State whether or not the following equation is balanced: FeO + Al → Fe + Al2O3
If it is not balanced, explain why and provide the balanced equation.

Answer: The empirical formula for the given compound is [tex]C_3H_3O_2[/tex]

Explanation:

The chemical equation for the combustion of hydrocarbon having carbon, hydrogen and oxygen follows:

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

where, 'x', 'y' and 'z' are the subscripts of Carbon, hydrogen and oxygen respectively.

We are given:

Mass of [tex]CO_2=0.9267g[/tex]

Mass of [tex]H_2O=0.1897g[/tex]

We know that:

Molar mass of carbon dioxide = 44 g/mol

Molar mass of water = 18 g/mol

For calculating the mass of carbon:

In 44 g of carbon dioxide, 12 g of carbon is contained.

So, in 0.9267 g of carbon dioxide, [tex]\frac{12}{44}\times 0.9267=0.2527g[/tex] of carbon will be contained.

For calculating the mass of hydrogen:

In 18 g of water, 2 g of hydrogen is contained.

So, in 0.1897 g of water, [tex]\frac{2}{18}\times 0.1897=0.021g[/tex] of hydrogen will be contained.

Mass of oxygen in the compound = (0.4987) - (0.2527 + 0.021) = 0.225 g

To formulate the empirical formula, we need to follow some steps:

Step 1: Converting the given masses into moles.

Moles of Carbon =[tex]\frac{\text{Given mass of Carbon}}{\text{Molar mass of Carbon}}=\frac{0.2527g}{12g/mole}=0.021moles[/tex]

Moles of Hydrogen = [tex]\frac{\text{Given mass of Hydrogen}}{\text{Molar mass of Hydrogen}}=\frac{0.021g}{1g/mole}=0.021moles[/tex]

Moles of Oxygen = [tex]\frac{\text{Given mass of oxygen}}{\text{Molar mass of oxygen}}=\frac{0.225g}{16g/mole}=0.014moles[/tex]

Step 2: Calculating the mole ratio of the given elements.

For the mole ratio, we divide each value of the moles by the smallest number of moles calculated which is 0.485 moles.

For Carbon = [tex]\frac{0.021}{0.014}=1.5[/tex]

For Hydrogen  = [tex]\frac{0.021}{0.014}=1.5[/tex]

For Oxygen  = [tex]\frac{0.014}{0.014}=1[/tex]

Step 3: Taking the mole ratio as their subscripts.

The ratio of C : H : O = 1.5 : 1.5 : 1

To make in whole number we multiply the ratio by 2, we get:

The ratio of C : H : O = 3 : 3 : 2

The empirical formula for the given compound is [tex]C_3H_3O_2[/tex]

Thus, the empirical formula for the given compound is [tex]C_3H_3O_2[/tex]

Answer:

B

Explanation:

The boiling point of water increases when a solute is dissolved in the water. The amount by which the boiling point is raised depends on the number of solute particles in the water.

For equal molar quantities of Epsom salt, potassium sulfide, sodium chloride, and sugar are, potassium sulfide yields the most particles.

K₂S dissociates as follows:

K₂S ⇒ 2K⁺ + S²⁻

One mole of K₂S yields 3 moles of particles.

Epsom salt (MgSO₄) yields 2 moles of particles for every mole:

MgSO₄ ⇒ Mg²⁺ + SO₄²⁻

Sodium chloride (NaCl) also yields 2 moles of particles for every mole:

NaCl ⇒ Na⁺ + Cl⁻

Sugar is not an electrolyte and does not dissociate, so 1 mole of sugar produces 1 mole of solute particles.

Answer:

Potassium sulfide (K2S)

Explanation:

Answer via Founder's Education/Educere

Answer: 85.47u

Explanation:

The average atomic mass of an element is determined by taking the weighted average of the atomic masses of its naturally occurring isotopes.

Now, weighted average simply means that each isotope contributes to the average atomic mass of the element proportionally to its percent abundance.

avg. atomic mass=∑i(isotopei×abundancei)

The more abundant an isotope is, the more its atomic mass will influence the average atomic mass of the element.

In your case, you know that rubidium has two stable isotopes

85Rb → 84.91 u, 72.16% percent abundance

87Rb →86.91 u, 27.84% percent abundance

When you calculate the average atomic mass, make sure that you use decimal abundance, which is simply percent abundance divided by

100.

So, plug in your values to get

avg. atomic mass = 84.91 u × 0.7216 + 86.91 u × 0.2784

avg. atomic mass = 85.4668 u

Rounded to four sig figs, the answer will be

avg. atomic mass =85.47 u

Answer:

In carbon containing compounds, carbon usually forms four bonds, nitrogen usually forms three bonds, oxygen usually forms two bonds, and hydrogen only forms one bond.

Explanation:

In organic compounds in which carbon is present, the number of bonds formed depend on the number of electrons available for each chemical element. In the case of Carbon, it is 4. Nitrogen is 3. Oxygen is 2. Hydrogen is 1. In other types of compounds, it is possible to see different types of bonds.

Answer:

Explanation:

I could have set up an experiment to determine the density of the metal in the jar. When I derive the density of the metal, I will compare it with that of every other metal to see if it properly fits any.

Density is the mass per unit volume of substance. It is the amount of substace contained per unit volume.

To find the density of the metal, the mass of the metal is obtained by directly weighing it. The volume is found by immersing the metal in water as it will sink. The volume of the water displaced is the volume of the metal. A measuring cylinder or an overflow is used to determine the volume of the liquid displaced.

     Then:

             Density = [tex]\frac{mass}{volume}[/tex]

Final answer:

To confirm the identity of the metal as pure zinc, perform an experiment with hydrochloric acid, observe reactions, record properties, and differentiate based on reactivity and density.

Explanation:

Experiment:

Place a few drops of zinc metal in a test tube and cover with dilute hydrochloric acid.

Heat the test tube containing the mixture to observe reactions and record your observations.

Wait for the product to cool, break the test tube, and examine the product to verify if it matches properties of pure zinc.

Observations:Zinc's reactivity with hydrochloric acid, its density compared to water, and its behavior in displacement reactions can be used to differentiate and confirm its identity as pure zinc.

Chemical Reactions:When zinc metal reacts with sulfuric acid, it produces zinc sulfate and hydrogen gas; whereas zinc oxide reacts with sulfuric acid to form zinc sulfate only.

Answer:

Hello My friend! The balanced reaction its: 2Al(s) + 3CuSO4(aq) –> Al2(SO4)3(aq) + 3Cu(s)

Explanation:

In this case an oxidation reaction involving the metallic aluminum occurred;

Al (s) -> Al3 + (aq) + 3e–

and reduction reaction involving copper;

2e– + Cu2 + (aq) -> Cu (s)

Answer:

2Al(s) + 3CuSO4(aq) → Al2(SO4)3(aq) + 3Cu(s)  

Single replacement reaction

Explanation:

From the picture above the reaction is between aluminium and copper(ii) tetraoxosulphate .

The chemical reaction can be represented with a chemical equation as follows:

Al(s) + CuSO4(aq) → Al2(SO4)3(aq) + Cu(s).

In a chemical reaction we have the reactant side and the product side. The reactant side is at the left hand side while the product is at the right hand side.

The number of atom of element should be equal in number on both sides for the chemical equation to be balanced .

2Al(s) + 3CuSO4(aq) → Al2(SO4)3(aq) + 3Cu(s)  

The equation is balanced now as we have 2 atoms of aluminium on the reactant and product sides., 3 atoms of copper on both sides, 3 atoms of S and 12 atoms  of O on both sides.

The reaction type is a single replacement reaction. The more reactive aluminium displaced copper from it compound.  

Answer:

number 2 your welcome good luck

Final answer:

Ionization in human cells due to high-energy particles or electromagnetic waves from radioactive nuclides can lead to unstable atoms, free electrons, and reactive free radicals, causing serious disruptions in cell functions and health.

Explanation:

The consequences of ionization in human cells can lead to various forms of radiation damage, which is highly concerning due to the critical functions that cells play in an organism's health. When high-energy particles such as alpha and beta particles, or electromagnetic waves emitted by radioactive nuclides, encounter living cells, they have the potential to cause significant disruption. These disruptions include:

The damage caused by ionizing radiation includes both somatic and genetic impacts, with the former affecting the individual's own body cells and the latter having potential consequences for future generations. Cells that reproduce rapidly, such as those found in bone marrow and the gastrointestinal tract, are often most susceptible to this type of damage.

Answer:

The vapor pressure of X at [tex]- 89^{\circ}[/tex] = 0.12 atm

Given:

[tex]\Delta H_{v} = 16.0 kJ mol[/tex]

Normal boiling point, T = [tex]- 43^{\circ}C = 230 K[/tex]

T' = [tex]- 89^{\circ}C = 184 K[/tex]

Solution:

At boiling point, vapor pressure  = atmospheric pressure

Thus at T, P = 1 atm

Now, to calculate vapor pressure, P' at T' = 184 K, we use:

[tex]log_{10}\frac{P'}{P} = \frac{\Delta H_{v}}{R2.303}\frac{T' - T}{T'T}[/tex]

where

R = Rydberg's constant = 8.314 J/mol.K

Putting the values in the above formula:

[tex]log_{10}\frac{P'}{1} = \frac{16.0\times 1000}{8.314\times 2.303}\frac{184 - 230}{184\times 230}[/tex]

[tex]log_{10}{P'}= - 0.9083[/tex]

[tex]P'= 10^{- 0.9083} = 0.12 atm[/tex]

Vapor pressure of Substance X at -89°C is calculated by using the Clausius-Clapeyron equation along with the given enthalpy of vaporization and the normal boiling point. The equation is rearranged to a linear form to solve for the vapor pressure.

To calculate the vapor pressure of Substance X at -89°C using the enthalpy of vaporization and normal boiling point, we use the Clausius-Clapeyron equation. This equation is: P = Ae¯^Hvap/RT, where AHvap is the enthalpy of vaporization for the substance, R is the gas constant, and A is a constant whose value depends on the substance. Temperature T must be in Kelvin for this equation. In this case, the enthalpy of vaporization of Substance X is 16.0kJ mol and its normal boiling point is −43.°C.

This equation can be rearranged into logarithmic form to obtain a linear equation: Hvap + lnA = RT. If we know the vapor pressure at one temperature (T₁, P₁) and want to find the vapor pressure at another temperature (T₂), we can use these values to find A and subsequently calculate the vapor pressure at T₂.

Keep in mind that the normal boiling point is the temperature at which the vapor pressure equals atmospheric pressure at sea level, so this allows us to know one vapor pressure-temperature value.

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Answer: There is no solution for the required amount of butanoic acid.

Explanation:

We are given:

Mass of butanoic acid needed = 60.00 grams

36.9 % w/w butanoic acid solution

This means that 36.9 grams of butanoic acid is present in 100 grams of solution

Applying unitary method:

If 36.9 grams of butanoic acid is present in 100 grams of solution

So, 60.00 grams of butanoic acid will be present in = [tex]\frac{100}{36.9}\times 60.00=162.6g[/tex]

As, the given amount of solution is less than the required amount.

Hence, there is no solution for the required amount of butanoic acid.

Final answer:

To obtain 60.00 g of butanoic acid from a 36.9% w/w solution, 162.6 g of the solution is needed. The student has only 120 g available, which is insufficient.

Explanation:

To determine how much of the 36.9% w/w butanoic acid solution is needed to obtain 60.00 g of butanoic acid, we use the percentage concentration to set up a calculation. The 36.9% w/w solution means that for every 100 g of solution, there are 36.9 g of butanoic acid. Therefore, to find the mass of the solution needed for 60.00 g of butanoic acid, we can use the equation:

Mass of solution = (Mass of butanoic acid)/(Percentage of butanoic acid by mass) × 100

This yields:

Mass of solution = (60.00 g)/(0.369) × 100 = 162.6 g

Since the student has 120 g of the solution available, which is less than the 162.6 g required, there is not enough solution to obtain 60.00 g of butanoic acid.

Answer:

The correct option is c) exothermic, negative.

Explanation:

Reactions that releases heat to the surroundings are called exothermic, and are characterized by negative entalpy (ΔH) values.

A chemical reaction that releases heat to the surroundings is said to be exothermic and has a negative H at constant pressure.

This is the type of reaction which involves the release or loss of heat to the surrounding.

Since heat is lost, exothermic reaction has a negative enthalpy thereby making option C the most appropriate choice.

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Answer:

What is your question?

High School Chemistry 10+5 pts

Water molecules are _____polar_______ because the hydrogen atoms are positively charged on one end and the oxygen atoms are negatively charged on one end. Molecules that are _____nonpolar_______ share electrons equally. Sodium chloride (NaCl) is an example of a ______polar______ molecule because it is soluble in water. Molecules that are _____nonpolar_______ are insoluble in water. It is ______false______ that most molecules formed with nonpolar bonds dissolve easily in water.

Answer:

The answer is letter b.

Explanation:

a. Acids and bases cannot mix together. This is wrong, in fact there is a reaction called neutralization in which the reactants are an acid and a base.

b. Acids and bases will neutralize each other. This is true, when acids and bases react, the products are a salt and water and the reaction is called neutralization reaction.

c. Acids, but not bases, can change the pH of a solution. It's false, both acids and bases change the pH of a solution.

d. Acids donate hydroxide ions (OH–); bases donate hydrogen ions (H+). It's wrong, acids donate H+ and bases donate OH-.

The correct statement here is  Acids and bases will neutralize each other.

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Answer : The correct option is, (7) 332 mL

Explanation : Given,

Density of solution of sulfuric acid = [tex]1.29g/cm^3=1.29g/mL[/tex]

38.1 % acid by mass that means 38.1 grams of sulfuric acid present in 100 grams of solution of sulfuric acid.

Now we have to calculate the mass of solution of sulfuric acid.

As, 38.1 grams of sulfuric acid present in 100 grams of solution of sulfuric acid

So, 163 grams of sulfuric acid present in [tex]\frac{163}{38.1}\times 100=428.95[/tex] grams of solution of sulfuric acid

Now we have to calculate the volume of sulfuric acid solution.

[tex]Density=\frac{Mass}{Volume}[/tex]

[tex]1.29g/mL=\frac{428.95g}{Volume}[/tex]

[tex]Volume=332mL[/tex]

Therefore, the volume of sulfuric acid solution needed is 332 mL.

Answer:

9742.37 J/mol

Explanation:

We follow the expression for Gibbs free energy:

[tex]\Delta G=\Delta G^{o}+RTlnQ[/tex]

First we calculate Q with the following expression for the reaction:

[tex]aA+bB \rightleftharpoons cC+dD[/tex]

[tex]Q=\frac{P_{C}^{c}P_{D}^{d}}{P_{A}^{a}P_{B}^{b}}[/tex]

Therefore, Q=0.0196

Now we continue with the first equation, and as we are on equilibrium, we know that the Gibbs free energy is zero, therefore:

[tex]0=\Delta G^{o}+RTlnQ\\\\\Delta G^{o}=-RTlnQ\\\\R=8.314J/molK\\\\T=298 K\\\\\Delta G^{o}=+9742.37J/mol[/tex]

The standard change in Gibbs free energy of the given reaction at 25°C can be calculated by first determining the equilibrium constant, K, based on the given partial pressures of the substances and then applying the formula ΔG° = -RT ln K, where R is the ideal gas constant and T is the temperature in Kelvin.

To calculate the standard change in Gibbs free energy of the reaction at 25 °C, we need to take into account the partial pressures of all the substances in the reaction. In this case, the equilibrium constant (K) can be determined as K=(PC*PD^2)/(PA^3*PB^2). After calculating K, we can use the relation for Gibbs free energy change: ΔG° = -RT ln K, with R being the ideal gas constant (8.314 J/(K*mol)) and T being the temperature in Kelvin (273K for 25°C).

Remember that in this context, the equation ΔG = ΔG° + RT ln Q where Q represents the ratio of the initial concentrations of products and reactants. In equilibrium, Q equals K, and ΔG equals to 0, simplifying our calculation.

We can substitute the calculated value of K into the equation to find the standard change in Gibbs free energy. Note that a negative value of ΔG° indicates a spontaneous reaction while a positive value indicates a nonspontaneous reaction at room temperature.

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Answer:

The answer to your question is:

a) 31.75 cm

b) 0.475 miles

c) 2.44 yards

d) 11496.04 inches

Explanation:

Convert

a)           12.5 in to cm

         1 in ------------------- 2.54 cm

       12.5 in ----------------    x

            x = 12.5(2.54)/1 = 31.75/ = 31.75 cm

b)          2513 ft to miles

           1 mile -------------- 5280 ft

           x miles ------------ 2513 ft

        x = 2513(1)/5280 = 0.475 miles

c) 2.23 m to yards

              1 m -------------   1,094 yards

            2.23 m ----------     x

       x= 2.23x1.094/1 = 2.44 yards

d)  292 m to inches

            1 m ---------------- 39.37 inches

          292 m -------------     x

    x = 292 x 39.37/1 = 11496.04 inches

Answer:

The answer to your question is letter A.

Explanation:

Isomers are molecules that have the same molecular formula but have a different structure. The molecule from which are looking an isomer has 5 carbons and 1 double bond. Then we need to look for another molecule with these components.

A.- This molecule has 5 carbons and 1 double bond, This structure is an isomer of the first one.

B.- This molecule has 3 carbons and 1 double bond, it's not an isomer of the first structure.

C. This molecule has 4 carbons and 1 triple bonds, it's not an isomer of the first structure.

D. This molecule has 5 carbons but it doesn't have any double bond, then it's not an isomer of the first structure.

Hey!

---------------------------------------------------------------

Mass of the alloy:

m = 8.48 g/cm^3 * 125.5 cm^3 = 954 grams

954 * 0.37 = 352.98 grams

---------------------------------------------------------------

Mass of the copper:

954 - 352.98 = 601.02 grams

---------------------------------------------------------------

Copper Molar Mass: 63.55 g/mol

Zinc Molar Mass: 65.38 g/mol

---------------------------------------------------------------

Moles in copper: 352.98 / 65.38 = 5.40 moles!

Moles in zinc: 601.02 / 63.55 = 9.46 moles!

---------------------------------------------------------------

Atoms in copper = 10^24 * 3.25 atoms

Atoms in zinc = 10^24 * 5.70

I used the Avogadro's Number.

---------------------------------------------------------------

Hope This Helped! Good Luck!

Hydrogen bonds between water molecules must break for water to change from solid to liquid to gas.

In order for water to change from solid to liquid to gas, the hydrogen bonds between water molecules must break. These hydrogen bonds are weaker than covalent or ionic bonds and are constantly forming and breaking in liquid water. When the heat is increased, the higher kinetic energy of the water molecules causes the hydrogen bonds to break completely, allowing water molecules to escape into the air as gas. On the other hand, when water is cooled and freezes, the water molecules form a crystalline structure maintained by hydrogen bonding, making ice less dense than liquid water.

Answer:

The correct answer to your question is the second option

Explanation:

The amount of energy from the products  This option is not correct because in a chemical reaction the energy given off or absorved is written at the end of the reaction, it is not a coefficient.

The ratios of the number of moles of each substance that react and that are produced  This option is correct, coefficients tell the number of moles of each substance in a reaction.

The physical states of the compounds reacting  Physical states are written next to the molecule and using parenthesis.  Incorrect

The elements involved in the reaction Incorrect because elements are written with symbols not with coefficients.

Final answer:

The coefficients in a balanced chemical equation represent the molar ratios of reactants and products in a chemical reaction, which are essential for stoichiometric calculations and ensure adherence to the Law of Conservation of Mass.

Explanation:

The coefficients in a balanced chemical equation tell us the ratios of the number of moles of each substance that react and that are produced during the chemical reaction. These coefficients indicate the relative amounts of reactants and products in a reaction and are used in stoichiometry to determine the quantities of one substance that will react with or produce a given amount of another substance.

Stoichiometry is the study of the numerical relationships between the reactants and the products in balanced chemical reactions. The coefficients in a balanced chemical equation also respect the Law of Conservation of Mass, ensuring that the number of atoms of each element is equal on both the reactant and product sides of the equation. These ratios are referred to as stoichiometric factors and are critical in performing quantitative chemical calculations.

To prepare 1.00 L of 0.120 M HNO3 by mixing with water, you would need approximately 0.992 kg of the concentrated solution.

To prepare 1.00 L of 0.120 M HNO3, we can start by calculating the number of moles of HNO3 needed, using the given concentration and volume. We can then use the density of the concentrated solution to calculate the mass of the concentrated solution required. Finally, we can use the percentage of HNO3 in the concentrated solution to determine the mass of HNO3 needed.

Step 1: Calculate the number of moles of HNO3 needed:

moles HNO3 = concentration x volume = 0.120 M x 1.00 L = 0.120 moles HNO3

Step 2: Calculate the mass of the concentrated solution needed:

mass concentrated solution = volume x density = 1.00 L x 1.41 g/mL = 1.41 kg

Step 3: Calculate the mass of HNO3 needed:

mass HNO3 = mass concentrated solution x percentage HNO3 = 1.41 kg x 70.3% = 0.992 kg

Therefore, you would need approximately 0.992 kg of the concentrated solution to prepare 1.00 L of 0.120 M HNO3 by mixing it with water.

Answer:

The answer to your question is letter B

Explanation:

Activated complex is an intermediate process between the reactants and the products which has a higher energy than both (reactants and products).

In the graph we can see that the higher point is letter B, that is the one of the activated complex. The energy that must be supply to the systed to proceed is called activated energy.

Answer:

D is the best choice. Those percentages, are giving you the information about how concentrated are the solutions.  As 0.015 is so concentrated, this solution will damage the structures more quickly

Explanation:

Answer:

The answer is D. 0.015%

Explanation:

That is the concentration of the Sulfuric Acid solution given in mass per mass percentage (w/w%), it means that the solution has 0.015 grams of Sulfuric Acid per 100 grams of solution. If it is compared with C answer, it has 0.005 grams more. Considering the reaction:

[tex]H_{2} SO_{4} + CaCO_{3}[/tex] ⇒ [tex]CaSO_{4} + CO_{2} + H_{2}O[/tex]

The more [tex]H_{2} SO_{4}[/tex] (Sulfuric Acid) is present, the more [tex]CaCO_{3}[/tex] (Limestone) is consumed.

Answer:

(a) 0.459 Jg⁻¹°C⁻¹

(b) 22 Jmol⁻¹°C⁻¹

(c) 0.72 moles

Explanation:

(a) The specific heat capacity can be calculated using the following equation:

Q = mcΔt, where Q is the heat energy, m is the mass, c is the specific heat capacity, and Δt is the temperature change from initial to final.

Rearranging the equation to solve for c gives:

c = Q / (mΔt) = (312J) / ((34.0g)(44.0°C - 24°C) = 0.459 Jg⁻¹°C⁻¹

(b) To find the molar specific heat, grams in the above result must be converted to moles using the mass per mole:

(0.459 Jg⁻¹°C⁻¹)(47g/mol) = 22 Jmol⁻¹°C⁻¹

(c) The numer of moles present are found by converting grams to moles using the mas per mole:

(34.0g)(mol/47g) = 0.72 moles

Answer:

The concentration of the standard NaOH solution is 0.094 moles/L.

Explanation:

In the titration, the equivalence point is defined as the point where the moles of NaOH (the titrant) and KHP (the analyte) are equal:

     moles of NaOH = moles of KHP

[tex][NaOH]xV_{NaOH} = moles of KHP[/tex]

[tex][NaOH] = \frac{moles of KHP}{V_{NaOH}}[/tex]

The [tex]V_{NaOH}[/tex] is 40.82mL = 0.04082L and the moles of KHP are

[tex]0.7816g / 204.2212\frac{g}{mol} = 3.827x10^{-3} moles[/tex]

Replacing at the first equation:

[tex][NaOH] = \frac{3.827x10^{-3}moles}{0.04082L} = 0.094 moles/L[/tex]

The temperature outside on the hot summer day was approximately 37.18 °C.

Charles's law, which states that for constant pressure and volume of a gas, the volume of a gas is proportional to its absolute temperature (measured in Kelvin), can be used to resolve this:

Calculating the temperature outside ([tex]\rm T_2[/tex]) in Kelvin using the information provided:

Initial temperature ([tex]\rm T_1[/tex]) = 19.0 °C + 273.15 K = 292.15 K

Initial diameter ([tex]\rm d_1[/tex]) = 50.0 cm

Final diameter ([tex]\rm d_2[/tex]) = 51.0 cm

[tex]\rm (T_1 / T_2) = (d_1^3 / d_2^3)[/tex]

[tex]\rm (292.15 K / T_2) = (50.0^3 / 51.0^3)[/tex]

Calculating the right-hand side of the equation:

[tex](50.0^3 / 51.0^3)[/tex] ≈ 0.94149

Solving for [tex]\rm T_2[/tex]:

[tex]\rm T_2[/tex] = 292.15 K / 0.94149 ≈ 310.33 K

Converting [tex]\rm T_2[/tex] back to Celsius:

Temperature outside (in Celsius) = [tex]\rm T_2[/tex] - 273.15

Temperature outside (in Celsius) = 310.33 K - 273.15 K ≈ 37.18 °C

Therefore, the temperature outside on the hot summer day was approximately 37.18 °C.

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The problem is based on Charles's Law which states the volume of a gas is directly proportional to its temperature at constant pressure. The initial and final conditions of the balloon are used to calculate the outside temperature to be approximately 38.35°C.

To solve this problem, we need to use the concepts of gas laws, specifically Charles's Law. Charles's Law states that volume of a gas is directly proportional to its temperature if pressure and the amount of gas remain constant. In this case, we assume that the pressure inside the balloon remains constant because it is exposed to constant external atmospheric pressure both inside the air-conditioned room and outside.

Let's express the initial and final conditions as follows:

According to Charles's Law, V1/T1=V2/T2. So, we can find the final temperature as T2 = V2*(T1/V1). Substituting our values, we find T2 = 69813*(292.15/65450) = 311.5 K. Finally, convert it back to Celsius by subtracting 273.15: T2 = 311.5 - 273.15 = 38.35°C. So, it was approximately 38.35°C outside.

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Answer:

a) 0.65

b) 0.342 atm

Explanation:

a) First, we need to know the molar mass of the compounds. By periodic table, the molar mass of the elements are:

C = 12 g/mol; Cl = 35.5 g/mol; H = 1 g/mol. So:

CCl4 = 12 + 4x35.5 = 154 g/mol

CHCl3 = 12 + 1 + 3x35.5 = 119.5 g/mol

They both have the same mass, so we can choose the basis of calculus as 100 g (you can choose any other basis, the result will be the same because the fraction will be the same!)

The number of moles is :

n = mass/molar mass

nCCl4 = 100/154 = 0.649 mol

nCHCl3 = 100/119.5 = 0.837 mol

So, the total number of moles is nt =  nCCl4 + nCHCl3 = 1.486

Then, the molar fractions in the solution will be:

xCHCl3 = nCHCl3/nt = 0.837/1.486 = 0.56

xCCl4 = 1 - 0.56 = 0.44

By Dalton's Law

Pt = PCCl4*xCCl4 + PCHCl3*xCHCl3

Where Pt is the total pressure of the vapor, and PCCl4 and PCHCl3 are the vapor pressure of the compounds. So:

Pt = 0.44*0.354 + 0.56*0.526 = 0.451 atm

The molar fraction of the vapor will be:

yCHCl3 = (xCHCl3*PCHCl3)/Pt

yCHCl3 = (0.56*0.526)/0.451 = 0.65

b) When the vapor is condensed, the molar fraction of the vapor phase will be the molar fraction of the solution, so xCHCl3 = 0.65

P = molar fraction x vapor pressure

P = 0.65 x 0.526

P = 0.342 atm

The mole fraction of CHCl₃ in the vapor above the solution is equal to 0.65.

Given the following data:

Vapor pressure of CCl₄ = 0.354 atm.

Vapor pressure of CHCl₃ = 0.526 atm.

Scientific data:

Molar mass of CCl₄ = 154 g/mol.

Molar mass of CHCl₃ = 119.5 g/mol.

Next, we would determine the number of moles for each compound:

Note: Assume a mass of 100 grams.

Mathematically, the number of moles contained in a chemical compound is given by this formula:

[tex]Number \;of \;moles = \frac {mass}{molar\;mass}\\\\Number \;of \;moles = \frac {100}{154}[/tex]

Number of moles of CCl₄ = 0.649 mol.

For CHCl₃:

[tex]Number \;of \;moles = \frac {mass}{molar\;mass}\\\\Number \;of \;moles = \frac {100}{119.5}[/tex]

Number of moles of CHCl₃ = 0.837 mol.

The total number of moles = 0.649 + 0.837 = 1.486 mol.

For the mole fraction of CCl₄, we have:

[tex]M_f = \frac{0.649}{1.486} \\\\[/tex]

Mole fraction = 0.44.

For CHCl₃, we have:

Mole fraction = 1 - 0.44 = 0.56.

Next, we would determine the total pressure of the two compounds by applying Dalton's law:

Total pressure = 0.56 × 0.526 + 0.44 × 0.354

Total pressure = 0.451 atm.

Now, we can determine the mole fraction of CHCl₃ in the vapor above the solution:

[tex]Mole \;fraction = \frac{0.56 \times 0.526}{0.451}[/tex]

Mole fraction = 0.65.

Vp = molar fraction × vapor pressure

Vp = 0.65 × 0.526

Vp = 0.342 atm.

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The mass of oxygen, silicon, ruthenium, and rhodium in the earth's crust is 2.274 × 1031 g, 1.360 × 1031 g, 4.998 × 1021 g, and 4.998 × 1021 g respectively.

To find the total mass of each of these elements in Earth's crust, we must first calculate the total volume of the crust. This is done by multiplying the surface area of the Earth by the mean thickness of the crust: 5.10 × 108 km2 * 35 km = 1.785 × 1010 km3.

Next, we convert this volume into cm3, because the density is given in g/cm3: 1.785 × 1010 km3 * (105)3 = 1.785 × 1025 cm3.

Then, we can calculate the total mass of the crust by multiplying the volume by the density: 1.785 × 1025 cm3 * 2.8 g/cm3 = 4.998 × 1025 g.

From there, we can calculate the mass of each element by multiplying the total mass by the abundance of each element. For oxygen and silicon, this would be: 4.998 × 1025 g * 4.55 × 105 g/t = 2.274 × 1031 g for oxygen and 4.998 × 1025 g * 2.72 × 105 g/t = 1.360 × 1031 g for silicon. For the rare elements ruthenium and rhodium, this would be: 4.998 × 1025 g * 1 × 10-4 g/t = 4.998 × 1021 g for both elements.

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Answer:

The answer to your question is: letter A

Explanation:

A. Gas particles are in constant motion. This statement is true because this theory says that Gases are composed of a large number of particles that behave like hard, spherical objects in a state of constant, random motion.

B. Gas particles attract each other. This statement is false because this theory says that there is no force of attraction between gas particles or between the particles and the walls of the container.

C. Gas particles lose their energy during collisions. This statement is false, this theory says that none of the energy of a gas particle is lost when it collides with another particle or with the walls of the container.

D. Gas particles stick to the walls of their container. This statement is false, the theory says that there is no force of attraction between gas particles or between the particles and the walls of the container.

Answer:

1 is b and 2 is d

Explanation:

because you do not know that the cat had done that you was just thinking it was the cat

Answer:

The answer is

Explanation:

Definitions

Observation: is when something catches our attention

Prediction: is a statement about a future event, based upon experience and knowledge

Inference: is a conclusion based on evidence and reasoning.

Hypothesis: is a proposed explanation for a fenomenon

Case I:

It isn't an observation

It isn't a prediction because it happened not will happen

I think is an inference

It isn't a hypothesis, a hypothesis has an specific structure If ... then ...

Case II

I think is a prediction, something that will happen

It isn't an observation he did more than that

It isn't an  inference

Hypothesis has an structure.