Deck 7: Photosynthesis: Using Light to Make Food

A) stroma
B) thylakoid membranes
C) cytoplasm
D) cristae

A) water.
B) glucose.
C) carbon dioxide.
D) chlorophyll.

A) chemosynthetic autotrophs.
B) photoautotrophs.
C) fungi.
D) heterotrophs.

A) grass on the front lawn
B) grizzly bears in Alaska
C) bacteria in our mouths
D) mushrooms growing on the side of a dead tree

A) light
B) NADPH
C) cellular respiration
D) ATP

A) cristae.
B) stomata.
C) grana.
D) vacuoles.

A) CO2
B) glucose
C) O2
D) chlorophyll

A) stomata.
B) thylakoid.
C) matrix.
D) stroma.

A) H and O both in glucose
B) H in glucose; O in water
C) H in water; O in glucose
D) H in glucose and water; O in O2

A) mitochondria that had a mutation for photosynthesis
B) photosynthetic prokaryotes that lived inside eukaryotic cells
C) prokaryotes with photosynthetic mitochondria
D) eukaryotes that engulfed photosynthetic fungi

A) glucose, ADP, NADP+
B) glucose, ADP, NADP+, CO2
C) ADP, NADP+, O2
D) ATP, NADPH, O2

A) Photosynthesis involves only reductions, whereas respiration involves only oxidations.
B) Photosynthesis involves only oxidations, whereas respiration involves only reductions.
C) In photosynthesis, carbon dioxide is oxidized to form sugar, whereas in respiration, sugar is reduced to form carbon dioxide.
D) In photosynthesis, carbon dioxide is reduced to form sugar, whereas in respiration, sugar is oxidized to form carbon dioxide.

A) stomata.
B) thylakoids.
C) grana.
D) stroma.

A) concentrated in a zone of leaf tissue called the mesophyll.
B) concentrated in a portion of the leaf called the stroma.
C) evenly distributed throughout the leaf tissue.
D) evenly distributed throughout the entire plant.

A) make sugar by using organic raw materials.
B) produce organic molecules from inorganic molecules.
C) eat other organisms that use light energy to make food molecules.
D) include only the green plants.

A) chemotrophs
B) heterotrophs
C) autotrophs

A) ATP is not produced during photosynthesis; it is produced only during cellular respiration.
B) Photosynthesis is ultimately powered by light energy and respiration by the chemical energy of fuel molecules.
C) Photosynthesis consumes CO2; respiration consumes O2.
D) Photosynthesis produces O2; respiration produces CO2.

A) Stomata
B) Mesophyll
C) Vein

A) oxygen.
B) water.
C) an electron.
D) a proton

A) an antenna.
B) a propeller on a motorboat.
C) a windmill.
D) a spring.

A) It takes several minutes for the pigment electrons to become excited.
B) Photons raise electrons in pigments to the ground state.
C) Excitation of the electrons is a very stable state.
D) Energy can be released by the excited electron as heat, light, or fluorescence.

A) blue
B) red
C) orange
D) green

A) Chlorophyll a reflects green light.
B) Chlorophyll a absorbs green light.
C) Chlorophyll b primarily uses green light as the source of energy for photosynthesis.
D) Green helps plants blend into their environment as a sort of camouflage.

A) carbon fixation
B) reduction of carbon
C) regeneration of NADP+
D) formation of waste products in the form of O2

A) mitochondria.
B) chlorophyll.
C) carotenoids.
D) ATP.

A) glucose, ADP, NADP+
B) glucose, ADP, NADP+, CO2
C) ATP, NADPH, O2
D) ATP, NADPH, CO2

A) electromagnetic
B) chemical
C) mechanical

A) chlorophyll b
B) chlorophyll a
C) a carotenoid

A) pass energy to the reaction center.
B) are found in the roots of plants.
C) absorb electrons.
D) break down H2O.

A) is best at absorbing the energy of green light.
B) is best at absorbing the energy of blue-violet and red light, just like chlorophyll a.
C) passes absorbed energy to chlorophyll a.
D) catalyzes the incorporation of carbon atoms into RuBP.

A) NADPH is reduced to NADP+.
B) NADPH is oxidized to NADP+.
C) NADP+ is reduced to NADPH.
D) NADP+ is oxidized to NADPH.

A) electrons passing down the electron transport chain.
B) ATP.
C) photons.
D) NADPH.

A) visible
B) electromagnetic
C) energy
D) ultraviolet

A) CO2.
B) H2O.
C) ATP.
D) photosystem II.

A) blue
B) green
C) yellow
D) red

A) occurs when carbon atoms from CO2 are incorporated into an organic molecule.
B) supplies the cell with ATP.
C) occurs during the light reactions.
D) provides the cell with a supply of NADPH molecules.

A) is located in the stroma.
B) shuttles electrons from photosystem II to photosystem I.
C) provides energy for the citric acid cycle.
D) is found on the plasma membrane of mesophyll cells.

A) quantum.
B) pigment.
C) photon.
D) phaser.

A) CO2 and chlorophyll
B) glucose and O2
C) O2 and CO2
D) glucose and CO2

A) cellular respiration.
B) photorespiration.
C) photophosphorylation.
D) aerobic respiration.

A) power sugar synthesis during the Calvin cycle.
B) are products of the Calvin cycle.
C) provide energy to photosystem I and photosystem II.
D) are used in the electron transport chain to pump H+ into the thylakoid space.

A) They help the plant synthesize glucose efficiently under dry conditions.
B) They allow the plant to fix carbon under conditions of low CO2.
C) They allow the plant to fix carbon in cool conditions.
D) They make it possible for the plant to use the Calvin cycle at night.

A) requires oxygen.
B) is similar to the production of ATP in mitochondria.
C) is done by the Calvin cycle.
D) is a result of the oxidation of glucose.

A) may be an evolutionary relic from when atmospheric O2 levels were low.
B) is of benefit to the plant since it breaks down rubisco.
C) is attributable to high CO2 levels.
D) produces glucose.

A) Forests play too minor a role in global CO2 dynamics, which are affected far more by marine algae.
B) Young trees fix carbon at a lower rate per unit mass than old trees.
C) Most of the biomass of the cut trees would be added to the atmosphere as CO2 within a few years.
D) Most of the young trees would die within a few years.

A) fuel for photosynthesis.
B) starting material for the Calvin cycle.
C) source of electrons for chemiosmosis.
D) fuel for cellular respiration and a starting material for making other organic molecules.

A) receives electrons from photosystem I.
B) passes electrons to photosystem I.
C) does not have a reaction center.
D) releases CO2 as a by-product.

A) The greenhouse effect is reduced by deforestation.
B) The greenhouse effect is exacerbated by the use of fossil fuels.
C) The greenhouse effect will decrease the average temperature of the planet.
D) The greenhouse effect decreases plant growth.

A) cellular respiration.
B) photosynthesis.
C) glycolysis.
D) anaerobic metabolism.

A) moderated by photosynthesis, which removes carbon dioxide from the atmosphere.
B) made worse by photosynthesis, which adds carbon dioxide to the atmosphere.
C) reduced by the burning of fossil fuels, which removes oxygen from the atmosphere.
D) of little concern, since it is part of the normal cycle for the planet.

A) catalyzes the Calvin cycle.
B) phosphorylates ADP to ATP.
C) is found in the stroma.
D) helps produce the concentration gradient of H+.

A) two
B) four
C) six
D) eight

A) electrons; grana; H+
B) H+; grana; electrons
C) H+; stroma; H+
D) H+; stroma; ATP

A) chemical; food; light
B) food; light; chemical
C) light; food; kinetic
D) food; light; nuclear

A) CO2.
B) ATP.
C) H2O.
D) photosystem I.

A) carbon monoxide.
B) carbon dioxide.
C) hydrocarbons.
D) methane.

A) it involves an electron transport chain.
B) energy is stored in the form of a proton (H+) concentration difference.
C) generation of ATP is driven by a flow of protons (H+) through ATP synthase.
D) the final electron acceptor is NADP+ and not oxygen.

A) lack mitochondria and chloroplasts.
B) lack mitochondria but have chloroplasts.
C) have mitochondria but do not have chloroplasts.
D) have mitochondria and chloroplasts.

A) G3P
B) ATP
C) NADH
D) carbon dioxide

A) there is a correlation between CO2 and temperature; when CO2 levels are high, so is temperature.
B) there is a correlation between CO2 and temperature; when CO2 levels are high, temperature is low.
C) there is no correlation between CO2 and temperature; CO2 fluctuates randomly and temperature is constant.
D) there is no correlation between CO2 and temperature; CO2 is constant and temperature fluctuates randomly.

A) Energy in sunlight directly becomes ATP molecules in photosynthesis.
B) ATP is made up of chemical energy which is transferred to sugar.
C) Energy in sunlight is transformed into chemical energy when electrons move to a more excited state.
D) Matter in ATP is transferred to sugars in photosynthesis when electrons from ATP become part of sugars.

A) Both this proposed process and photosynthesis store solar energy as electricity for later use.
B) Both this proposed process and photosynthesis split water into hydrogen and oxygen.
C) The mimic leaves would have to be green like photosynthesizing leaves in order to respond to light.
D) Both processes convert electrical energy to light energy.

A) extreme weather patterns
B) lower sea levels
C) spread of tropical diseases
D) increased extinction rates

A) Plants turn sunlight into sugars.
B) The majority of the mass of plant-made sugars comes from water and nutrients from the soil.
C) The majority of the mass of plant-made sugars comes from the atmosphere.
D) Plants make sugars by breaking down other organic molecules and using those components to make sugars.

A) Black plants would heat up faster and therefore all chemical reactions including photosynthesis would operate faster.
B) A black plant would reflect all wavelengths and therefore have more energy to drive photosynthesis.
C) A black plant would absorb all wavelengths and therefore absorb more light energy that powers photosynthesis.
D) A black plant would absorb green wavelengths like most plants, but would absorb them more efficiently.

A) 1, 2, 3, 4
B) 1, 4, 2, 3
C) 2, 4, 1, 3
D) 2, 3, 1, 4

A) O2.
B) CO2.
C) H2O.
D) C6H12O6.

A) C3 plants, such as wheat and rice
B) C3 plants and C4 plants, such as corn and sugarcane
C) C3 plants and CAM plants, such as prickly pear and pineapple
D) C4 plants and CAM plants

A) random experimental error
B) an increase in atmospheric CO2 levels
C) There were more poison ivy plants in the control plots to begin with.

A) In some years of the study the mean poison ivy biomass decreased to the level it was at the beginning of the study.
B) There were more elevated CO2 plots than control plots.
C) Not all of the increase in mean poison ivy biomass can be attributed to the CO2 that the researcher added.
D) Poison ivy in the experimental plots was more toxic than that in the control plots.

A) red
B) yellow
C) green
D) blue

A) thylakoids; chloroplasts; mesophyll
B) chloroplasts; thylakoids; mesophyll
C) mesophyll; chloroplasts; thylakoids
D) mesophyll; thylakoids; chloroplasts

A) structure A
B) structure B
C) structure C
D) structure D

A) NADPH.
B) G3P.
C) ATP.
D) O2.

A) through photosystem I
B) through an electron transport chain molecule
C) through the ATP synthase
D) directly through the phospholipids of the thylakoid membrane

A) 1, 2, 3, 4
B) 1, 3, 4, 2
C) 1, 4, 3, 2
D) 4, 1, 2, 3

A) 100 ppm
B) 200 ppm
C) 600 ppm
D) 1,000 ppm

A) Algal photosynthesis would use up more CO2, which traps heat.
B) Algal photosynthesis would produce more O2, which blocks light.
C) Algal photosynthesis would be inhibited by the addition of fertilizer.
D) Algae photosynthesis would use heat in place of photons.

A) S2
B) SO2
C) CS2
D) C6H12S6