5B - Energy Transfer and Nutrient Cycles

Question 1

What does an ecosystem include?

Answer 1

All the organisms living in a particular area and all the abiotic conditions.

Question 2

What are producers?

Answer 2

Organisms that make their own food through photosynthesis.

Question 3

What do producers use the sugars produced in photosynthesis for?

Answer 3

• Respiration -> Releasing energy for growth

* Making biological molecules (e.g. cellulose)

Question 4

What is biomass?

Answer 4

The mass of living material in an organism (or the chemical energy stored).

Question 5

Describe the order of a food chain.

Answer 5

• Producer
• Primary consumer
• Secondary consumer
• Tertiary consumer
(• Decomposers)

Question 6

How can biomass be measured?

Answer 6

Looking at:
• The dry mass (kg)
• The chemical energy stored (kJ)

Question 7

What is dry mass?

Answer 7

The mass of an organism with the water removed.

Question 8

How can dry mass (biomass) of an organism be measured?

Answer 8

1) Dry an organism at a low temperature in an oven
2) Weigh it regularly until the mass becomes constant (so all the water has been removed)
3) If needed, the result is scaled up to give the biomass of the total population or of the area being investigated
4) The mass of carbon is taken as about 50% of the dry mass

Question 9

What are the units for dry mass per unit area?

Answer 9

kg/m2

Question 10

What are the two ways dry mass may be quoted?

Answer 10

• Dry mass of the total population
• Dry mass of the area being investigated

NOTE: It may refer to the mass of carbon contained, not the total dry mass.

Question 11

How much of dry mass is usually mass of carbon?

Answer 11

About 50%

Question 12

How can the chemical energy (biomass) of an organism be measured?

Answer 12

1) Dry an organism at a low temperature in an oven
2) Weigh it regularly until the mass becomes constant (so all the water has been removed)
3) Burn the biomass in a calorimeter
4) The amount of heat given off tells you how much energy is in it

Question 13

What are the units for chemical energy?

Answer 13

J (or kJ)

Question 14

What is GPP?

Answer 14

• Gross Primary Production

* The total amount of chemical energy converted from light energy by plants in a given area

Question 15

What is R?

Answer 15

• Respiratory loss

* The amount of the GPP lost to the environment as heat when plants respire

Question 16

How much of GPP is lost as respiratory loss?

Answer 16

About 50%

Question 17

What is NPP?

Answer 17

• Net Primary Production
• The remaining chemical energy from GPP that is not lost as respiratory losses. It is the energy available for growth and reproduction.

Question 18

Give the equation relating GPP, NPP and R.

Answer 18

NPP = GPP - R

Question 19

How is NPP stored?

Answer 19

As biomass.

Question 20

How much of GPP is passed down to the next trophic level?

Answer 20

Just NPP.

Question 21

What is primary productivity?

Answer 21

When primary production is expressed as a RATE, it is called this.

Question 22

How is primary productivity usually expressed?

Answer 22

• As a rate

* i.e. The total amount of chemical energy in a given area in a given time

Question 23

What are the units for primary productivity?

Answer 23

kJ/ha/yr (or kJ/m2/yr)

Question 24

What is the difference between primary production and primary productivity?

Answer 24

• Primary production - Energy per area

* Primary productivity - Energy per area per time

Question 25

The grass in an ecosystem has a gross primary productivity of 20,000 kJ/m2/yr. It loses 8,000 kJ/m2/yr as heat from respiration. What is the net primary productivity?

Answer 25

12,000 kJ/m2/yr

Question 26

How much of a consumers’ food is transferred to the next trophic level?

Answer 26

About 10%

Question 27

What are some reasons why not all biomass is passed between trophic levels?

Answer 27

• Not all food is eaten (e.g bones)
• Excretion
• Respiration

Question 28

What is the net production of a consumer?

Answer 28

The chemical energy stored in a consumers’ biomass that is available to the next trophic level.

Question 29

What is the equation for net production of consumers?

Answer 29

N = I - (F + R)

Where:
N = Net production
I = Chemical energy in ingested food
F = Chemical energy lost in faeces and urine
R = Energy lost through respiration

Question 30

What can the net production of consumers be called?

Answer 30

Secondary production

Question 31

What is the difference between primary and secondary productivity?

Answer 31

Primary is in producers, while secondary is in consumers.

Question 32

Rabbits receive 20,000 kJ/m2/yr and their net productivity is 2,000 kJ/m2/yr. What is the efficiency of energy transfer?

Answer 32

10%

Question 33

What is the difference between a food chain and food web?

Answer 33

• Food chain -> Shows simple lines of energy transfer.

* Food web -> Shows how lots of food chains overlap.

Question 34

What is each stage in a food chain called?

Answer 34

Trophic level

Question 35

What are decomposers?

Answer 35

Organisms that break down dead or undigested material, allowing nutrients to be recycled.

Question 36

What are the two main ways in which farming practices increase the efficiency of energy transfer?

Answer 36

1) Reducing the energy lost to other organisms (e.g. pests)

2) Reducing the energy lost through respiration

Question 37

How can farmers increase efficiency of energy transfers by reducing energy lost to other organisms?

Answer 37

Simplifying food webs by removing pests by:
CHEMICAL PESTICIDES
• Insecticides
• Herbicides
BIOLOGICAL AGENTS
• Parasites
• Pathogenic bacteria and viruses
INTEGRATED SYSTEMS (both chemical and biological)

Question 38

How do insecticides help to increase the efficiency of energy transfers?

Answer 38

• They kill insect pests that eat and damage crops

* So less biomass is lost and the NPP is greater

Question 39

How do herbicides help to increase the efficiency of energy transfers?

Answer 39

• They kill weeds, which removes competition and removes the habitat and food source of insect pests
• So more biomass is grown and less is lost, so the NPP is greater

Question 40

How do parasites help to increase the efficiency of energy transfers?

Answer 40

• They live in or lay their eggs on a pest insect, which kills it or reduces its ability to function
• So less biomass is lost to pests and the NPP is greater

Question 41

How do pathogenic bacteria and viruses help to increase the efficiency of energy transfers?

Answer 41

• They kill insect pests that eat and damage crops

* So less biomass is lost and the NPP is greater

Question 42

How can farmers increase efficiency of energy transfers by reducing energy lost by respiration?

Answer 42

• Restricting the movement of animals

* Building pens indoors and keeping them warm

Question 43

What are the pros and cons of factory farming?

Answer 43

PROS
• More food can be produced in a shorter space of time, often at a lower cost
CONS
• Raises ethical issues

Question 44

What is a natural ecosystem?

Answer 44

One that hasn’t been changed by human activity.

Question 45

What happens when human activity enters a natural ecosystem?

Answer 45

It can disrupt the cycling of nutrients.

Question 46

What is the technical name for decomposers?

Answer 46

Saprobionts

Question 47

What are saprobionts?

Answer 47

A type of decomposer that feed on the remains of dead plants and animals, and on their waste products.

Question 48

How are saprobionts useful in food webs?

Answer 48

They break down dead and waste matter, allowing important chemical elements to be recycled.

Question 49

How do saprobionts work?

Answer 49

EXTRACELLULAR DIGESTION
• Secrete enzymes and digest food externally
• Then absorb the nutrients they need

Question 50

What does extracellular digestion involve?

Answer 50

Breaking down organic molecules into inorganic ions.

Question 51

What is saprobiotic nutrition?

Answer 51

Obtaining nutrients from dead organic matter using extracellular digestion.

Question 52

What is the name for symbiotic relationships between fungi and roots of plants?

Answer 52

Mycorrhizae

Question 53

What are mycorrhizae?

Answer 53

Symbiotic relationships between some fungi and roots of plants.

Question 54

What are mycorrhizae between?

Answer 54

Some fungi and roots of plants

Question 55

Describe how mycorrhizae work.

Answer 55

• Fungi are made up of long, thin strands called hyphae, which connect to the plant roots
• Hyphae increase surface area from the plant’s root system, helping them absorb ions that are scarce and water
• In turn, the fungi obtain organic compounds from the plants, such as glucose

Question 56

What do plants gain from mycorrhizae?

Answer 56

Increased surface area for absorption of:
• Ions
• Water

Question 57

What do fungi gain from mycorrhizae?

Answer 57

Organic compounds, such as glucose, from the plant

Question 58

What is nitrogen needed for in plants and animals?

Answer 58

To make:
• Proteins
• Nucleic acids (DNA and RNA)

Question 59

How much of the atmosphere is nitrogen gas?

Answer 59

78%

Question 60

Why can’t nitrogen from the atmosphere be used by plants and bacteria directly?

Answer 60

It is very reactive.

Question 61

What does the nitrogen cycle show?

Answer 61

How nitrogen is converted into a usable form and then passed on between different living organisms and the non-living environment.

Question 62

What are the 4 stages of the nitrogen cycle?

Answer 62

1) Nitrogen fixation
2) Ammonification
3) Nitrification
4) Denitrification

Question 63

How does nitrogen from the atmosphere get taken up by plants and animals?

Answer 63

• It must be in the form of nitrogen compounds (e.g. nitrates).
• Plants absorb nitrates from the soil.
• Animals can only take in nitrogen by consuming other organisms.

Question 64

Describe nitrogen fixation.

Answer 64

• When nitrogen gas in the atmosphere is turned into nitrogen-containing compounds by bacteria such as Rhizobium.
• They turn nitrogen into ammonia, which goes on to form ammonium in solution that can be used by plants.
• Rhizobium are found inside root nodules (growths on the roots) of leguminous plants.
• This is mutualistic -> Bacteria provide plants with nitrogen compounds and the plant provides them with carbohydrates.

• Atmospheric nitrogen -> Ammonia -> Ammonium -> Nitrogen compounds in plants

Question 65

Give an example of a nitrogen-fixing bacteria.

Answer 65

Rhizobium

Question 66

Where is Rhizobium (a nitrogen-fixing bacteria) found?

Answer 66

In root nodules (growths on the roots) of leguminous plants

Question 67

Give some examples of leguminous plants.

Answer 67

• Peas
• Beans
• Clover

Question 68

What does nitrogen fixation convert from and to?

Answer 68

Atmospheric nitrogen -> Ammonia -> Ammonium -> Nitrogen compounds in plants

Question 69

How do nitrogen compounds reach animals?

Answer 69

Through feeding on plants and animals that contain nitrogen containing compounds.

Question 70

Describe ammonification.

Answer 70

• Saprobionts turn nitrogen compounds from dead organisms and waste into ammonia, which then form ammonium ions.
• Nitrogen compounds in plants -> Ammonia -> Ammonium ions

Question 71

What carries out ammonification?

Answer 71

Saprobionts (decomposers)

Question 72

What does ammonification convert from and to?

Answer 72

Nitrogen compounds in plants -> Ammonia -> Ammonium ions

Question 73

Describe nitrification.

Answer 73

• When ammonium ions in the soil are changed into nitrites and then nitrates that can then be used by plants.
FIRST STEP
• Nitrosomonas change ammonium ions into nitrites
SECOND STEP
• Nitrobacter change nitrites into nitrates

• Ammonium ions -> Nitrites -> Nitrates

Question 74

Give an example of nitrifying bacteria.

Answer 74

• Nitrosomonas (ammonium ions -> nitrates)

* Nitrobacter (nitrites -> nitrates)

Question 75

What does nitrification convert from and to?

Answer 75

Ammonium ions -> Nitrites -> Nitrates

Question 76

Describe denitrification.

Answer 76

• Denitrifying bacteria convert nitrates in the soil into nitrogen gas (by using the nitrates in respiration and releasing nitrogen gas)
• This happens under anaerobic conditions

• Nitrates -> Atmospheric nitrogen

Question 77

How do denitrifying bacteria work?

Answer 77

The use nitrates in the soil to respire, which releases nitrogen gas into the atmosphere.

Question 78

Under what conditions do denitrifying bacteria work?

Answer 78

Anaerobic e.g. in waterlogged soils

Question 79

How else can nitrogen get into an ecosystem?

Answer 79

• Lightning -> Fixes atmospheric nitrogen

* Artificial fertilisers -> Produced from atmospheric nitrogen on an industrial scale in the Haber process

Question 80

Do you need to learn the name of the different microorganisms in the nitrogen cycle?

Answer 80

No

Question 81

Name all of the microorganisms involved in the nitrogen cycle.

Answer 81

• Nitrogen fixing bacteria
• Saprobionts (bacteria, fungi, etc.) in ammonification
• Nitrifying bacteria
• Denitrifying bacteria

Question 82

Remember to practise drawing out the full diagram for the nitrogen cycle.

Answer 82

Pg 132 of revision guide.

Question 83

Describe the whole nitrogen cycle.

Answer 83

1) NITROGEN FIXATION
• Nitrogen gas in the atmosphere is turned into nitrogen-containing compounds by bacteria such as Rhizobium.
• They turn nitrogen into ammonia, which goes on to form ammonium in solution that can be used by plants.
• Rhizobium are found inside root nodules (growths on the roots) of leguminous plants.
(• Atmospheric nitrogen -> Ammonia -> Ammonium -> Nitrogen compounds in plants)
2) AMMONIFICATION
• Saprobionts turn nitrogen compounds from dead organisms and waste into ammonia, which then form ammonium ions.
(• Nitrogen compounds in plants -> Ammonia -> Ammonium ions)
3) NITRIFICATION
• When ammonium ions in the soil are changed into nitrites and then nitrates that can then be used by plants.
(• Ammonium ions -> Nitrites -> Nitrates)
4) DENITRIFICATION
• Denitrifying bacteria convert nitrates in the soil into nitrogen gas (by using the nitrates in respiration and releasing nitrogen gas)
• This happens under anaerobic conditions
(• Nitrates -> Atmospheric nitrogen)

Question 84

What do plants and animals need phosphorus for?

Answer 84

To produce biological molecules such as:
• Phospholipids
• DNA
• ATP

Question 85

How is phosphorus found in rocks and in oceans?

Answer 85

As phosphate ions.

Question 86

How can plants and other producers use phosphate ions?

Answer 86

They can be assimilated (absorbed and then used to make more complex molecules) from water in soil.

Question 87

What is the formula for phosphate ions?

Answer 87

PO4 3-

Question 88

What is assimilation?

Answer 88

When ions are absorbed by plants so they can be used to make more complex molecules.

Question 89

Describe the phosphorus cycle.

Answer 89

1) Phosphate ions in rocks are released into soil by weathering.
2) Phosphate ions are taken into plants through the roots (mycorrhizae help with this).
3) Phosphate ions transferred through the food chain (as animals eat plants and other animals)
4) Phosphate ions are lost in waste products from animals.
5) Saprobionts break down organic compounds when plants and animals die and their waste, releasing phosphate ions into the soil
6) Weathering of rocks ALSO releases phosphate ions into seas, lakes and rivers. This is taken up by aquatic producers, such as algae, and passed along the food chain to birds.
7) Waste products from sea birds are known as guano. It returns a significant amount of phosphate ions to soil.

Question 90

Is the phosphorus cycle one cycle?

Answer 90

No, it is kind of 2 cycles -> one in the water and one on land.

Question 91

What is guano?

Answer 91

Sea bird waste

Question 92

What is guano used for and why?

Answer 92

It is often used as a natural fertiliser, since it has a high proportion of phosphate ions.

Question 93

Remember to practise drawing out the phosphorus cycle.

Answer 93

Pg 133 of revision guide

Question 94

How are nutrients lost from fields?

Answer 94

• Harvesting crop.
• Removing animals or animal products.

It removes the minerals that these have taken up from the soil. They cannot decompose there or release waste products, so the minerals are not returned to the soil.

Question 95

What are fertilisers used for?

Answer 95

Replacing lost ions (e.g. phosphates or nitrates) from soil, which means more energy from the ecosystem can be used for growth, increasing the efficiency of energy transfer.

Question 96

What are the two types of fertiliser?

Answer 96

• Natural

* Artificial

Question 97

What are artificial fertilisers?

Answer 97

• Inorganic

* Contain pure chemicals (e.g. ammonium nitrate) as powders or pellets

Question 98

What are natural fertilisers?

Answer 98

• Organic

* Include manure, composted vegetables, crop residues and sewage sludge

Question 99

What are the issues with fertilisers?

Answer 99

• Leaching -> Eutrophication

* Crops and other plants to die if there is too much of a particular nutrient

Question 100

What is leaching?

Answer 100

When water-soluble compounds in the soil are washed away e.g. by rain. It is often into nearby ponds and rivers.

Question 101

When is leaching most likely to occur?

Answer 101

When fertiliser is applied just before heavy rainfall.

Question 102

What type of fertiliser leads to more leaching and why?

Answer 102

• Artificial fertilisers -> Inorganic ions are relatively soluble -> More likely to cause leaching
• Natural fertilisers -> Nitrogen and phosphorus are contained in organic molecules that need to be decomposed by microorganisms before the nutrients can be used by plants -> Decomposition is gradual, so the release is slow -> Less likely to cause leaching

Question 103

Which nutrient in artificial fertilisers is likely to cause more leaching and why? (Nitrates or phosphates)

Answer 103

Nitrates, because they are more soluble.

Question 104

What can leaching lead to?

Answer 104

Eutrophication

Question 105

Describe the process of eutrophication.

Answer 105

1) Mineral ions leached from fertilised fields stimulate the rapid growth of algae in ponds and rivers.
2) Large amounts of algae block light from reaching the plants below.
3) The plants are unable to photosynthesise and eventually die.
4) Bacteria feed on the dead plant matter, which causes their number to grow. Their aerobic respiration reduces the oxygen concentration of the water.
5) Fish and other aquatic organisms die because there isn’t enough dissolved oxygen.