = [OH-][unknown base] / [base]

Kb = (10^(-4.74) mol/L)(0.10 M) / (0.10 M - 10^(-4.74) M)

Simplify and calculate Kb.

c. Selection of Indicator:

Based on the given pKa ranges of the indicators, the indicator phenolphthalein (pKa range: 8.3 - 10.0) would be appropriate for this titration. The reason is that the pH at the equivalence point is expected to be around 7, which is well within the range of phenolphthalein's color change. Bromophenol Blue and Methyl Red have lower pKa values and would not be suitable for indicating the equivalence point in this particular titration.

d. Calculation of Molarity and % Ionization of the Weak Base Solution:

To calculate the molarity of the weak base solution, we can use the Henderson-Hasselbalch equation:

pH = pKa + log([A-]/[HA])

At the half-neutralization point, [A-] = [HA], and the pH is 9.26.

9.26 = pKa + log([A-]/[HA])

The pKa can be determined using the pOH at half-neutralization:

pKa = 14 - pOH = 14 - 4.74 = 9.26

9.26 = 9.26 + log([A-]/[HA])

log([A-]/[HA]) = 0

[A-]/[HA] = 10^0 = 1

Since [A-] = [HA], the concentration of the weak base (before titration) is equal to the concentration of its conjugate acid.

Therefore, the molarity of the weak base solution is 0.10 M.

To calculate the % ionization of the weak base, we can use the formula:

% Ionization = ([A-]/[HA]) × 100

% Ionization = (1/0.10) × 100

% Ionization = 1000%

Note: The % ionization may exceed 100% in cases where the concentration of the conjugate acid is very small compared to the concentration of the weak base.

We can see here that the best fuel is the one that produces the most heat per unit mass. In this case, the fuel that produces the most heat per unit mass is methanol.

Fuel is a substance that is used to produce energy through combustion or other chemical reactions. It is commonly utilized to power various forms of transportation, generate heat or electricity, and operate machinery and appliances.

The results of the experiment are shown below:

Fuel            Mass (g)      Heat produced (J)       Heat per gram (J/g)

Methanol 1.0                          350                   350

Ethanol         1.0                          250                   250

Propane         1.0                          200                   200

Butane         1.0                          150                            150

Pentane         1.0                          100                            100

It is important to note that the results of this experiment are only a measure of the heat produced by the fuels.

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Increasing the concentration of CO  decreases the equilibrium  concentration of oxygen and increases the concentration of CO₂, increasing the concentration of CO₂ increases the concentration of CO and O₂.

Chemical equilibrium refers to the state of a system in which the concentration of the reactant and the concentration of the products do not change with time, and the system does not display any further change in properties.

It is the state of a reversible reaction where the rate of the forward reaction equals the rate of the reverse reaction. While a reaction is in equilibrium the concentration of the reactants and products are constant.

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Answer:

1 and 2 are identical

Explanation:

Draw zigzag project

A compound is named by combining the names of its cation and anion.

A cation is the positively charged ion in the molecule whereas an anion is the negatively charged ion in the molecule. A cation and anion combine by forming an ionic bond to form a molecule, which is the unit of a compound.

Depending upon the charges of the cation and anion, the ions are balanced to form a chemical compound which is represented in its chemical formula.

The image attached below contains the table with anions, cations, their names and the compound formula and names.

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