Topic 4 - Bioenergetics

Question 1

Where does photosynthesis take place?

Answer 1

It takes place inside chloroplasts found in plants and algae.

Question 2

Is photosynthesis endothermic or exothermic?

Answer 2

Photosynthesis is endothermic meaning it requires energy.

Question 3

What does photosynthesis convert carbon dioxide and water into?

Answer 3

It converts them into oxygen and glucose.

Question 4

What is the word equation for photosynthesis?

Answer 4

carbon dioxide + water –> oxygen + glucose

Question 5

What is the energy source for photosynthesis and where is it?

Answer 5

The source of energy is sunlight, which is trapped by a chemical called chlorophyll inside chloroplasts in plant cells.

Question 6

What is the symbol equation for photosynthesis?

Answer 6

6CO2 + 6H20 –> C6H12O6 + 6O2

Question 7

What are the four key factors that affect the rate of photosynthesis?

Answer 7

Chlorophyll concentration, carbon dioxide concentration, temperature and light intensity.

Question 8

How does the amount of chlorophyll concentration affect the rate of photosynthesis?

Answer 8

High chlorophyll concentration gives a high rate of photosynthesis.

Question 9

How does carbon dioxide concentration affect the rate of photosynthesis?

Answer 9

Increasing the carbon dioxide concentration increases the rate of photosynthesis. However, above a certain threshold, further increases in the carbon dioxide concentration do not increase the rate of photosynthesis because another factor (like light intensity) is limiting the rate of reaction.

Question 10

How does temperature affect the rate of photosynthesis?

Answer 10

Increasing the temperature increases the rate of photosynthesis because more energy is provided. However, if the temperature is increased to above about 45°C, the enzymes that catalyse the reaction begin to denature. This causes the rate of the reaction to drop sharply until it stops altogether.

Question 11

How does light intensity affect the rate of photosynthesis?

Answer 11

Increasing light intensity increases the rate of photosynthesis because more energy is provided. However, if the light intensity is increased above a certain threshold, the rate of photosynthesis will not increase because another factor (like temperature) is limiting the rate of reaction.

Question 12

What is a limiting factor?

Answer 12

A limiting factor restricts the rate of reaction.

Question 13

What is the limiting factor for photosynthesis at night?

Answer 13

At night, light intensity is the limiting factor.

Question 14

What is the limiting factor for photosynthesis at winter?

Answer 14

In winter, the temperature is the limiting factor.

Question 15

What is the limiting factors for photosynthesis in warm and bright conditions?

Answer 15

In warm and bright conditions, carbon dioxide concentration is usually the limiting factor.

Question 16

What is the limiting factors for photosynthesis in mineral-deficient soil?

Answer 16

If plants are grown in mineral-deficient soil, they may not absorbs enough minerals to produce lots of chlorophyll. In this case, chlorophyll concentration can be the limiting factor.

Question 17

How does lighting and heating affect rate of photosynthesis and yield?

Answer 17

Lighting and heating increase the rate of photosynthesis that is possible. A high rate of photosynthesis means that crops grow faster and the total yield is bigger.

Question 18

What happens if the farmers costs are high?

Answer 18

If lighting and heating are very expensive, it may not be possible to spend money on increasing the light intensity and temperature of a greenhouse. Farmers must evaluate the trade-off (balance) between the costs of lighting and heating, and the rate of photosynthesis that is possible.

Question 19

What are the can glucose be converted into?

Answer 19

Cellulose, fats and oils, starch and protein.

Question 20

Why is cellulose a good use of glucose?

Answer 20

Cellulose is used to strengthen cell walls. It is particularly important for fast-growing plants.

Question 21

Why are fats and oils a good use of glucose?

Answer 21

They are stored in structures such as seeds.

Question 22

Why is starch a good use of glucose?

Answer 22

Starch is insoluble (cannot be dissolved) and is stored in stems, leaves or roots.

Question 23

Why are proteins a good use of glucose?

Answer 23

Proteins are needed for cell growth and repair. A source of nitrogen is also needed for glucose to be converted into proteins. Plants get this nitrogen by absorbing nitrate ions from soil.

Question 24

What is glucose produced by photosynthesis mainly used by?

Answer 24

Plants in respiration.

Question 25

How can you test the rate of photosynthesis?

Answer 25

Using an aquatic (lives in water) plant like pondweed. To do this, change the distance between the lamp and the pondweed and count the number of bubbles produced.. In this experiment, light intensity is the independent variable and the number of bubbles is the dependent variable.

Question 26

What does the rate that pond weed produces bubbles indicate?

Answer 26

It indicates the rate of photosynthesis. The bubbles released are oxygen, a waste product of photosynthesis.

Question 27

What is the inverse square law?

Answer 27

Light intensity = 1 / distance^2

Question 28

Why do organisms need energy?

Answer 28

Contraction - to contract the muscles of animals, allowing them to move.
Construction - to make larger molecules from smaller molecules.
Homeostasis - to keep the body temperature of warm-blooded animals relatively constant.

Question 29

What is respiration?

Answer 29

Respiration is an exothermic reaction (releases energy) that supplies all the energy needed by living organisms. This reaction happens continuously in all living cells.

Question 30

What is aerobic respiration?

Answer 30

Aerobic means with oxygen. Glucose reacts with oxygen in the mitochondria of cells to give carbon dioxide, water and energy.

Question 31

What is the word equation for aerobic respiration?

Answer 31

Glucose + oxygen –> carbon dioxide + water (+energy)

Question 32

What is the symbol equation for aerobic respiration?

Answer 32

C6H12O6 + 6O2 –> 6CO2 + 6H20 (+energy)

Question 33

How does anaerobic respiration work in plants?

Answer 33

Anaerobic means without oxygen. In plants and yeast cells, glucose is converted into ethanol and carbon dioxide. In yeast cells, this is called fermentation. This is an important step in the manufacture of both bread and alcohol.

Question 34

What is the word equation for anaerobic respiration in plants?

Answer 34

Glucose –> ethanol + carbon dioxide

Question 35

How does anaerobic respiration work in animals?

Answer 35

Glucose is not broken down completely, making it a less efficient way of transferring energy than aerobic respiration. In animals, glucose is converted to lactic acid.

Question 36

What is the word equation for anaerobic respiration in animals?

Answer 36

Glucose –> lactic acid

Question 37

When does anaerobic respiration happen?

Answer 37

When insufficient oxygen reaches the muscles during periods of intense activity.

Question 38

What is metabolism?

Answer 38

Metabolism is the combination of all the chemical processes that happen in an organism. Many of these create new molecules with the help of enzymes.

Question 39

What are examples of metabolic reactions?

Answer 39

Converting glucose, making lipids, breaking down excess proteins and making amino acids.

Question 40

How does the metabolic reaction of converting glucose work?

Answer 40

Converting glucose into starch (plants), glycogen (animals) and cellulose (plants).

Question 41

How does the metabolic reaction of making lipids work?

Answer 41

Combining glycerol and fatty acid chains to make lipid molecules.

Question 42

How does the metabolic reaction of breaking down excess proteins work?

Answer 42

Breaking down excess proteins to form urea, which is excreted (got rid of) in urine.

Question 43

How does the metabolic reaction of making amino acids work?

Answer 43

Combining glucose and nitrate ions to make amino acids. Amino acids can then be combined to make proteins.

Question 44

Why do we need to increase the rate of respiration when exercising?

Answer 44

Exercise increases the body’s energy demands. The rate of respiration must increase in order to meet these new demands.

Question 45

What are the main responses to increase the rate of respiration?

Answer 45

Increase in breath volume, blood vessels dilate, increased heart rate and increase in breathing rate.

Question 46

Why do we need an increase in breath volume to increase the rate of respiration?

Answer 46

Increase in breath volume also increases the rate of gas exchange.

Question 47

Why do blood vessels dilate to increase rate of respiration?

Answer 47

Blood vessels dilate (open wider) to ensure more blood reaches the muscles.

Question 48

Why does our heart rate increase to increase the rate of respiration?

Answer 48

Increase in heart rate delivers more blood (containing glucose and oxygen) to the muscles.

Question 49

Why does our breathing rate increase to increase the rate of respiration?

Answer 49

An increase in breathing rate increases gas exchange in the lungs, with more oxygens taken in and more carbon dioxide released.

Question 50

What happens when muscles are not supplied with enough oxygen during intense exercise?

Answer 50

Muscle cells may start to respire anaerobically, this can lead to oxygen debt.

Question 51

What is lactic acid?

Answer 51

Lactic acid is a by-product of anaerobic respiration. Lactic acid is toxic and can build up in muscles, leading to muscular pain and fatigue. Lactic acid also stops muscles contracting efficiently.

Question 52

What is oxygen debt?

Answer 52

Oxygen debt refers to the extra oxygen required after exercise to oxidise (combine with oxygen) lactic acid and remove it from cells.

Question 53

How do you repay oxygen debt?

Answer 53

Blood transports the lactic acid to the liver, where it reacts with oxygen to produce carbon dioxide and water. Heavy breathing after exercise helps to repay the oxygen debt by taking more oxygen into the lungs.