If a gas at 25oC occupies 3.60 L at a pressure of 2.50 atm, what will be its volume at a pressure of 1.00 atm if the temperature does NOT change?

Answer: lithium + oxygen Right arrow. lithium oxide

lithium + oxygen proper arrow. lithium oxide This equation indicates lithium oxide is formed from the reaction between oxygen and lithium.

Lithium oxide is used as a flux in ceramic glazes and creates blues with copper and pinks with cobalt. Lithium oxide reacts with water and steam, forming lithium hydroxide, and needs to be isolated from them.

Lithium Oxide is an extraordinarily insoluble thermally stable Lithium source suitable for glass, optic, and ceramic programs. Lithium oxide is a white stable also referred to as lithia, it is produced whilst lithium metallic burns inside the presence of oxygen.

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Answer:

Vapor pressure of solution is 736mmHg

Explanation:

Vapor pressure of an ideal solution follows Raoult's law:

[tex]P_{solution} = X_{solvent}P_{solvent}[/tex]

Where P is vapor pressure and X is mole fraction

Moles of glucose are:

48.4g × (1mol / 180.156g) = 0.2687mol glucose

Moles of water:

151.2g × (1mol / 18.1g) = 8.354 mol water

Thus, mole fraction of water (Solvent) is:

8.354 mol / (8.354 mol + 0.2687mol) = 0.9688

Vapor pressure of a solvent at boiling point is equal to atmospheric pressure (760mmHg). Replacing in Raoult's law:

[tex]P_{solution} = 0.9688*760mmHg[/tex]

Vapor pressure of solution is 736mmHg

The vapor pressure of the solution will be "736 mmHg".

According to the question,

Sample of glucose = 48.4 g

Mass of water = 151.2 g

Temperature = 100°C

Now,

Moles of glucose will be:

= 48.4 × ([tex]\frac{1 \ mol}{180.156}[/tex])

= 0.2687 mol

Moles of water will be:

= 151.2 × ([tex]\frac{1 \ mol}{18.1}[/tex])

= 8.354 mol

Water's moles fraction will be:

= [tex]\frac{Moles \ of \ water}{Moles \ of \ water +Glucose}[/tex]

By substituting the values,

= [tex]\frac{8.354}{8.354+0.2687}[/tex]

= 0.9688

hence,

By using Raoult's Law,

→ [tex]P_{solution}[/tex] = [tex]X_{solvent} P_{solvent}[/tex]

By substituting the values,

                = 0.9688 × 760

                = 736 mmHg

Thus the above solution is correct.55

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Answer:

Explanation:

q = (mass) (temp change) (specific heat)

q = (10000 g) (40 °C) (0.385 J/g⋅°C) = 154000 J = 154 kJ

154 kJ / 2220 kJ/mol = 0.069369369 mol

0.069369369 mol times 44.0962 g/mol = 3.06 g (to three sig figs)

answer choice 4

The heat of combustion ([tex]\Delta[/tex]Hc0) is the amount of energy released as heat when a compound completely burns with oxygen under standard conditions.

3.05988g. grams of propane must be burned to raise the temperature of a 10.0 kg block of copper from 25.0°C to 65.0°C.

q=m*c*(change of T)

q=10000g(0.385J/g*c)*(65.0C-25.0C)or (338.2 K-298.2K)

q=154000J

154000J*(1 mol/2220 KJ)=69.36936 x [tex]10 ^-3[/tex] mol

here's where I'm stuck

0.069369 mol

and i know that for every 1 mol there is 44.11g of C3H8.

0.069369 mol* (44.11g C3H8)/1mol = 3.05988g.

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For a reaction system at equilibrium, LeChatelier's principle can be used to predict the "effect of a stress on the system".

Option: C

Explanation:

Le Chatelier's theory can be implemented to forecast a system's behavior due to variations in pressure, temperature, or concentration that will lead in predictable and contested variations in the system adjustments to establish a new state of equilibrium. This means that adding heat to a process would favor the endothermic path of a reaction, because this decreases the amount of heat generated in the system.

Here shift in equilibrium take place when volume increase, the total pressure decreases, which have potential to reverse the reaction, while on increasing pressure of system, the total volume decreases of the gaseous system, which can shift an equilibrium in the direction of the fewer molecules.

For a reaction system at equilibrium, the Le principle can be used to predict the effect of a stress on the system.

The Le principle is an observation about chemical equilibria of reactions. Le principle can be used to predict the effect of a stress like changing concentration of a substance has on a reaction system at equilibrium.

If the concentration of a reaction species is increased at constant Temperature and Volume, the equilibrium system will shift in the direction that reduces the concentration of that substance so we can conclude that the Le principle can be used to predict the effect of a stress on the system.

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Answer:

Liquid B because of its higher vapor pressure due to the fact that evaporation rate is directly proportional to vapor pressure

Explanation:

The vapor pressure of  liquid at equilibrium is a function to the liquid's rate of evaporation. The evaporation rate and hence the vapor pressure is a measure of the propensity of the particles  of the liquid to leave the surface of the liquid and exist as vapor directly above the liquid. As high evaporation rate leads to high vapor pressure, a liquid with a higher vapor pressure will evaporate faster than one with a lower vapor pressure at the same temperature and pressure.

Therefore, liquid B with a vapor pressure of 18.04 kPa at 40° C will evaporate faster than liquid A with a lower vapor pressure of 7.37 kPa at the same 40°C.

Liquid B with a higher vapor pressure of 18.04 kPa at 40°C would evaporate faster than liquid A with 7.37 kPa, as higher vapor pressure indicates that the liquid is more volatile and its molecules can more easily escape into the gas phase.

At 40°C, between liquid A with a vapor pressure of 7.37 kPa and liquid B with a vapor pressure of 18.04 kPa, liquid B would evaporate faster. This is because vapor pressure is a measure of the tendency of molecules to escape from a liquid and enter the gas phase. A higher vapor pressure indicates that molecules can break away from the surface of the liquid more easily, which is indicative of a more volatile liquid. Therefore, liquid B, with its higher vapor pressure at the same temperature, is the more volatile and will evaporate more rapidly than liquid A.

Vapor pressure of a liquid is directly related to its intermolecular forces; liquids with weaker intermolecular forces have higher vapor pressures, and hence they evaporate faster. Conversely, greater intermolecular forces result in a lower vapor pressure and slower evaporation rate. For volatile liquids in a mixture, adding their partial pressures yields the total vapor pressure of the mixture

Answer:

The greater the change in free energy (ΔG0′), and the greater the energy released

Explanation:

Recall that the change in free energy is given by:

∆G°'= nFE°'

But E° is given by E°acceptor - E°donor

Hence the greater the difference between E°acceptor and E°donor, the greater the value of E° and consequently the greater the value of ∆G° and the energy released.

Note: E°acceptor and E°donor refer to reduction potentials of donor and acceptor

Answer:

Im 90% sure its 3.

Explanation:

Answer:

4

Explanation:

Answer:

The answer to your question is 0.41 moles

Explanation:

Data

moles of NaCl = ?

mass of NaCl = 24 g

Process

To solve this problem just calculate the molar mass of NaCl, and remember that the molar mass of any substance equals to 1 mol.

1.- Calculate the molar mass

NaCl = 23 + 35.5 = 58.5 g

2.- Use proportions and cross multiplication

               58.5 g of NaCl ------------------- 1 mol

               24.0 g               ------------------- x

                     x = (24 x 1) / 58.5

                     x = 0.41 moles

Answer:

0.64 L

Explanation:

Recall that

n= CV where n=m/M

Hence:

m/M= CV

m= given mass of solute =152g

M= molar mass of solute

C= concentration of solute in molL-1 = 1.5M

V= volume of solute =????

Molar mass of potassium permanganate= 158.034 g/mol

Thus;

152 g/158.034 gmol-1= 1.5M × V

V= 0.96/1.5

V= 0.64 L

Answer:

The volume of KMnO4 produced is = 16,013.7 Litres

Explanation:

Concentration = mass (in moles) ÷ volume (in litres)

1g = 158.03 moles

152g = 24,020.56 moles of KMnO4

1.5 M = mass (in moles) ÷ vol

⇒ Volume =  [tex]\frac{24,020.56} {1.5}[/tex]

= 16,013.7 Litres

Answer : The new pressure if the volume changes to 560.0 mL is, 280 mmHg

Explanation :

According to the Boyle's, law, the pressure of the gas is inversely proportional to the volume of gas at constant temperature and moles of gas.

[tex]P\propto \frac{1}{V}[/tex]

or,

[tex]P_1V_1=P_2V_2[/tex]

where,

[tex]P_1[/tex] = initial pressure = 560.00 mmHg

[tex]P_2[/tex] = final pressure = ?

[tex]V_1[/tex] = initial volume = 280 mL

[tex]V_2[/tex] = final volume = 560.0 mL

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

[tex]560.00mmHg\times 280 mL=P_2\times 560.0 mL[/tex]

[tex]P_2=280mmHg[/tex]

Therefore, the new pressure if the volume changes to 560.0 mL is, 280 mmHg

Answer:

6.58 atm total

3.29 atm NO2

3.29 atm O2

Explanation:

Balanced equation:

O3 + NO → NO2 + O2

There are equal numbers of moles of both reactants, so neither is in excess and either could be considered the limiting reactant.

( 1.30 mol NO) x (1 mol NO2 / 1 mol NO) =  1.30 mol NO2

( 1.30 mol NO) x (1 mol O2 / 1 mol NO) =  1.30 mol O2

Total pressure by using the formula;

P = nRT / V

= ( 1.30 mol +  1.30 mol) x (0.08205746 L atm/K mol) x (401.0 K) / (13.0 L)  

= 6.58 atm

Partial pressure for NO2;

(6.58 atm) x (1.30 mol NO2) / (1.30 mol + 1.30 mol)

= 3.29 atm NO2

Partial pressure for O2

6.58 atm total - 3.29 atm NO2

= 3.29 atm O2

1. The partial pressure of nitrogen dioxide ([tex]NO_2[/tex]) is equal to 3.29 atm.

2. The partial pressure of oxygen gas ([tex]O_2[/tex]) is equal to 3.29 atm.

3. The total pressure in the flask at the end of the chemical reaction is 6.58 atm.

Given the following data:

Scientific data:

To determine the partial pressure of each product and the total pressure in the flask at the end of the chemical reaction:

First of all, we would write a balanced chemical equation for the chemical reaction as follows:

                                  [tex]O_3 + NO \rightarrow NO_2+O_2[/tex]

Since the numbers of moles of reactants are equal, the total number of moles of products is:

[tex]n=1.3+1.3[/tex]

n = 2.6 moles

Now, we can find the total pressure in the flask at the end of the chemical reaction by using the ideal gas law equation;

[tex]PV=n RT[/tex]

Where;

Making P the subject of formula, we have;

[tex]P=\frac{nRT}{V}[/tex]

Substituting the parameters into the formula, we have;

[tex]P=\frac{2.6 \times 0.0821 \times 401}{13}\\\\P=\frac{85.597}{13}[/tex]

Total pressure, P = 6.58 atm.

Next, we would determine the partial pressure of each product:

[tex]Molefraction \;of \;a \;substance =\frac{No.\; of \; moles \;of \;substance}{Total \;no. \;of \; moles \;of \;substances}[/tex]

[tex]Molefraction \;of \;a \;substance =\frac{1.3}{2.6} \\\\Molefraction \;of \;a \;substance =0.5[/tex]

For [tex]NO_2[/tex]:

[tex]Partial \;pressure = Molefraction \times Total\;pressure\\\\Partial \;pressure = 0.5 \times 6.58[/tex]

Partial pressure of [tex]NO_2[/tex] = 3.29 atm.

For [tex]O_2[/tex]:

[tex]Partial \;pressure = Molefraction \times Total\;pressure\\\\Partial \;pressure = 0.5 \times 6.58[/tex]

Partial pressure of [tex]O_2[/tex] = 3.29 atm.

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Answer:

NH3 and NH4+

Explanation:

NH4+ is the conjugate acid of the base NH3.

The example of base-conjugate acid pair is B. NH3 and NH4+.

A base-conjugate acid pair simply means a pair that consist of two substances that only differ by the presence of a proton (H+).

In this case, the example of base-conjugate acid pair is NH3 and NH4+ because bNH4+ is the conjugate acid of the base NH3.

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Answer:

I got .146 g of water

Explanation:

Refer to this equation:

Q= mcΔt

Q= .545 J

c= 4.186 J/g

Δt= .892

plug in values:

.545 J = m(4.186 J/g)(.892°C)

simplify:

.545 J = m(3.734 J/g°C)

.146 g

Answer:

A. 1 AgNO3 + 1 KCl ⇒ 1 AgCl + 1 KNO3 double replacement

B. 1 H2O + 1 SO3 ⇒ 1 H2SO4 synthesis

C. 2 KI + 1 Cl2 ⇒ 2 KCl + 1 I2 single replacement

D. 2 NaHCO3 ⇒ 1 Na2CO3 + 1 H2O + 1 CO2 decomposition

E. 1 Zn + 2 HCl ⇒ 1 ZnCl2 + 1 H2 single replacement

F. 1 BaCl2 + 1 Na2SO4 ⇒ 1 BaSO4 + 2 NaCl double displacement

G. 1 C3H8 + 5 O2 ⇒ 3 CO2 + 4 H2O combustion

H. 2 Al + 3 CuCl2 ⇒ 2 AlCl3 + 3 Cu single displacement

Explanation:

Use algebra to make sure you have the same amount of each element on each side (Reactants and Products) and only change the coefficients of the compounds and elements!

double displacement: AB + CD ⇒ AD + CB

single replacement: AB + C ⇒ A + CB

decomposition: A ⇒ B + C

synthesis: A + B ⇒ C

combustion: any reaction that involve oxygen and don't follow any of the previous reactions

To balance a chemical reaction equation, the number of atoms of each element on both sides of the reaction equation must be the same.

A chemical reaction equation has a right hand side (reactants side) and a left hand side (products side). The reactants combine to give the products. The number of atoms of each element on the reactants side must be exactly the same as the number of atoms of the same element on the products side.

The balanced chemical reaction equation for each of the reactions is shown below;

If there is no molar coefficient written in front of any of the species then the molar is 1.

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Answer:

The answer to your question is 82g

Explanation:

Data

Molecule: Sodium acetate  Na(C₂H₃O₂)

Molar mass = ?

Process

Look for the atomic mass of each element, multiply this number by the subscript and add the results.

Sodium = 23 g

Carbon = 2 x 12 = 24 g

Hydrogen = 1 x 3 = 3 g

Oxygen = 2 x 16 = 32 g

Sum up the result

Molar mass = 23 + 24 + 3 + 32

                   = 82 g

Answer:

2.4 L

Explanation:

Given data:

Mass of LiF = 19.6 g

Molarity of solution = 0.320 M

Volume of water used = ?

Solution:

Number of moles = mass/molar mass

Number of moles = 19.6 g/ 26 g/mol

Number of moles = 0.75 mol

Volume required:

Molarity = number of moles/ volume in L

0.320 M = 0.75 mol /  volume in L

Volume in L = 0.75 mol  /0.320 M

      M = mol/L

Volume in L = 2.4 L

Answer:

5.03 moles

Explanation:

Find the molar mass of C5H12 and you will get 72.17 g/mol

Next to find the number of moles, you divide 362.8 by the molar mass and you get

(362.8 g)/(72.17 g/mol)= 5.03 moles

Answer:

The answer is 20.6 grams.

Explanation:

Molality describes the concentration of a solution. It can be defined as the number of moles of a solute dissolved in 1 kilogram of solvent. Then it is equal to the moles of solute (the substance that dissolves) divided by the kilograms of solvent (the substance used to dissolve):

[tex]Molality=\frac{number of moles of solute}{kilogram of solvent}[/tex]

The molality is expressed in units ([tex]\frac{moles}{kg}[/tex]).

So, you can apply the following rule of three with the solution being 0.5 molal: if in 1 kg of solution there are 0.5 moles of solute, in 0.4 kg (400 g, being 1kg = 1000g) how many moles of solute are there?

[tex]moles=\frac{0.4 kg*0.5 moles}{1 kg}[/tex]

moles=0.2 moles

Now, you know:

Then, The molar mass of sodium bromide NaBr is

NaBr= 23 g/mole + 80 g/mole= 103 g/mole

Now a new rule of three applies, if in 1 mole of sodium bromide there are 103 grams, in 0.2 mole how much mass is there?

[tex]mass=\frac{0.2 moles*103 grams}{1 mole}[/tex]

mass= 20.6 grams

The answer is 20.6 grams.

Answer:

39.446L

Explanation:

since helium is ideal gas, we can use PV = nRT

P = pressure

V = volume

n = moles

R = gas constant

T = temperature in Kelvin

we are solving for V

V = [tex]\frac{nRT}{P}[/tex]

C to K temp transfer: K = C + 273, so K = 290 since C = 17

our gas constant is 0.08206 atm L/mol K, this gas constant r will change depending on what unit of pressure you are using (mmHg, atm, etc).

plug and chug

V = [tex]\frac{(2.3mol)(290K)(\frac{0.08206 atmL}{molK}) }{1 atm}[/tex]

canceling out units

V = [tex]\frac{2.3 * 209 * 0.08206L}{1}[/tex] = 39.446

Answer:

B. Single Replacement

Explanation:

Single replacement:

It is the reaction in which one elements replace the other element in compound.

AB + C → AC + B

Chemical equation:

2HgO + Cl₂ → HgCl + O₂

This is the single replacement reaction. In this reaction chlorine replace the oxygen from mercury oxide and form mercury chloride.

Other options are incorrect because,

Decomposition reaction:

It is the reaction in which one reactant is break down into two or more product.

AB → A + B

Synthesis reaction:

It is the reaction in which two or more simple substance react to give one or more complex product.

A + B → AB

Double replacement:

It is the reaction in which two compound exchange their ions and form new compounds.

AB + CD → AC +BD

You purchase several rolls of fiberglass insulation and pay extra for installation. This is a service.

The majority of homes include fibreglass, an insulation substance made of incredibly thin glass fibres. It is frequently used in two forms of insulation: loose-fill and batts and rolls. Additionally, rigid boards or duct insulation are both options.

In accordance with the U.S. Department of Energy, manufacturers already make medium- and high-density fibreglass batt insulation materials with a little better R-Value than regular batts. Unfinished floors, ceilings, and walls can all be filled with fibreglass. It is set in place between beams, joists, and studs. You purchase several rolls of fiberglass insulation and pay extra for installation. This is a service.

Therefore, fiberglass insulation is a service.

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Answer:

1.24 atm is the new pressure

Explanation:

We may solve this question with the Ideal Gases Law that must be used, twice. → P . V = n . R . T

Total pressure = Partial pressure of gas A + Partial pressure of gas B

Total pressure = 0.298 atm + 0.589 atm → 0.887 atm

We convert the T° to Absolute value  → 55°C + 273 = 328K

0.887 atm . 9.80L = n . 0.082 . 328K

(0.887 atm . 9.80L) /(0.082 . 328K) = 0.323 moles

These are the moles from the initial mixture, but we add 0.130 moles

Total new moles are 0.323 + 0.130 = 0.453 moles

P = (0.453 mol . 0.082 . 328K) / 9.80L

P = 1.24 atm

Notice, that the pressure was increased. As we add a third gas, the pressure is correctly increased because the molecules from all of the gases   collide more with the walls of the vessel.

Answer:

      [tex][SOCl_2]=0.0218M[/tex]

Explanation:

The equations for a first order reaction are:

      [tex]\dfrac{d[A]}{dt}=-k[A][/tex]

      [tex][A]=[A_0]e^{-kt}[/tex]

      [tex]t\frac{1}{2}=\dfrac{\ln 2}{k}[/tex]

1. Calculate the constant of reaction, k:

Use the equation

                                [tex]t\frac{1}{2}=\dfrac{\ln 2}{k}[/tex]

     [tex]8.75h=\dfrac{\ln 2}{k}[/tex]

     [tex]k=\dfrac{\ln 2}{8.75h}[/tex]

     [tex]k\approx 0.0792168h^{-1}[/tex]

2. Calculate the concentration after 17.0 hours

Use the equation

                               [tex][A]=[A_0]e^{-kt}[/tex]

      [tex][SOCl_2]=0.0837M\cdot e^{-0.0792168h^{-1}\times 17.0h}[/tex]

      [tex][SOCl_2]=0.0218M[/tex]

Answer:

There are no caterpillars on the oak tree in winter. ... Some farmers spray their crops with chemicals to kill insects and weeds. ... Some farmers leave a strip of land around the edge of each field which they do not spray with chemicals.

Explanation:

Hope this help ;)

Farmers leaving unsprayed strips of land can increase partridge numbers due to safer habitats free from pesticides and better provision of food and nesting areas.

Leaving a strip of land around the edge of each field unsprayed with chemicals will likely increase the number of partridges on these farms for two main reasons.

Crop rotation is also a practice that allows farmers to improve soil fertility, diversify their crops, and reduce pesticide costs by breaking the cycle of weeds, insects, and diseases naturally.

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Answer:

180 g/mol

Explanation:

M(HC₉H₇O₄) = M(H) + 9M(C) + 7M(H) + 4M(O) = 1+ 9*12 +7*1 + 4*16= 180

The molar mass of Aspirin (C9H8O4) is calculated as 180.17 g/mol, by summing the individual contributions of the atomic masses of carbon, hydrogen, and oxygen.

The molar mass of acetylsalicylic acid, commonly known as Aspirin, can be calculated by adding the atomic masses of its constituent atoms. Aspirin has the molecular formula C9H8O4. To calculate the molar mass, we sum the atomic masses as follows:

Adding these contributions together, we get:

Molar mass of Aspirin (C9H8O4) = 108.09 + 8.08 + 64.00 = 180.17 g/mol

This value is slightly different from the reference value of 180.15 g/mol, likely due to rounding differences in the atomic masses used.

Answer:

mass = 172.78 grams Na₂CO₃(s) formed

Explanation:

6Na°(s) + Fe₂(CO₃)₃ => 3Na₂CO₃(s) + 2Fe°(s)

moles Na°(s) = 15g/23g/mol = 3.26 mole Na°(s)

From stoichiometry of reaction equation, 3.26 mole Na°(s) => 3/6(3.26) mole Na₂CO₃(s) = 1.63 mole Na₂CO₃(s) x 106 g/mole = 172.78 grams Na₂CO₃(s)

 Explanation:

answer is b

Answer:

[NaCl]: 2M

Explanation:

This solution is made of NaCl therefore:

Our solute is NaCl

Moles of solute: 4

Our solution's volume is 2L

Molarity are the moles of solute contained in 1L of solution (mol/L)

[NaCl]: 4 mol /2L = 2M

We can also make a rule of three:

In 2 L we have 4 moles of solute

So, In 1 L we must have (1 . 4) /2 = 2 M

The molarity of the solution is 2.0 M (moles per liter).

To determine the molarity of a solution, one must use the formula:

[tex]\[ \text{Molarity (M)} = \frac{\text{Number of moles of solute (n)}}{\text{Volume of solution (V)}} \][/tex]

Given that the solution contains 4.0 moles of NaCl (solute) and has a total volume of 2.0 liters, we can plug these values into the formula:

[tex]\[ \text{Molarity (M)} = \frac{4.0 \text{ moles}}{2.0 \text{ L}} \] \[ \text{Molarity (M)} = 2.0 \text{ M} \][/tex]

Therefore, the molarity of the solution is 2.0 moles per liter. This means that there are 2.0 moles of NaCl dissolved in every liter of the solution.

Answer: [tex]t=\frac{Q}{I}[/tex]

Explanation:

[tex]I=\frac{Q}{t}[/tex]

Multiply by t on both sides.

[tex]t*I=\frac{Q}{t}*t[/tex]

[tex]tI=Q[/tex]

Now divide by I to isolate t.

[tex]\frac{tI}{I}=\frac{Q}{I}[/tex]

[tex]t=\frac{Q}{I}[/tex]

Final answer:

To solve for time t in the equation I = Q/t, multiply both sides by t to get t × I = Q, and then divide both sides by I to obtain[tex]t=\frac{Q}{I}[/tex].

Explanation:

To solve the equation, [tex]I= \frac{Q}{t}[/tex] for the variable t, you need to isolate t on one side of the equation. This can be done by rearranging the equation algebraically. Here's how it is done step-by-step:

Multiply both sides of the equation by t to get t × I = Q.

Next, divide both sides of the equation by I to solve for t, so we have [tex]t=\frac{Q}{I}[/tex].

Through these steps, we've successfully isolated t and found that the time (t) is equal to the charge (Q) divided by the current (I).