Gases Topic Outlines Gas Pressure Gas Laws Ideal

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Gases – Topic Outlines • • • Gas Pressure Gas Laws & Ideal Gas

Gases – Topic Outlines • • • Gas Pressure Gas Laws & Ideal Gas Equation Density of Gases Stoichiometry involving gas reactions Kinetic Molecular Theory of Gases Root-mean-square speed Rates of Gas Diffusion and Effusion Deviation of Real Gases Atmospheric Chemistry

Pressure • SI units = Newton/meter 2 = 1 Pascal (Pa) • 1 standard

Pressure • SI units = Newton/meter 2 = 1 Pascal (Pa) • 1 standard atmosphere = 1 atm • 1 atm = 760 mm Hg = 760 torr = 101, 325 Pa

Gas and Liquid Pressure • Both are due to force exerted by molecules colliding

Gas and Liquid Pressure • Both are due to force exerted by molecules colliding with the surface of container walls. • Liquid Pressure = g·d·h (g= gravitational constant; d = liquid density; h = height of liquid column) • Gas pressure = n. RT/V (n = mol of gas; R = gas constant; T = temperature in K, and V = volume in L)

Barometer • • A device used to measure atmospheric pressure. Mercury barometer uses Hg(l);

Barometer • • A device used to measure atmospheric pressure. Mercury barometer uses Hg(l); • Pressure exerted by Hg(l) column (PHg) is equalized by air pressure; • Since PHg h. Hg; atm pressure h. Hg , and atm pressure is expressed in term of height of Hg column: 1 atm = 760. 0 mm. Hg (760 torr) •

Opened-end Manometer

Opened-end Manometer

Manometers Prentice-Hall © 2002 General Chemistry

Manometers Prentice-Hall © 2002 General Chemistry

Manometer or Pressure Gauge • Device used for measuring the pressure of a gas

Manometer or Pressure Gauge • Device used for measuring the pressure of a gas in a container.

Pressure Conversions: An Example The pressure of a gas is measured as 2. 5

Pressure Conversions: An Example The pressure of a gas is measured as 2. 5 atm. Represent this pressure in both torr and pascals.

Gas Law • Avogadro’s Law: At fixed temperature and pressure, volume is directly proportional

Gas Law • Avogadro’s Law: At fixed temperature and pressure, volume is directly proportional to the moles of gas; V = an (a is a proportionality constant); V 1/n 1 = V 2/n 2

Boyle’s Law For a given quantity of gas at constant temperature, volume is inversely

Boyle’s Law For a given quantity of gas at constant temperature, volume is inversely proportional to pressure; V = b/P (b is a proportionality constant); P 1 V 1 = P 2 V 2

Boyle’s Law

Boyle’s Law

Charles’s Law For a given quantity of gas at constant pressure, volume is directly

Charles’s Law For a given quantity of gas at constant pressure, volume is directly proportional to the temperature in Kelvin; V = c. T (c is a proportionality constant; T is temperature in Kelvin) V 1/T 1 = V 2/T 2

Charles’s Law • Volume and Temperature (in Kelvin) are directly related (constant P and

Charles’s Law • Volume and Temperature (in Kelvin) are directly related (constant P and n). • V=c. T (c is the proportionality constant) • K = °C + 273 • 0 K is called absolute zero.

Charles’s Law

Charles’s Law

Avogadro’s Law • Volume and number of moles are directly related (constant T and

Avogadro’s Law • Volume and number of moles are directly related (constant T and P). • V = an (a is a proportionality constant)

Ideal Gas Law • We can combine these laws into one comprehensive law: V

Ideal Gas Law • We can combine these laws into one comprehensive law: V = b. T (constant P and n) V = an (constant T and P) V = k/P (constant T and n) PV = n. RT (where R = 0. 08206 L·atm/mol·K, the universal gas constant)

Molar Volume of an Ideal Gas • For 1 mole of an ideal gas

Molar Volume of an Ideal Gas • For 1 mole of an ideal gas at 0°C and 1 atm, the volume of the gas is 22. 41 L. • STP = standard temperature and pressure § 0°C and 1 atm § Therefore, the molar volume is 22. 41 L at STP.

Standard Temperature and Pressure • STP = Standard Temperature and Pressure Standard Temperature =

Standard Temperature and Pressure • STP = Standard Temperature and Pressure Standard Temperature = 0 o. C = 273. 15 K Standard Pressure = 1. 000 atm (760. 0 torr) • At STP, molar volume of ideal gas = 22. 4 L/mol • Ideal gas constant, R = 0. 08206 L. atm/K. mol • In another units, R = 62. 36 L. torr/K. mol = 6. 236 x 104 m. L. torr/K. mol;

Dalton’s Law of Partial Pressure • In a mixture of gases, the total pressure

Dalton’s Law of Partial Pressure • In a mixture of gases, the total pressure is equal to the sum of the partial pressures of individual gases. • If the partial pressures of gases A, B, C, …are PA, PB, PC, . . , then the total pressure is • • PTotal = PA + PB + PC + … Since PA = n. ART/V; PB = n. BRT/V, and PC = n. CRT/V, PT = (n. ART/V) + (n. BRT/V) + (n. CRT/V) = (n. A + n. B + n. C + …)(RT/V) = (ntotal)RT/V

Exercise 27. 4 L of oxygen gas at 25. 0°C and 1. 30 atm,

Exercise 27. 4 L of oxygen gas at 25. 0°C and 1. 30 atm, and 8. 50 L of helium gas at 25. 0°C and 2. 00 atm were pumped into a 5. 81 -liter tank at 25°C. • Calculate the new partial pressure of oxygen. 6. 13 atm • Calculate the new partial pressure of helium. 2. 93 atm • Calculate the new total pressure of both gases. 9. 06 atm

Density and Molar Mass of Gases • Density = Mass/Volume = grams/L • Mass

Density and Molar Mass of Gases • Density = Mass/Volume = grams/L • Mass (in grams) = mole x molar mass = n. M

Molar Mass of a Gas § § d = density of gas T =

Molar Mass of a Gas § § d = density of gas T = temperature in Kelvin P = pressure of gas R = universal gas constant

The Need for a Model/Theory -Kinetic Molecular Theory (KMT) • So far we have

The Need for a Model/Theory -Kinetic Molecular Theory (KMT) • So far we have considered “what happens, ” but not “why. ” • In science, “what” always comes before “why. ”

Postulates of the Kinetic Molecular Theory 1) The particles are so small compared with

Postulates of the Kinetic Molecular Theory 1) The particles are so small compared with the distances between them that the volume of the individual particles can be assumed to be negligible (zero).

Postulates of the Kinetic Molecular Theory 2) The particles are in constant motion. The

Postulates of the Kinetic Molecular Theory 2) The particles are in constant motion. The collisions of the particles with the walls of the container are the cause of the pressure exerted by the gas.

Postulates of the Kinetic Molecular Theory 3) The particles are assumed to exert no

Postulates of the Kinetic Molecular Theory 3) The particles are assumed to exert no forces on each other; they are assumed neither to attract nor to repel each other.

Postulates of the Kinetic Molecular Theory 4) The average kinetic energy of a collection

Postulates of the Kinetic Molecular Theory 4) The average kinetic energy of a collection of gas particles is assumed to be directly proportional to the Kelvin temperature of the gas.

Kinetic Molecular Theory • Gas is composed of tiny particles with finite masses but

Kinetic Molecular Theory • Gas is composed of tiny particles with finite masses but negligible molecular volume; • Gas particles are in constant random motion, and colliding with the container walls; • Molecular collisions are completely elastic – energy is conserved during collisions; • Intermolecular attractions between gas particles are nonexistent; • The average molecular kinetic energy for gas depends only on its temperature in Kelvin.

Kinetic Molecular Theory Two gases at the same temperature have the same average molecular

Kinetic Molecular Theory Two gases at the same temperature have the same average molecular kinetic energy; At the same temperature, the lighter gaseous molecules have higher average velocities;

Kinetic Molecular Theory

Kinetic Molecular Theory

Kinetic Molecular Theory

Kinetic Molecular Theory

Concept Check You are holding two balloons of the same volume. One contains helium,

Concept Check You are holding two balloons of the same volume. One contains helium, and one contains hydrogen. Complete each of the following statements with “different” or “the same” and be prepared to justify your answer. He H 2

Concept Check • Complete the following statement with “different” or “the same” and be

Concept Check • Complete the following statement with “different” or “the same” and be prepared to justify your answer. • The pressures of the gas in the two balloons are ________. He H 2

Concept Check • Complete the following statement with “different” or “the same” and be

Concept Check • Complete the following statement with “different” or “the same” and be prepared to justify your answer. • The temperatures of the gas in the two balloons are _______. He H 2

Concept Check • Complete the following statement with “different” or “the same” and be

Concept Check • Complete the following statement with “different” or “the same” and be prepared to justify your answer. • The numbers of moles of the gas in the two balloons are _____. He H 2

Concept Check • Complete the following statement with “different” or “the same” and be

Concept Check • Complete the following statement with “different” or “the same” and be prepared to justify your answer. • The densities of the gas in the two balloons are _____. He H 2

KMT Explanation of Boyle’s Law • Pressure-Volume Relationship • At constant temperature, gaseous particles

KMT Explanation of Boyle’s Law • Pressure-Volume Relationship • At constant temperature, gaseous particles travel with the same average speed. • If volume is compressed, the average distance traveled by particles decreases; • This leads to a higher frequency of molecular collisions with walls, which leads to higher gas pressure.

KMT Explanation of Charles’s Law • Volume–Temperature Relationship • The volume of a gas

KMT Explanation of Charles’s Law • Volume–Temperature Relationship • The volume of a gas will increase proportionally as the temperature increases at constant pressure. • Increasing the temperature causes: – molecules to travel faster; – rate of molecular collision with container walls increases. • To maintain a constant pressure when temperature increases: – the volume of the gas must increase to reduce the frequency of collisions.

KMT Explanation of Charles’s Law • Pressure-Temperature Relationship • Gas pressure will increase proportionally

KMT Explanation of Charles’s Law • Pressure-Temperature Relationship • Gas pressure will increase proportionally as the temperature is increased at constant volume. • As the temperature increases, average molecular speed increases; • This causes frequency of collisions to increase, which leads to an increase in pressure.

KMT Explanation of Avogadro’s Law • Volume – Mole Relationship • At constant temperature,

KMT Explanation of Avogadro’s Law • Volume – Mole Relationship • At constant temperature, increasing the number of gas molecules leads to higher rates of collisions and higher pressure; • To maintain a constant pressure, volume of gas must expand. • Avogadro’s law: at constant temperature and pressure, gas volume increases proportionally with the number of moles.

Real Gases Correction for real gas when: 1. Pressure of the gas is high.

Real Gases Correction for real gas when: 1. Pressure of the gas is high. 2. Temperature is low. Under these conditions: 1. Concentration of gas particles is high. 2. Attractive forces become important.

Plots of PV/n. RT Versus P for Several Gases (200 K)

Plots of PV/n. RT Versus P for Several Gases (200 K)

Plots of PV/n. RT Versus P for Nitrogen Gas at Three Temperatures

Plots of PV/n. RT Versus P for Nitrogen Gas at Three Temperatures

Equation for Real Gases • van der Waals equation for real gases includes two

Equation for Real Gases • van der Waals equation for real gases includes two factors: one correct the effect of intermolecular forces (n 2 a/V 2) and the other correct the effect of molecular volume (nb), such that, • {P + (n 2 a/V 2)}(V – nb) = n. RT • For 1 mole of gas (n = 1) • (P + a/V 2)(V – b) = RT • This yields the expression for pressure, • P = {RT/(V – b)} – a/V 2

Real Gases (van der Waals Equation) corrected pressure corrected volume Pideal Videal

Real Gases (van der Waals Equation) corrected pressure corrected volume Pideal Videal

Values of the van der Waals Constants for Some Gases • • The value

Values of the van der Waals Constants for Some Gases • • The value of a reflects how much of a correction must be made to adjust the observed pressure up to the expected ideal pressure. A low value for a reflects weak intermolecular forces among the gas molecules.

Characteristics Real Gases • The actual pressure for a real gas is lower than

Characteristics Real Gases • The actual pressure for a real gas is lower than that expected for an ideal gas. • The existence of intermolecular (attractive) forces lowers the observed pressure in real gases.

Concept Check Sketch a graph of: I. Pressure versus volume at constant temperature and

Concept Check Sketch a graph of: I. Pressure versus volume at constant temperature and moles.

Molecular View of Boyle’s Law

Molecular View of Boyle’s Law

Concept Check Sketch a graph of: II. Volume vs. temperature ( C) at constant

Concept Check Sketch a graph of: II. Volume vs. temperature ( C) at constant pressure and moles.

Concept Check Sketch a graph of: III. Volume vs. temperature (K) at constant pressure

Concept Check Sketch a graph of: III. Volume vs. temperature (K) at constant pressure and moles.

Molecular View of Charles’s Law

Molecular View of Charles’s Law

Concept Check Sketch a graph of: IV. Volume vs. moles at constant temperature and

Concept Check Sketch a graph of: IV. Volume vs. moles at constant temperature and pressure.

Molecular View of The Ideal Gas Law

Molecular View of The Ideal Gas Law

Concept Check VNe = 2 VAr Which of the following best represents the mass

Concept Check VNe = 2 VAr Which of the following best represents the mass ratio of Ne: Ar in the balloons? 1: 1 1: 2 2: 1 1: 3 3: 1 Ne Ar

Concept Check • You have a sample of nitrogen gas (N 2) in a

Concept Check • You have a sample of nitrogen gas (N 2) in a container fitted with a piston that maintains a pressure of 6. 00 atm. Initially, the gas is at 45 C in a volume of 6. 00 L. • You then cool the gas sample.

Concept Check Which best explains the final result that occurs once the gas sample

Concept Check Which best explains the final result that occurs once the gas sample has cooled? a) b) c) d) e) The pressure of the gas increases. The volume of the gas increases. The pressure of the gas decreases. The volume of the gas decreases. Both volume and pressure change.

Concept Check The gas sample is then cooled to a temperature of 15 C.

Concept Check The gas sample is then cooled to a temperature of 15 C. Find the new gas volume. (Hint: A moveable piston keeps the pressure constant overall, so what condition will change? ) 5. 43 L

Root Mean Square Velocity R = 8. 3145 J/K·mol (J = joule = kg·m

Root Mean Square Velocity R = 8. 3145 J/K·mol (J = joule = kg·m 2/s 2) T = temperature of gas (in K) M = mass of a mole of gas in kg Final units are in m/s.

Diffusion and Effusion • Diffusion – the mixing of gases. • Effusion – describes

Diffusion and Effusion • Diffusion – the mixing of gases. • Effusion – describes the passage of a gas through a tiny orifice into an evacuated chamber. • Rate of effusion measures the speed at which the gas escapes from the chamber.

Effusion

Effusion

Diffusion

Diffusion

Graham’s Law of Effusion • M 1 and M 2 represent the molar masses

Graham’s Law of Effusion • M 1 and M 2 represent the molar masses of the gases.

Molar Mass Determination using Relative Rate of Effusion • The rate of effusion of

Molar Mass Determination using Relative Rate of Effusion • The rate of effusion of an unknown gas at a certain temperature and pressure is 25. 0 m. L per minute. Under the same conditions, the effusion rate of N 2 gas is 57. 1 m. L/minute. What is the molar mass of the unknown gaseous compound? If the gaseous compound is composed of 21. 95% sulfur and 78. 05 % fluorine, by mass, what is the formula of the compound? Molar mass = 146; Formula SF 6

Pressure of Real Gases • Use the van der Waals equation to estimate the

Pressure of Real Gases • Use the van der Waals equation to estimate the pressure of 1. 00 mol of N 2 and Cl 2, respectively, in a 22. 4 -L gas flask, at 0. 0 o. C? (For N 2: a = 1. 39 L 2 -atm/mol 2; b = 0. 0391 L/mol; for Cl 2: a = 6. 49 L 2 -atm/mol 2; b = 0. 0562 L/mol) For N 2, P = 1. 00 atm; For Cl 2, P = 0. 990 atm.

The Atmosphere

The Atmosphere

Atmospheric Chemistry • Earth atmosphere is divided into 5 regions: – Troposphere (ca. 0

Atmospheric Chemistry • Earth atmosphere is divided into 5 regions: – Troposphere (ca. 0 – 10 km) – climate changes occur – Stratosphere (ca. 10 – 30 km) – where ozone layer is – Mesosphere (ca. 30 – 50 km, – Thermosphere (ca. 50 – 400 km, and – Exosphere (ca. > 400 km) • Principal components of atmosphere: – N 2, O 2, Ar, H 2 O, and CO 2 – H 2 O and CO 2 make the Earth warm and livable

Troposphere • Lowest part of the atmosphere; • Contains most of our weather phenomena

Troposphere • Lowest part of the atmosphere; • Contains most of our weather phenomena – clouds, rain, snow; • Contains about 75% of all the air; • Temperature decreases with altitude by about 6. 5 o. C per km; • Pressure also decreases with height;

Stratosphere • Contains much of the ozone in the atmosphere; • Temperature increases with

Stratosphere • Contains much of the ozone in the atmosphere; • Temperature increases with height due to absorption of UV radiation by ozone; • Absorption of dangerous UV radiation by ozone protect us from skin cancer. • Uses of CFC compounds in refrigeration and air-conditioning systems caused the reduction of ozone layer in Stratosphere.

The Ozone Layer • The formation of ozone in the Stratosphere: Photo-dissociation of O

The Ozone Layer • The formation of ozone in the Stratosphere: Photo-dissociation of O 2: O 2 2 O; • Reaction of O with O 2 to form ozone molecule: O 2 + O O 3 • Absorption of uv radiation by ozone molecule: O 3 + uv O 2 + O

Destruction of Ozone Layer • Photo-dissociation of CFC compounds produce free-radical chlorine atom (Cl).

Destruction of Ozone Layer • Photo-dissociation of CFC compounds produce free-radical chlorine atom (Cl). For example, CCl 2 F 2 + uv CCl. F 2 + Cl • Reaction of Cl with O 3: Cl + O 3 Cl. O + O 2 • Reaction of Cl. O with O and re-generation of Cl: Cl. O + O O 2 + Cl • Overall reaction: O 3 + O 2 O 2

Air Pollution • Two main sources: § Transportation § Production of electricity • Combustion

Air Pollution • Two main sources: § Transportation § Production of electricity • Combustion of petroleum produces CO, CO 2, NO, and NO 2, along with unburned molecules (hydrocarbons) from gasoline.

Atmospheric Pollutants • Formation of nitric oxide, NO, in internal combustion engines and its

Atmospheric Pollutants • Formation of nitric oxide, NO, in internal combustion engines and its subsequent oxidation to NO 2: • N 2 + O 2 2 NO (inside the engine) • 2 NO + O 2 2 NO 2 (occurs in air) • Photo-dissociation of NO 2: • NO 2 + uv NO + O*

Atmospheric Pollutants • Reaction of reactive O* atom with O 2 to form O

Atmospheric Pollutants • Reaction of reactive O* atom with O 2 to form O 3 • O 2 + O* O 3 • Reaction of O* with H 2 O to produce excited hydroxyl radical OH: H 2 O + O* 2 OH* • Reaction of OH radical with NO 2 forms HNO 3: OH* + NO 2 HNO 3 • HNO 3 causes acid rain.

The Formation of Acid Rain, HNO 3 • The formation of NO, NO 2,

The Formation of Acid Rain, HNO 3 • The formation of NO, NO 2, and HNO 3: N 2 + O 2 2 NO + O 2 2 NO 2 + H 2 O HNO 3 + HNO 2 + OH* HNO 3; • Action of HNO 3 on marble structures: Ca. CO 3(s) + 2 HNO 3 Ca(NO 3)2 + H 2 O + CO 2

Sulfur Oxides (from Burning Coal for Electricity) • Sulfur burns to form toxic SO

Sulfur Oxides (from Burning Coal for Electricity) • Sulfur burns to form toxic SO 2 gas. • SO 2 is oxidized to SO 3, which combines with rain water to form corrosive sulfuric acid, H 2 SO 4.

The Formation of Acid Rain, H 2 SO 4 • Combustion of sulfur-containing coal

The Formation of Acid Rain, H 2 SO 4 • Combustion of sulfur-containing coal produces SO 2 gas, which is further oxidized to SO 3: S + O 2 SO 2 2 SO 2 + O 2 2 SO 3 • Reaction of SO 3 with rain water produces H 2 SO 4: SO 3 + H 2 O H 2 SO 4(aq) • Reaction of H 2 SO 4 with marble structures: Ca. CO 3(s) + H 2 SO 4(aq) Ca. SO 4(aq) + H 2 O(l) + CO 2(g)

Removal of SO 2 From Flu-Gas • Decomposition of Ca. CO 3 to produce

Removal of SO 2 From Flu-Gas • Decomposition of Ca. CO 3 to produce quicklime: Ca. CO 3(s) Ca. O(s) + CO 2(g) • Reaction of Ca. O with SO 2 to form Ca. SO 3: Ca. O(s) + SO 2(g) Ca. SO 3(s) (Ca. SO 3 is disposed in landfills)

A Schematic Diagram of a Scrubber

A Schematic Diagram of a Scrubber

Photochemical Smog • Reaction of hydroxyl radical with HC, such as methane, and other

Photochemical Smog • Reaction of hydroxyl radical with HC, such as methane, and other subsequent reactions involving free-radicals: 1) CH 4 + OH H 2 O + CH 3 2) CH 3 + O 2 CH 3 O 2 3) CH 3 O 2 + NO CH 3 O + NO 2 4) CH 3 O + O 2 HCHO + HO 2 5) HO 2 + NO 2 + OH • Overall reaction: CH 4 + 2 O 2 + 2 NO HCHO + 2 NO 2 + H 2 O

Other Reactions in Photochemical Smog • Reactions of OH radical lead to formation of

Other Reactions in Photochemical Smog • Reactions of OH radical lead to formation of atmospheric pollutant PAN: CH 3 + OH CH 3 CH 2 + H 2 O CH 3 CH 2 + O 2 CH 3 CH 2 O 2 + NO CH 3 CH 2 O + NO 2 CH 3 CH 2 O + O 2 CH 3 CHO + HO 2 + NO 2 + OH CH 3 CHO + OH CH 3 CO + H 2 O CH 3 CO + O 2 CH 3 COO 2 + NO 2 CH 3 COO 2 NO 2 (PAN) (PAN = peroxyacetylnitrate is an eye irritant)

Concentration for Some Smog Components vs. Time of Day

Concentration for Some Smog Components vs. Time of Day

Explain the following: 1. The destruction of ozone by chlorofluorocarbon (CFC) compounds; 2. The

Explain the following: 1. The destruction of ozone by chlorofluorocarbon (CFC) compounds; 2. The formation of HNO 3 and H 2 SO 4, respectively, in the atmosphere; 3. The destruction of marble structures by acid rains. 4. The use of quick lime (Ca. O) to remove toxic gas such as SO 2 from industrial flu-gas.

Exercise Consider the following apparatus containing helium in both sides at 45°C. Initially the

Exercise Consider the following apparatus containing helium in both sides at 45°C. Initially the valve is closed. After the valve is opened, what is the pressure of the helium gas? 2. 00 atm 9. 00 L 3. 00 atm 3. 00 L

Exercise A sample of helium gas occupies 12. 4 L at 23°C and 0.

Exercise A sample of helium gas occupies 12. 4 L at 23°C and 0. 956 atm. What volume will it occupy at 1. 20 atm assuming that the temperature stays constant? 9. 88 L

Exercise Suppose a balloon containing 1. 30 L of air at 24. 7°C is

Exercise Suppose a balloon containing 1. 30 L of air at 24. 7°C is placed into a beaker containing liquid nitrogen at – 78. 5°C. What will the volume of the sample of air become (at constant pressure)? 0. 849 L

Exercise If 2. 45 mol of argon gas occupies a volume of 89. 0

Exercise If 2. 45 mol of argon gas occupies a volume of 89. 0 L, what volume will 2. 10 mol of argon occupy under the same conditions of temperature and pressure? 76. 3 L

Exercise An automobile tire at 23°C with an internal volume of 25. 0 L

Exercise An automobile tire at 23°C with an internal volume of 25. 0 L is filled with air to a total pressure of 3. 18 atm. Determine the number of moles of air in the tire. 3. 27 mol

Exercise What is the pressure in a 304. 0 L tank that contains 5.

Exercise What is the pressure in a 304. 0 L tank that contains 5. 670 kg of helium at 25°C? 114 atm

Exercise At what temperature (in °C) does 121 m. L of CO 2 at

Exercise At what temperature (in °C) does 121 m. L of CO 2 at 27°C and 1. 05 atm occupy a volume of 293 m. L at a pressure of 1. 40 atm? 696°C

Exercise A sample of oxygen gas has a volume of 2. 50 L at

Exercise A sample of oxygen gas has a volume of 2. 50 L at STP. How many grams of O 2 are present? 3. 57 g

Exercise What is the density of F 2 at STP (in g/L)? 1. 70

Exercise What is the density of F 2 at STP (in g/L)? 1. 70 g/L