Deck 2: Water

A) A pH change from 5.0 to 6.0 reflects an increase in the hydroxide ion concentration ([OH^-]) of 20%.
B) A pH change from 8.0 to 6.0 reflects a decrease in the proton concentration ([H⁺]) by a factor of 100.
C) Charged molecules are generally insoluble in water.
D) Hydrogen bonds form readily in aqueous solutions.
E) The pH can be calculated by adding 7 to the value of the pOH.

A) are the driving force in the formation of micelles of amphipathic compounds in water.
B) do not contribute to the structure of water-soluble proteins.
C) have bonding energies of approximately 20-40 Kjoule per mole.
D) involve the ability of water to denature proteins.
E) primarily involve the effect of polar solutes on the entropy of aqueous systems.

A) Hydrogen bonds account for the anomalously high boiling point of water.
B) In liquid water, the average water molecule forms hydrogen bonds with three to four other water molecules.
C) Individual hydrogen bonds are much weaker than covalent bonds.
D) Individual hydrogen bonds in liquid water exist for many seconds and sometimes for minutes.
E) The strength of a hydrogen bond depends on the linearity of the three atoms involved in the bond.

A) 0.189 times the [H⁺] as the gastric juice.
B) 5.29 times lower [H⁺] than the gastric juice.
C) 6 times lower [H⁺] than the gastric juice.
D) 6000 times lower [H⁺] than the gastric juice.
E) one million times lower [H⁺] than the gastric juice.

A) A buffer composed of a weak acid of pK_a = 5 is stronger at pH 4 than at pH 6.
B) At pH values lower than the pK_a, the salt concentration is higher than that of the acid.
C) The pH of a buffered solution remains constant no matter how much acid or base is added to the solution.
D) The strongest buffers are those composed of strong acids and strong bases.
E) When pH = pK_a, the weak acid and salt concentrations in a buffer are equal.

A) charged solute molecule (ion) across a membrane.
B) gas molecule across a membrane.
C) nonpolar solute molecule across a membrane.
D) polar solute molecule across a membrane.
E) water molecule across a membrane.

A) binding of a hormone to its receptor protein.
B) enzyme-substrate interactions.
C) membrane structure.
D) three-dimensional folding of a polypeptide chain.
E) All of the answers are correct.

A) 1 M HCl.
B) 1 M NH₃ (pK_a = 9.25).
C) 0.5 M NaHCO₃ (pK_a = 3.77).
D) 0.1 M NaOH.
E) 0.001 M NaOH.

A) has the structure H₃O⁺.
B) is a hydrated hydrogen ion.
C) is a hydrated proton.
D) is the usual form of one of the dissociation products of water in solution.
E) All of the answers are correct.

A) acid A
B) Water is as good as either of the acids available.
C) acid B
D) Both are equally effective.

A) conversion of an acid anhydride to two acids
B) conversion of an ester to an acid and an alcohol
C) conversion of ATP to ADP
D) photosynthesis
E) production of gaseous carbon dioxide from bicarbonate

A) concentration of the water.
B) hydrogen bonding of the water.
C) ionic bonding of the water.
D) pH of the water.
E) temperature of the water.

A) H₃PO₄.
B) H₂PO₄^-.
C) HPO₄^2-.
D) PO₄^3-.
E) None of the answers is correct.

A) pH of buffer 1 < pH of buffer 2 < pH of buffer 3
B) pH of buffer 1 = pH of buffer 2 = pH of buffer 3
C) pH of buffer 1 > pH of buffer 2 > pH of buffer 3
D) The problem cannot be solved without knowing the value of pK_a.
E) None of the statements is true.

A) 5.60.
B) 8.90.
C) 9.13.
D) 9.32.
E) The pH cannot be determined from this information.

A) allows the graphic determination of the molecular weight of a weak acid from its pH alone.
B) does not explain the behavior of di- or tri-basic weak acids.
C) employs the same value for pK_a for all weak acids.
D) is equally useful with solutions of acetic acid and of hydrochloric acid.
E) relates the pH of a solution to the pK_a and the concentrations of acid and conjugate base.

A) pH remains constant.
B) pH rises more than if an equal amount of NaOH is added to an acetate buffer initially at pH 6.76.
C) pH rises more than if an equal amount of NaOH is added to unbuffered water at pH 4.76.
D) ratio of acetic acid to sodium acetate in the buffer falls.
E) sodium acetate formed precipitates because it is less soluble than acetic acid.

A) cohesion of liquid water due to hydrogen bonding
B) high heat of vaporization
C) high specific heat
D) the density of water being greater than the density of ice
E) the very low molecular weight of water

A) 6.5.
B) 6.8.
C) 7.2.
D) 7.4.
E) 7.5.

A) heating the solution
B) cooling the solution
C) lowering the pH of the solution
D) increasing the ionic strength of the solution
E) All of the answer choices would disrupt interactions between biomolecules

A) increases; decreases
B) increases; increases
C) decreases; decreases
D) decreases; increases
E) decreases; stabilizes

A) the dipole moment in a water molecule
B) the unshared electron pairs on the oxygen atom
C) the electronegativity difference between hydrogen and oxygen
D) the unequal electron sharing between hydrogen and oxygen
E) All of the answers are correct.

A) hydrogen donating an electron to oxygen.
B) oxygen donating an electron to hydrogen.
C) hydrogen receiving an electron from oxygen.
D) oxygen receiving an electron from hydrogen.
E) None of the answers is correct.

A) Fatty acids in small concentrations are surrounded by highly ordered water molecules in a "cage-like" structure.
B) Fatty acids will cluster together to minimize the lipid surface area.
C) Fatty acids will form micelles to sequester hydrophobic groups from water.
D) The driving force of solubilizing fatty acids is increasing entropy of the fatty acid.
E) All the statements are true.

A) hydrogen bonding, because it a strong non-covalent bond
B) hydrophobic interactions that increase solvent entropy
C) covalent interactions, because they are very stable interactions
D) electrostatic interactions between oppositely charged ions
E) van der Waals interactions, because of the attraction between transient dipoles

A) The properties of the bound water molecules are different from those of the "bulk" water of the solvent.
B) The bound water molecules may provide a path for "proton hopping."
C) The bound water molecules can form an essential part of the protein's ligand binding site.
D) The orientation of bound water molecules is precise.
E) All of the statements are true.

A) The electron clouds begin to repel each other.
B) The nuclei begin to repel each other.
C) The transient dipole is cancelled out by the neighboring atom.
D) The electron clouds begin to attract each other.
E) The nuclei begin to attract each other.

A) Head groups of the molecules are sequestered in the interior of the micelle, maximizing hydrogen bonding of the hydrophobic tail with surrounding solvent molecules.
B) Head groups of the molecules are exposed on the outer surface of the micelle, maximizing hydrogen bonding between hydrophobic tails.
C) Head groups of the molecules are exposed on the outer surface of the micelle, minimizing the order of the surrounding solvent molecules.
D) Hydrophilic tails are exposed on the outer surface of the micelle, maximizing hydrogen bonding between the tails and surrounding solvent molecules.
E) Hydrophobic tails are exposed on the outer surface of the micelle, maximizing hydrogen bonding between head groups.

A) A
B) B
C) both A and B
D) neither A nor B

A) The cell is in a hypotonic solution; water will move in and cause the cell to swell.
B) The cell is in a hypotonic solution; solutes will move in and cause the cell to swell.
C) The cell is in a hypotonic solution; water will move out and cause the cell to shrink.
D) The cell is in a hypertonic solution; solutes will move in and cause the cell to swell.
E) The cell is in a hypertonic solution; water will move out and cause the cell to shrink.

A) covalent bond > hydrogen bond > ionic bond > van der Waals interaction
B) covalent bond > ionic bond > hydrogen bond > van der Waals interaction
C) ionic bond > covalent bond > hydrogen bond > van der Waals interaction
D) covalent bond > van der Waals interaction > ionic bond > hydrogen bond
E) hydrogen bond > ionic bond > van der Waals interaction > covalent bond

A) O₂ and CO₂ are the most important gases for living things and are therefore very soluble in water.
B) O₂ and CO₂ are both polar and are therefore very soluble in water.
C) O₂ and CO₂ are both nonpolar molecules and are therefore both poorly soluble in water.
D) CO₂ contains polar bonds but O₂ is nonpolar; therefore, CO₂ is very soluble in water, but O₂ is poorly soluble in water.
E) All biologically important gases are very soluble in water.

A) the geometry of the molecule
B) the polarity of the molecule
C) the ability of water molecules to hydrogen bond
D) the dipole moment in a water molecule
E) All of the answers are correct.

A) M NaCl (MW = 58 g/mol)
B) M CaCl₂ (MW = 111 g/mol)
C) M glucose (MW = 180 g/mol)
D) M sucrose (MW = 342 g/mol)
E) All of the answer choices would have the same effect.

A) Hydrogen bonds are highly directional.
B) Hydrogen bonds are capable of holding molecules in a specific geometric arrangement.
C) Hydrogen bonds are strongest when the three atoms in the bond are in a straight line.
D) Hydrogen bonds are strongest when the oxygen atom is perpendicular to the hydrogen donor.
E) Hydrogen bonds place a hydrogen ion directly between two partial negative charges.

A) shorter; pulled together by the shared electron pair
B) shorter; pulled together by the attraction of the nucleus to the bonded atom
C) shorter; pulled together by hydrogen bonding
D) longer; repelled due to the shared electron pair
E) longer; repelled due to the nuclear repulsion between bonded atoms

A) less dense; frozen water maintains more hydrogen bonds than liquid water
B) less dense; liquid water maintains more hydrogen bonds than frozen water
C) denser; frozen water maintains more hydrogen bonds than liquid water
D) denser; liquid water maintains more hydrogen bonds than frozen water
E) denser; frozen water cannot hydrogen bond

A) CH₂O
B) CH₄
C) NH₃
D) CH₃CH₂OH
E) None of the answers is correct.

A) A and D
B) A and C
C) B and C
D) C and D
E) B and D

A) -4.25
B) 4.25
C) 5.65
D) -9.75
E) 9.75

A) 0.3 M to 0.8 M OH.
B) 0.9 to 1.0 M OH.
C) pH 3.5 to pH 4.2.
D) pH 2.8 to pH 3.8.
E) pH 2.8 to pH 4.8.

A) weak; resists change when 50% titrated.
B) strong; resists change when 50% titrated.
C) weak; changes dramatically when 100% titrated.
D) strong; changes dramatically when 100% titrated.
E) It cannot be determined from the information given.

A) when the concentration of acid is close to zero
B) when the pH approaches 7
C) when the concentration of the conjugate base is equal to the ionization constant for water
D) when the concentration of the conjugate base is equal to the concentration of the acid.
E) None of the answers is correct.

A) an individual proton "jumps" from one electronegative group to the next.
B) a free proton moves from one hydroxyl group of ionized water to the next.
C) several protons move between hydrogen bonded water molecules causing the net movement of a photon over a long distance in a short time.
D) individual protons are freer to move among and between water molecules in solution.
E) hydronium ions are freer to move among and between water molecules in solution.

A) intravenous administration of bicarbonate
B) hyperventilating
C) breathing into a paper bag
D) vigorous exercise
E) All of these treatments/actions could be used to counteract acidosis.

A) 6.31 × 10^-11 M
B) 1.58 × 10^-4 M
C) 1.58 × 10^-5 M
D) 1.02 × 10^-3 M
E) 6.31 × 10^-4 M

A) 0.2.
B) 0.5.
C) 3.2.
D) 3.8.
E) 4.8.

A) -9.37
B) 9.37
C) -4.63
D) 4.63
E) 13.4

A) acetic acid, carbonic acid, nitrous acid, phosphoric acid
B) carbonic acid, acetic acid, nitrous acid, phosphoric acid
C) acetic acid, nitrous acid, carbonic acid, phosphoric acid
D) phosphoric acid, nitrous acid, acetic acid, carbonic acid
E) carbonic acid, phosphoric acid, nitrous acid, acetic acid

A) H₃PO₄.
B) H₂PO₄^2-.
C) HPO₄^2-.
D) HPO₄^3-.
E) PO₄^3-.

A) Ephedrine can more easily pass through the cell membrane than epinephrine.
B) Epinephrine can more easily pass through the cell membrane than ephedrine.
C) Both epinephrine and ephedrine can pass through the cell membrane equally well.
D) Neither epinephrine nor ephedrine can pass through the cell membrane.
E) None of the statements is true.

A) 6.86
B) 7.14
C) 8.68
D) 10.7
E) 1.38

A) CH₃COOH
B) NH₄⁺
C) H₂CO₃
D) H₃PO₄
E) CH₃CH₂OH

A) 8.90
B) 4.45
C) 3.75
D) 2.2 Ionization of Water, Weak Acids, and Weak Bases2
E) 1.72

A) 11.3
B) 10.5
C) 8.2
D) 5.7
E) 2.9

A) 8.5
B) -5.5
C) -8.5
D) 14
E) 6.5

A) More ibuprofen will be absorbed in the small intestine because it will be uncharged due to the pH being greater than the pK_a^.
B) More ibuprofen will be absorbed in the stomach because it will be uncharged due to the pH being lower than the pK_a.
C) More ibuprofen will be absorbed in the small intestine because it will be charged due to the pH being greater than the pK_a.
D) More ibuprofen will be absorbed in the stomach because it will be charged due to the pH being lower than the pK_a.
E) Ibuprofen will be absorbed equally well in both the stomach and small intestine.

A) Cells have a contractile vacuole, an organelle that pumps water out of the cell.
B) Animals have a high concentration of albumin and other proteins in blood plasma.
C) Cells actively pump out Na⁺ and other ions.
D) Cells store fuel as a polysaccharide instead of as simple sugars.
E) All of the statements describe a strategy to maintain osmotic balance.

A) 2.4 Water as a Reactant0 × 10⁰ M
B) 2.5 The Fitness of the Aqueous Environment1 × 10^-12 M
C) 2.5 The Fitness of the Aqueous Environment1 × 10^-3M
D) 3.98 × 10^-3 M
E) 3.98 × 10^-6 M

A) histidine.
B) bicarbonate.
C) phosphate.
D) bicarbonate and phosphate.
E) histidine, bicarbonate, and phosphate.

A) Metabolic water is produced by oxidation of fuels such as glucose.
B) Metabolic water is produced by acid/base dehydration reactions.
C) Metabolic water is produced by symbiotic bacteria in the camel's gut.
D) Metabolic water is produced by splitting carbon dioxide.
E) None of the answers is correct.

A) CO₂ can be directly bound to hemoglobin for transport.
B) CO₂ can be converted to the more soluble CO for transport.
C) CO₂ can be converted to the more soluble HCO₃^-1 for transport.
D) CO₂ can be bound by erythrocytes for transport.
E) CO₂ is only produced in the lungs.

A) a solvent
B) a reactant
C) a product
D) both a solvent and reactant
E) a solvent, reactant, and product

A) Water has a high specific heat.
B) Water has an extended hydrogen-bonding network.
C) Water can auto-ionize.
D) A large amount of heat is required to raise the temperature of water by 1 °C.
E) All of the statements describe reasons that water can act as a heat buffer.

A) Water has a high specific heat.
B) Water has a high heat of vaporization.
C) Due to hydrogen bonding, solid water is less dense than liquid water.
D) Water has a high melting point.
E) Nonpolar molecules are poorly soluble in water.

A) Plants can transport dissolved nutrients from roots to leaves.
B) Water can combine with carbon dioxide to form glucose.
C) Loss of water causes lettuce leaves to wilt.
D) Water is split by the energy of sunlight through photosynthesis.
E) Water can be used as a product in respiration.

A) A = hydrolysis, B = condensation
B) A = condensation, B = hydrolysis
C) A = dehydrolysis, B = condensation
D) A = phosphorylation, B = phosphatase
E) A = metabolism, B = catabolism