Organisation of an Ecosystem (AQA GCSE Biology)

Exam Questions

2 hours15 questions
1a
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1 mark

Name the process carried out by all ecological producers. 

1b
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2 marks

In a woodland food chain, the following events occur, as set out in Table 1.

Table 1

Event

Description

A

Woodland birds feed on ladybirds

B

Aphids feed on tree sap

C

Birds of prey feed

D

Trees photosynthesise and produce food

E

Ladybirds feed on aphids

Complete the table below to reorder events A - E into chronological order.  

1st

2nd

3rd

4th

5th

 

 

 

 

 

1c
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3 marks

Complete the missing words in the passage below from the list of words in Figure 1. You may not need to use all the words in Figure 1.

wordfill-mcq
1d
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1 mark

Which of the ecological terms A - D best describes a grazing animal?

  • Primary consumer

  • Secondary consumer

  • Producer

  • Herbivorous predator

1e
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1 mark

Which of the sketch graphs (A - D shown below) best represents the fluctuations in numbers of predators versus the numbers of prey in a feeding relationship?

predators-v-prey-sketch-graph-mcq-1
  • Option A

  • Option B

  • Option C

  • Option D

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2a
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1 mark

Ecologists use a sampling method in which quadrats are laid down along a straight line in order to sample how the area's wildlife varies along that line.

Name this type of sampling method. 

2b
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2 marks

For an area of 10 000 m2, calculate the number of 1m2 quadrats needed to sample 2% of the overall area.

2c
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3 marks

A single 50cm × 50cm quadrat is represented in Figure 2 below. The quadrat contained grass, clover and an area of bare ground. 

Figure 2

quadrant--cover-1

Estimate the percentage cover of clover in the quadrat shown in Figure 2.

2d
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1 mark

A scientist decided to use quadrats to investigate species in a field.

Which technique of A - D is the best one for deciding where to place the quadrats to collect the sample?

  • Place quadrats down in areas where the species under study is present in large numbers.

  • Pick the sunniest areas because more life will grow there. 

  • Close your eyes, throw the quadrat and sample the area where it lands. 

  • Create a grid of the field and use a random number generator to find coordinates to place the quadrat down. 

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3a
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2 marks

Figure 3 contains a number of biological keywords.

Identify the two keywords from Figure 3 that are defined by the phrases A and B below.

Figure 3

frequency          biodiversity          abundance          range     

distribution          ecosystem          community          niche

A. The number of individuals of one species found in a sample.

B. The geographical locations of all the members of a population.

3b
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2 marks

Higher Tier Only

The wildebeest (shown in Figure 4) is a large grazing herbivore that lives on the plains of Africa. For much of the year, the plains are dry and arid, although rain falls more in certain seasons. 

Figure 4

wildebeest-1

The number of wildebeest in one area of the African plains is shown in Table 2.

Table 2

Month

Monthly rainfall in mm

Number of wildebeest (estimate)

January

95

1 560

April

210

2 350

July

60

840

October

100

1 210

Use the data in Table 2 to calculate the mean number of wildebeest present in the area throughout the year. 

3c
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2 marks

Higher Tier Only

Plot the data from Table 2 on the axes below. A copy of Table 2 is repeated here for convenience. 

Table 2

Month

Monthly rainfall in mm

Number of wildebeest (estimate)

January

95

1 560

April

210

2 350

July

60

840

October

100

1 210

Graph area

wildebeest-axes-2
3d
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2 marks

Higher Tier only

Describe the link between monthly rainfall and the number of wildebeest found in this particular area of Africa. 

Suggest a reason for the pattern of data that is seen. 

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4a
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1 mark

Which of the processes A - D is the one by which carbon enters the carbon cycle by being incorporated into the biomass of producers?

  • Decomposition

  • Photosynthesis

  • Aerobic respiration

  • Evaporation

4b
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2 marks

Part of the carbon cycle is shown in Figure 5.

Figure 5

carbon-cycle-2

Name processes X and Y.

X ________________

Y ________________

4c
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3 marks

Over 97% of the Earth's water is salty so will not sustain life on land, which requires fresh (unsalted) water. 

With reference to the water cycle, explain how salty ocean water is converted to reach land as fresh water in nature.

4d
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1 mark

Which of the factors listed A - D is not a factor that affects the rate of decay of dead biomass by microorganisms?

  • Temperature

  • Light intensity

  • Water availability

  • Oxygen availability

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5a
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2 marks

In an investigation into the effect of temperature on the decomposition of milk, lipids in the milk are converted to fatty acids and glycerol by the enzyme lipase.  The experiment is set up with an initial pH of 8·0 which then fell as the experiment progressed. 

Explain the fall in pH levels during the experiment.

5b
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1 mark

In the experiment outlined in part a), phenolphthalein is used in the reaction mixture.

Describe the role of phenolphthalein in this experiment. 

5c
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2 marks

Two separate tubes were set up with milk and lipase and incubated at 15°C and 30°C for 5 minutes each. The results shown in Table 3 below were obtained in this experiment.

Table 3

Temperature in °C

Drop in number of pH units in 5 minutes

Rate of fall of pH in pH units per minute

15

1.8

0.36

30

3.7

 

Calculate the rate of fall of pH at 30°C.

5d
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2 marks

In a separate experiment, scientists measured the rate of decay of <0.05 pH units per minute at 3°C. 

Suggest how this information could be used to advise consumers about the correct storage of milk as a food source. 

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1a3 marks

The intertidal zone is the area along a coast which is underwater at high tide and above water (exposed) when the tide is low.

A group of students on a field trip in Asia wanted to investigate the distribution of two species of seaweed (C. racemosa and C. microphysa) along a rocky shore to establish whether they could live at certain positions. 

Seaweeds are multicellular algae that produce glucose. 

Describe the role that seaweeds play in an ecosystem as producers.

1b6 marks

Describe and explain a method that the students could use to investigate the distribution of the two species of seaweed along the rocky shore using a quadrat and a tape measure. 

You should explain how the students would collect valid data.

1c4 marks

How could the students alter their method if they wanted to investigate the abundance of each type of seaweed along the coastline by measuring percentage cover?

1d3 marks

Another group of students carried out the same investigation the year before.

Their results are shown in Figure 1 below.

Figure 1

seaweed

Suggest and explain a conclusion that the students could draw from their results using information from Figure 1.

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2a3 marks

Microorganisms play a vital role in cycling nutrients through ecosystems.

Explain how.

2b1 mark

Carbon in dead biomass is converted into carbon dioxide by the action of certain bacteria and fungi.

Name these microorganisms.

2c3 marks

A gardener is attempting to create compost to spread on her flower beds. She uses dead plant biomass to create compost. Give three conditions that she should optimise in order to create the best quality compost that she can. 

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3a
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4 marks

A group of students investigated the abundance of daisies in a field behind their school.

The dimensions of the field were 200 metres × 100 metres.

The students:

  • Chose areas where the daisies were growing

  • Placed 20 quadrats in these areas where daisies were growing

  • Counted the number of daisies in each of the 20 quadrats

Each quadrat was 0.25 × 0.25 metres in size.

Table 1 shows their results.

Table 1

Quadrat Number

Number of daisy plants

Quadrat number

Number of daisy plants

1

5

11

3

2

3

12

14

3

4

13

3

4

1

14

1

5

3

15

10

6

2

16

2

7

4

17

2

8

1

18

3

9

5

19

5

10

6

20

1

Using the students' results from Table 1, calculate the estimated number of daisy plants in the whole field.

3b2 marks

It is unlikely that it is possible to calculate a valid estimate of the number of daisy plants in the field using the students' method. 

Suggest two improvements that could be made to the students' method.

For each suggested improvement, give a reason why your method would produce more valid results than the students' method. 

3c2 marks

Explain how systematic sampling differs from random sampling in a quadrat study.

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4a6 marks

Figure 2 shows an outline of the carbon cycle.

Figure 2

q4a_organisation-of-an-ecosystem_ecology_gcse_aqa_biology

Describe the role of living organisms in the cycling of carbon.

4b2 marks

Suggest a consequence to the living world of substances such as carbon not being recycled. 

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5a1 mark

Microorganisms such as bacteria can produce methane gas.

Name the process that produces methane gas in microorganisms such as bacteria. 

5b1 mark

Methane gas can be produced industrially using a biogas generator. 

Methane gas can be used as a fuel.

Table 2 below shows how the composition of biogas changed over the first three weeks of production. 

Table 2

biogas

Explain why it would not be advisable to collect biogas from the generator after longer than three weeks. 

Use data from Table 2 in your answer. 

5c3 marks

Air from the atmosphere is present in the biogas generator when it is set up.

Suggest an explanation as to why the concentration of carbon dioxide changed over the course of three weeks. 

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6a3 marks

Higher Tier Only

Sulfur dioxide is one type of air pollutant.

About 99% of atmospheric sulfur dioxide in air comes from human activity. 

One source of sulfur dioxide pollution comes from burning fossil fuels contaminated with sulfur. 

A group of students decided to measure the distribution of two species of lichen growing on trees at increasing distances from a main road. 

One of the species of lichen they decided to study is sensitive to high levels of sulfur dioxide; the other is not. 

Describe how a group of scientists would investigate the distribution of the two lichens.

6b3 marks

Higher Tier Only

Predict the results that might be expected from the experiment you described in part (a)

Explain the reasoning behind your prediction.

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1a
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2 marks

It has been found, through DNA sequencing, that many extremophile organisms share a higher-than-normal proportion of guanine and cytosine (G and C) in their DNA.

Guanine and cytosine are joined by 3 hydrogen bonds across a molecule DNA, whereas the other two bases (adenine and thymine) are joined by just 2 hydrogen bonds. 

Suggest and explain the property that having a high G-C content gives those organisms. 

1b
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3 marks

Name three extreme conditions that extremophile microorganisms have been found in and for each one, describe the adaptations that allow the microorganisms to survive in those extreme conditions.

1c
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1 mark

One group of extremophile microorganisms are the barophiles.

Which extreme condition of A - D is the one to which barophiles are well-adapted? 

  • High/low pressure

  • Low temperature (below 0°C)

  • Low pH (acid conditions)

  • High salinity eg. in salt marshes

1d
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2 marks

Figure 2 below shows four species of extremophile microorganisms, along with their individual extreme adaptations.

For each one, draw a line to link the adaptation to the organisms' preferred habitat using straight lines.

Figure 2

extreme-adaptations-q-2

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2a
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2 marks

Higher Tier Only

Ecologists carried out a study into the effect of soil moisture level on the distribution of certain species of wildflower in a large meadow.

Figure 3 shows the meadow from the study, bounded by a river to the north and east and by farmland to the west and south.

The meadow slopes down to the river, with the south end of the meadow elevated approximately 10 metres above the north end. 

Figure 3

meadow-soil-moisture-1

A quadrat study was carried out to determine the abundance and distribution of wildflowers in the meadow, alongside a measurement of soil moisture levels using a soil moisture probe of the sort shown in Figure 4.

Samples were analysed in four areas of the meadow, W, X, Y and Z as shown in Figure 3.

Figure 4

soil-moisture-probe-1

The data found by the ecologists is shown in Table 1.

Table 1

Area

Soil moisture level in % by mass

No of wildflower species identified in quadrats

Predominant species found

W

28

23

Succisa pratensis, Lychnis flos-cuculi, Centaurea nigra

X

13

15

Chrysanthemum segetum, Centaurea nigra

Y

31

21

Lychnis flos-cuculi, Silaum silaus

Z

41

26

Succisa pratensis, Lythrum salicaria

Suggest reasons for the differing soil moisture levels at W, X, Y and Z.

2b
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3 marks

Higher Tier Only

Using the data in Table 1, determine the correct ranking of the wildflower species listed below, from 1 to 6, in ascending order of adaptation to dry conditions.

Species

Rank 1 - 6

6 = best adapted to dry conditions

Centaurea nigra

 

Chrysanthemum segetum

 

Lychnis flos-cuculi

 

Lythrum salicaria

 

Silaum silaus

 

Succisa pratensis

 

2c
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2 marks

Higher Tier Only

Suggest why the answer you gave in part 3(b) may not be the the most accurate rank order of adaptation to dry conditions. 

2d
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2 marks

Identify and explain two structural adaptations of wildflowers that would benefit the plant living in a dry soil environment.

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3a
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1 mark

The carbon cycle is built around the constant exchange of carbon between carbon dioxide (CO2) in the air and carbon in other forms, including in biomass.

There is one other carbon-containing gas that plays an important role as it is exchanged between living organisms and the atmosphere.

Name this other gas.

3b
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3 marks

Table 2 shows the approximate masses of carbon contained within carbon-containing compounds in various parts of the Earth's crust and atmosphere.

Table 2

 Reservoir 

 Mass of carbon in gigatonnes 

 Sedimentary rocks (including fossil fuels)

50 000 000

 Deep oceans 

38 000

 Soil 

1 580

 Surface oceans 

970

 Atmosphere 

750

 Land organisms 

610

 Ocean organisms 

3

1 gigatonne is 1 billion (1 000 000 000) metric tonnes.

Calculate the total mass of carbon in carbon-containing compounds in all reservoirs except for sedimentary rocks. Give your answer in kg in standard form. 

3c
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1 mark

Name one process by which carbon in sedimentary rock (the largest sink shown in Table 2) is returned directly to the atmosphere. 

3d
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2 marks

Carbon transfers from the 'land organisms' sink to the 'soil' sink. Give two ways in which this transfer takes place. 

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4a
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4 marks

Recently, rules governing the disposal of waste in landfill sites have been introduced to separate food waste from general waste and from waste to be recycled.

Food waste is a valuable resource in the production of high-quality compost that can be used in gardens and on crops. 

Identify and explain one other advantage and one disadvantage of separating food waste from other waste streams during waste disposal. 

4b
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2 marks

In-Vessel Composting (IVC) is an industrial process to manufacture compost from household food and garden waste. 

Figure 5 shows the typical process flow through an IVC factory manufacturing compost sold in garden centres and DIY stores. 

Figure 5

compost-flowchart-1

Suggest the source of the heat referred to in stage 4 of Figure 5.

4c
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2 marks

Stages 2 and 3 in Figure 5 are for preparing the biomaterial for the composting stage.

Mixing involves making a blend of garden waste (grass cuttings, hedge trimmings etc) with food waste (uneaten food, peelings etc).

Shredding involves chopping all the pieces down to an average size of 10-15 mm and allowing all the pieces to drop from a height of about 4 metres onto a pile for composting.

Suggest the main reason for both stages 2 and 3 of the process. 

4d
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3 marks

The type of compost made in a process such as the one described in Figure 5 is claimed to be 'peat free'.

Explain why it is important for commercially-available composts to be peat-free.

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