4.3 Carbon Cycling

Question 1

What is the carbon cycle?

Answer 1

The carbon cycle is a biogeochemical cycle whereby carbon is exchanged between the different spheres of the Earth

Question 2

What are the four spheres?

Answer 2

The four spheres are the atmosphere (air), lithosphere (ground), hydrosphere (water / oceans) and biosphere (living things)

Question 3

In what 4 forms can carbon be exchanged?

Answer 3

atmospheric gases
oceanic carbonates
organic materials
non-living remains

Question 4

In what form can carbon be found in atmospheric gases?

Answer 4

mainly carbon dioxide (CO2), but also methane (CH4)

Question 5

In what form can carbon be found in atmospheric gases?

Answer 5

mainly carbon dioxide (CO2), but also methane (CH4)

Question 6

In what form can carbon be found in oceanic carbonates?

Answer 6

including bicarbonates dissolved in the water and calcium carbonate in corals and shells

Question 7

In what form can carbon be found in organic materials?

Answer 7

including the carbohydrates, lipids and proteins found in all living things

Question 8

In what form can carbon be found in living remains?

Answer 8

as detritus and fossil fuels

Question 9

How do autotrophs convert inorganic compounds?

Answer 9

Autotrophs, such as all plants and algae, convert inorganic carbon dioxide into organic compounds via photosynthesis

Question 10

What organic compounds is CO2 converted into via photosynthesis?

Answer 10

These organic compounds include the carbohydrates, lipids and proteins required by the organism for survival

Question 11

What levels of CO2 should autotrophs have?

Answer 11

Since autotrophs use carbon dioxide for photosynthesis, the levels of carbon dioxide within the organism should always be low

Question 12

In which sphere should there be a higher conc of CO2?

Answer 12

In other words, carbon dioxide should always be at a higher concentration in the atmosphere (or water)

Question 13

What does the differing concentration of CO2 ensure?

Answer 13

This concentration gradient ensures that carbon dioxide will passively diffuse into the autotrophic organism as required

Question 14

How does diffusion of CO2 differ in aquatic and terrestrial autotrophs?

Answer 14

In aquatic producers, CO2 can usually diffuse directly into the autotroph; whereas in terrestrial plants, diffusion occurs at stomata

Question 15

What do all organisms produce to survive?

Answer 15

All organisms may produce the chemical energy (ATP) required to power metabolic processes via the process of cell respiration

Question 16

What does cell respiration involve?

Answer 16

Cell respiration involves the breakdown of organic molecules (e.g. sugars) and produces carbon dioxide as a by-product

Question 17

What is a result of respiration? How is this useful?

Answer 17

The build up of CO2 in respiring tissues creates a concentration gradient, allowing it to be removed by passive diffusion

Question 18

In autotrophs, what may happen in relation to these two processes?

Answer 18

In autotrophs, the uptake of CO2 by photosynthesis may at times be balanced by the production of CO2 by respiration

Question 19

What is it called when rate of photosynthesis=rate of respiration?

Answer 19

This is known as the compensation point, at which the net carbon dioxide assimilation is zero (intake = output)

Question 20

What determines the level of carbon dioxide in the environment? (2 relating to net ___)

Answer 20

If there is more net photosynthesis than cell respiration occuring in the biosphere, atmospheric carbon dioxide levels should drop

If there is more net respiration than overall photosynthesis occuring, atmospheric carbon dioxide levels should increase

Question 21

What happens when Co2 dissolves in water?

Answer 21

Carbon dioxide dissolves in water and some of it will remain as a dissolved gas, however the remainder will combine with water to form carbonic acid

Question 22

Give equation for CO2 dissolving in water

Answer 22

CO2 + H2O ⇄ H2CO3

Question 23

What happens to carbonic acid + equation?

Answer 23

Carbonic acid will then dissociate to form hydrogen carbonate ions (H2CO3 ⇄ HCO3– + H+)

Question 24

What causes the change in pH of the ocean?

Answer 24

This conversion (H2CO3) also releases hydrogen ions (H+), which is why pH changes when CO2 is dissolved in water (> acidic)

Question 25

What do autotrophs absorb in relation to ocean CO2?

Answer 25

Autotrophs absorb both dissolved carbon dioxide and hydrogen carbonate ions and use them to produce organic compounds

Question 26

What can hydrogen carbonate ions come into contact with in the ocean?

Answer 26

When the hydrogen carbonate ions come into contact with the rocks and sediments on the ocean floor, they acquire metal ions

Question 27

What can the contact between HCO3- ions with rocks and sediments form?

Answer 27

This commonly results in the formation of calcium carbonate and the subsequent development of limestone

Question 28

How can CaCO3 be formed in oceans?

Answer 28

Living animals may also combine the hydrogen carbonate ions with calcium to form calcium carbonate

Question 29

What is the use of calcium carbonate in aquatic environments?

Answer 29

This calcium carbonate forms the hardened exoskeleton of coral, as well as forming the main component of mollusca shells

Question 30

What happens to the calcium carbonate when an organism dies?

Answer 30

When the organism dies and settles to the sea floor, these hard components may become fossilised in the limestone

Question 31

What are methanogens?

Answer 31

Methanogens are archaean microorganisms that produce methane (CH4) as a metabolic by-product in anaerobic conditions

Question 32

Where can methanogens be found?

Answer 32

Anaerobic conditions where methanogens may be found include: Wetlands (e.g. swamps and marshes) Marine sediments (e.g. in the mud of lake beds) Digestive tract of ruminant animals (e.g. cows, sheep, goats)

Question 33

What do methanogens produce and how?

Answer 33

Methanogens produce methane from the by-products of anaerobic digestion, principally acetic acid and carbon dioxide:

Question 34

How is acetic acid used in methanogens? give equation

Answer 34

Acetic acid → Methane and Carbon Dioxide (CH3COO– + H+ → CH4 + CO2)

Question 35

How is CO2 and H2O used by methanogens? Give equation

Answer 35

Carbon Dioxide and Hydrogen → Methane and Water (CO2 + 4 H2 → CH4 + 2 H2O)

Question 36

What happens to released methane?

Answer 36

Methane may either accumulate under the ground or diffuse into the atmosphere

Question 37

How may natural gas be formed?

Answer 37

When organic matter is buried in anoxic conditions (e.g. sea beds), deposits of methane (natural gas) may form underground

Question 38

What may be increasing global levels of methane?

Answer 38

Rising global numbers of domesticated cattle may be increasing the levels of methane being released into the atmosphere

Question 39

How long does methane persist in the atmosphere?

Answer 39

When methane is released into the atmosphere as a result of anaerobic reactions, it only persists for ~12 years

Question 40

Why are methane levels in the atmosphere are not very large, even though significant quantities are being produced ?

Answer 40

Methane will be naturally oxidised to form carbon dioxide and water (CH4 + 2 O2 → CO2 + 2 H2O)

Question 41

What is methane oxidised to? Give equation

Answer 41

Methane will be naturally oxidised to form carbon dioxide and water (CH4 + 2 O2 → CO2 + 2 H2O)

Question 42

How are nutrients recycled in soil?

Answer 42

In many soils, saprotrophic bacteria and fungi will decompose dead organisms and return nutrients to the soil for cycling

Question 43

What does the process of decomposition require?

Answer 43

This decomposition process requires oxygen (cell respiration is required to fuel digestive reactions)

Question 44

Where is aerobic decomposition not possible?

Answer 44

Waterlogged regions may lack oxygenated air spaces within the soil and thus possess anaerobic conditions

Question 45

What does anaerobic respiration form?

Answer 45

Anaerobic respiration by organisms in these regions produces organic acids (e.g. acetate), resulting in acidic conditions

Question 46

What do the acidic conditions (in soils) prevent?

Answer 46

Saprotrophic bacteria and fungi cannot function effectively in anaerobic / acidic conditions, preventing decomposition

Question 47

What is formed due to the incomplete decomposition of organic matter?

Answer 47

Since the organic matter is not fully decomposed in waterlogged soils, carbon-rich molecules remain in the soil and form peat

Question 48

What happens when peat is compressed?

Answer 48

When deposits of peat are compressed under sediments, the heat and pressure force out impurities and remove moisture

Question 49

How is coal produced from peat?

Answer 49

The remaining material has a high carbon concentration and undergoes a chemical transformation to produce coal

Question 50

In general, how is oil and natural gas formed?

Answer 50

Oil (i.e. petroleum) and natural gas form as the result of the decay of marine organisms on the ocean floor

Question 51

In aquatic ecosystems, what is deposited upon organic matter to start the formation of oil/natural gas?

Answer 51

Sediments (e.g. clay and mud) are deposited on top of the organic matter, creating anoxic conditions that prevent decomposition

Question 52

What is a result of the material compaction in aquatic ecosystems?

Answer 52

As a result of the burial and compaction, the organic material becomes heated and hydrocarbons are formed

Question 53

What do the hydrocarbons form? (aquatic ecosystem)

Answer 53

The hydrocarbons form oil and gas, which are forced out of the source rock and accumulate in porous rocks (e.g. sandstone)

Question 54

How long does it take for various fossil fuels to be formed?

Answer 54

The formation of fossil fuels (coal, oil and gas) takes place over millions of years, making them a non-renewable energy source

Question 55

What is a combustion reaction? (conditions)

Answer 55

When organic compounds rich in hydrocarbons are heated in the presence of oxygen, they undergo a combustion reaction

Question 56

What type of reaction is combustion?

Answer 56

This reaction is exergonic (produces energy) and releases carbon dioxide and water as by-products

Question 57

What happens to the carbon dioxide produced by combustion?

Answer 57

The carbon dioxide is typically released into the atmosphere, increasing the concentration of the gas in the air

Question 58

What happens to organic compounds when they're compacted for millions of years?

Answer 58

Organic compounds can become rich in hydrocarbons when compacted underground for millions of years

Question 59

What does compaction trigger in order to make organic matter rich in hydrocarbons?

Answer 59

The heat and pressure over time triggers a chemical transformation that results in the compaction of the organic matter

Question 60

What is produced by the compaction of organic matter?

Answer 60

The resulting products of this process are fossil fuels (coal, oil and natural gas)

Question 61

Why are fossil fuels considered non-renewable?

Answer 61

Because this geological process takes millions of years to occur, fossil fuels are a non-renewable energy source

Question 62

What is another way to manufacture fuels, reducing dependence on fossil fuels?

Answer 62

An alternative to relying on fuels produced by geological processes is to manufacture fuels from biological processes

Question 63

What do living organisms produce which are useful for fuels?

Answer 63

Living organisms produce hydrocarbons as part of their total biomass (either for use or as a waste product)

Question 64

What can be done with the hydrocarbons produced by organisms?

Answer 64

These hydrocarbons can be extracted and purified to produce an alternative fuel source (e.g. bioethanol and biodiesel)

Question 65

Why is biomass considered a "better" fuel source?

Answer 65

Provided new raw materials are provided and waste products are removed, this source of energy is renewable

Question 66

What are carbon fluxes?

Answer 66

Carbon fluxes describe the rate of exchange of carbon between the various carbon sinks / reservoirs

Question 67

What are the 4 main carbon sinks?

Answer 67

There are four main carbon sinks – lithosphere (earth crust), hydrosphere (oceans), atmosphere (air), biosphere (organisms)

Question 68

What does the rate of carbon exchange depend on?

Answer 68

The rate at which carbon is exchanged between these reservoirs depends on the conversion processes involved

Question 69

What is the role of photosynthesis in the carbon cycle?

Answer 69

removes carbon dioxide from the atmosphere and fixes it in producers as organic compounds

Question 70

What is the role of respiration in the carbon cycle?

Answer 70

releases carbon dioxide into the atmosphere when organic compounds are digested in living organisms

Question 71

What is the role of decomposition in the carbon cycle?

Answer 71

releases carbon products into the air or sediment when organic matter is recycled after death of an organism

Question 72

What is the role of gaseous disolution in the carbon cycle?

Answer 72

the exchange of carbon gases between the ocean and atmosphere

Question 73

What is the role of lithification in the carbon cycle?

Answer 73

the compaction of carbon-containing sediments into fossils and rocks within the Earth’s crust (e.g. limestone)

Question 74

What is the role of combustion in the carbon cycle?

Answer 74

releases carbon gases when organic hydrocarbons (coal, oil and gas) are burned as a fuel source

Question 75

Is it possible to measure the size of carbon sinks?

Answer 75

NO It is not possible to directly measure the size of the carbon sinks or the fluxes between them – instead estimates are made

Question 76

How are global carbon fluxes measured?

Answer 76

Global carbon fluxes are very large and are therefore measured in gigatonnes (1 gigatonne of carbon = 1 billion metric tonnes)

Question 77

Are carbon flux calculations accurate?

Answer 77

Because carbon fluxes are large and based on measurements from many different sources, estimates have large uncertainties

Question 78

What does estimating carbon fluxes require?

Answer 78

estimating carbon fluxes requires an understanding of the factors that can affect the exchange of carbon between different sinks

Question 79

What are some of the main causes for flux changes?

Answer 79

Some of the main causes for flux change include climate conditions, natural events and human activity

Question 80

Climate conditions | When will rates of photosynthesis be higher?

Answer 80

Rates of photosynthesis will likely by higher in summer seasons, as there is more direct sunlight and longer days

Question 81

cc | how do oceanic temepratures affect co2?

Answer 81

Oceanic temperatures also determine how much carbon is stored as dissolved CO2 or as hydrogen bicarbonate ions

Question 82

cc | how do climate events change carbon flux?

Answer 82

Climate events like El Nino and La Nina will change the rate of carbon flux between ocean and atmosphere

Question 83

cc | how does the melting of polar ice caps affect carbon fluxes?

Answer 83

Melting of polar ice caps will result in the decomposition of frozen detritus

Question 84

what two natural events can affect co2 concentrations?

Answer 84

forest fires | volcanic eruptions

Question 85

How do forest fires affect co2 conc?

Answer 85

Forest fires can release high levels of carbon dioxide when plants burn (loss of trees also reduces photosynthetic carbon uptake)

Question 86

How do volcanic eruptions affect carbon dioxide concentration?

Answer 86

Volcanic eruptions can release carbon compounds from the Earth’s crust into the atmosphere

Question 87

What 3 human activities affect carbon dioxide concentration?

Answer 87

clearing of trees ruminant livestock fossil fuels

Question 88

How does clearing of trees affect co2 conc?

Answer 88

Clearing of trees for agricultural purposes (deforestation) will reduce the removal of atmospheric CO2 via photosynthesis

Question 89

How does increased number of ruminant livestock affect co2 conc?

Answer 89

Increased numbers of ruminant livestock (e.g. cows) will produce higher levels of methane

Question 90

Who has measured atmospheric co2 concs and where?

Answer 90

Atmospheric CO2 concentrations have been measured at the Mauna Loa Observatory (in Hawaii) since 1958 by Charles Keeling

Question 91

(findings from Charles Keeling) | how often do co2 levels flc=uctuate?

Answer 91

CO2 levels fluctuate annually (lower in the summer months when long days and more light increase photosynthetic rates)

Question 92

(findings from Charles Keeling) | WHat will global co2 patterns conform to and why?

Answer 92

Global CO2 trends will conform to northern hemisphere patterns as it contains more of the planet’s land mass (i.e. more trees)

Question 93

(findings from Charles Keeling) | How are CO2 levels changing?

Answer 93

CO2 levels are steadily increasing year on year since the industrial revolution (due to increased burning of fossil fuels)

Question 94

(findings from Charles Keeling) | How are CO2 levels now?

Answer 94

Atmospheric CO2 levels are currently at the highest levels recorded since measurements began

Question 95

Why may different monitoring stations have different trends in CO2?

Answer 95

Different monitoring stations may have slightly different trends due to seasonal variations and the distribution of local vegetation