Nokea
Under which of the following conditions do real gases approach ideal behavior?
- A. At high pressure and high temperature
- B. At low pressure and high temperature
- C. Near the boiling point of water
- D. Real gases can never exhibit ideal behavior
Correct Answer: A
Rationale: Real gases approach ideal behavior at high pressure and high temperature. At these conditions, the volume of the gas molecules becomes negligible compared to the total volume of the gas. Additionally, the average distance between molecules becomes small enough for intermolecular forces to become less significant, leading to behavior that closely mirrors the assumptions of the ideal gas law. Choice B is incorrect because low pressure does not favor ideal behavior as the volume of gas molecules becomes more significant. Choice C is incorrect as the boiling point of water does not directly relate to ideal gas behavior. Choice D is incorrect because real gases can approach ideal behavior under specific conditions, such as high pressure and high temperature.
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If oxygen is in a compound, what would its oxidation number be?
- A. 2
- B. -2
- D. -1
Correct Answer: B
Rationale: Oxygen typically has an oxidation number of -2 in compounds because it tends to gain electrons. This is due to its high electronegativity, which leads to oxygen attracting electrons towards itself in a chemical bond. Choice A (2) is incorrect because oxygen doesn't have a +2 oxidation number in compounds. Choice C (0) is incorrect as oxygen rarely has an oxidation number of 0 in compounds. Choice D (-1) is incorrect as oxygen's oxidation number in compounds is typically -2, not -1.
Which law is expressed by the equation: Ptot = Pa + Pb, where P represents pressure, Ptot is the total pressure, and Pa and Pb are component pressures?
- A. Henry's law
- B. Dalton's law
- C. Boyle's law
- D. Gay-Lussac's law
Correct Answer: B
Rationale: The correct answer is B, Dalton's law. Dalton's law states that in a mixture of non-reacting gases, the total pressure is equal to the sum of the partial pressures of the individual gases. The equation Ptot = Pa + Pb represents Dalton's law, where Ptot is the total pressure, and Pa and Pb are the component pressures. Choice A, Henry's law, deals with the solubility of gases in liquids. Choice C, Boyle's law, describes the inverse relationship between the pressure and volume of a gas at constant temperature. Choice D, Gay-Lussac's law, states that the pressure of a gas is directly proportional to its absolute temperature when volume is constant.
Which, if any, of these statements about solubility is correct?
- A. The solubility of a substance is defined as its concentration in a saturated solution
- B. Substances with solubilities much less than 1 g/100 mL of solvent are generally considered insoluble
- C. A saturated solution is one that cannot dissolve any more solute
- D. All of these statements are correct
Correct Answer: D
Rationale: A. The solubility of a substance is indeed defined as the concentration of a solute that can be dissolved in a solvent to form a saturated solution at a specific temperature and pressure. B. Substances with solubilities much less than 1 g/100 mL of solvent are generally considered insoluble because they do not dissolve in significant amounts in the solvent. C. A saturated solution is one that cannot dissolve any more solute as it has reached its maximum capacity at a specific temperature and pressure. Therefore, all the statements provided are correct, making option D the correct answer.
What does the term amphoteric mean?
- A. A substance that only acts as a base
- B. A substance that can act as both a base and an acid
- C. A substance that only acts as an acid
- D. A substance that acts as neither a base nor an acid
Correct Answer: B
Rationale: The term 'amphoteric' refers to substances that have the ability to act as both acids and bases depending on the surrounding conditions. This dual nature allows amphoteric substances to donate or accept protons, making them versatile in various chemical reactions. Choice A is incorrect because amphoteric substances can also act as acids. Choice C is incorrect as amphoteric substances can also act as bases. Choice D is incorrect as amphoteric substances can act as either a base or an acid.
Which type of radiation emits helium ions and can be stopped by a piece of paper?
- A. Beta radiation
- B. Alpha radiation
- C. Gamma radiation
- D. X-ray radiation
Correct Answer: B
Rationale: Alpha radiation emits helium ions, which are helium nuclei without electrons, making them positively charged. These ions are relatively large and heavy compared to beta and gamma radiation. Due to their size and charge, alpha particles interact strongly with matter and are easily stopped. A piece of paper or even human skin can effectively block alpha radiation. Therefore, alpha radiation is the type of radiation that can be stopped by a piece of paper. Beta radiation consists of fast-moving electrons and can penetrate further into materials than alpha radiation, thus not stopped by a piece of paper. Gamma radiation is highly penetrating and requires dense materials like lead or concrete to block it effectively. X-ray radiation, similar to gamma radiation, is also highly penetrating and cannot be stopped by a piece of paper.