B3.1 Gas Exchange

Question 1

What is gas exchange?

Answer 1

Gas exchange is the process by which oxygen and carbon dioxide are exchanged between living organisms and their environment.

Question 2

How does gas exchange occur in organisms?

Answer 2

Gas exchange takes place by the process of diffusion.

Question 3

What are three factors that determine the rate of diffusion in gas exchange?

Answer 3

The three factors that determine the rate of diffusion in gas exchange are:

size of the respiratory surface

concentration gradient

diffusion distance

Question 4

True or False?

Large multicellular organisms can rely on diffusion alone for gas exchange.

Answer 4

False.

Large multicellular organisms cannot rely on diffusion alone to supply every cell with oxygen due to their smaller surface area to volume ratio and greater diffusion distance.

Question 5

List four properties of effective gas exchange surfaces.

Answer 5

Effective gas exchange surfaces are permeable, have a thin tissue layer, presence of moisture, and a large surface area.

Question 6

Why do small, unicellular organisms like amoeba not need specialised gas exchange organs?

Answer 6

Small, unicellular organisms have a large surface area compared to their volume and a short diffusion distance, allowing sufficient diffusion for their oxygen needs.

Question 7

How does the presence of moisture facilitate gas exchange?

Answer 7

Moisture facilitates gas exchange by allowing gases to dissolve, which aids their diffusion across the gas exchange surface.

Question 8

What is the role of blood vessels in maintaining concentration gradients for gas exchange?

Answer 8

Blood vessels provide a dense network with a large surface area for gas diffusion and ensure continuous blood flow to maintain concentration gradients.

Question 9

How does ventilation contribute to gas exchange?

Answer 9

Ventilation brings oxygen close to the gas exchange surface and removes carbon dioxide, helping to maintain concentration gradients.

Question 10

True or False?

Respiration and gas exchange are the same process.

Answer 10

False.

Respiration is a chemical process occurring in all living cells, while gas exchange refers to the diffusion of oxygen and carbon dioxide across a respiratory surface.

Question 11

How are the alveoli adapted for gas exchange?

Answer 11

The alveoli have thin walls to minimise diffusion distance, a good blood supply to maintain a steep concentration gradient and surfactant to increase the rate of diffusion.

Question 12

How do bronchioles help regulate airflow into the lungs?

Answer 12

Bronchioles are lined with smooth muscle that can dilate when more air is needed and constrict when an allergen is present, regulating airflow.

Question 13

What structure is found at the end of bronchioles?

Answer 13

Groups of alveoli are found at the end of bronchioles.

Question 14

How do alveoli contribute to efficient gas exchange?

Answer 14

Alveoli provide a large surface area for gas exchange and are surrounded by an extensive network of capillaries.

Question 15

True or False?

Bronchi have smooth muscle in their walls.

Answer 15

True.

Bronchi have walls strengthened with cartilage and a layer of smooth muscle that can contract or relax to change the diameter of the airways.

Question 16

What is the function of surfactant in the alveoli?

Answer 16

Surfactant lowers the surface tension in the alveoli, preventing them from collapsing and sticking together during expiration.

Question 17

What maintains the concentration gradient between alveoli and blood?

Answer 17

Deoxygenated blood enters the capillary beds from a branch of the pulmonary artery while oxygenated blood leaves via a branch of the pulmonary vein, maintaining the concentration gradient.

Question 18

True or False?

The bronchi divide to form bronchioles.

Answer 18

True.

Bronchioles branch off the two bronchi to form a network of narrow tubes.

Question 19

What is ventilation and why is it important?

Answer 19

Ventilation is the process of breathing in and out, which is essential for effective gas exchange in the lungs by replacing older air with fresh air and maintaining concentration gradients.

Question 20

Define inspiration in the context of ventilation.

Answer 20

Inspiration is the process of breathing in, which causes the volume of the chest to increase and air pressure to decrease until it is lower than atmospheric pressure.

Question 21

What happens to the diaphragm during inspiration?

Answer 21

During inspiration, the diaphragm contracts and flattens, increasing chest volume.

Question 22

How do external intercostal muscles contribute to inspiration?

Answer 22

External intercostal muscles contract during inspiration, causing the ribcage to move upwards and outwards, increasing chest volume.

Question 23

What causes air to move into the lungs during inspiration?

Answer 23

Air moves into the lungs during inspiration because it flows down the pressure gradient from the higher pressure outside to the lower pressure inside the lungs.

Question 24

True or False?

Expiration is always an active process.

Answer 24

False.

Expiration is mostly a passive process due to the recoil of the lungs after they have been stretched by inspiration.

Question 25

Describe the passive expiration process.

Answer 25

In passive expiration, external intercostal muscles relax, the diaphragm relaxes and becomes dome-shaped, and elastic fibres in alveoli walls recoil, reducing lung volume.

Question 26

When does active expiration occur?

Answer 26

Active expiration occurs when there is a need to expel excess air from the lungs, such as when blowing out a candle.

Question 27

What role do abdominal muscles play in active expiration?

Answer 27

During active expiration, abdominal muscles contract to push organs upwards against the diaphragm, decreasing the volume of the chest cavity.

Question 28

True or False? During expiration, the volume of the chest increases.

Answer 28

False. During expiration, the volume of the chest decreases and pressure increases, causing air to be forced out down its pressure gradient.

Question 29

What is a spirometer?

Answer 29

A spirometer is an apparatus used to investigate ventilation, consisting of a water-filled chamber covered by a hinged plastic lid.

Question 30

Define tidal volume.

Answer 30

Tidal volume is the volume of air inhaled and exhaled during normal breathing.

Question 31

What is vital capacity and how is it calculated?

Answer 31

Vital capacity (VC) is the total amount of air exhaled after taking a deep breath, calculated as: VC = Tidal Volume + Inspiratory Reserve Volume + Expiratory Reserve Volume.

Question 32

True or False? Exercise decreases tidal volume.

Answer 32

False. Exercise leads to an increase in tidal volume as more air is moved in and out of the lungs.

Question 33

What is the inspiratory reserve volume?

Answer 33

Inspiratory reserve volume is the difference between the maximum inspiratory level and tidal volume.

Question 34

How is ventilation rate determined using a spirometer?

Answer 34

Ventilation rate is determined by counting the number of inhalations or exhalations per minute on the spirometer trace.

Question 35

What is the maximum expiratory level?

Answer 35

The maximum expiratory level is the maximum volume of air that can be exhaled during expiration.

Question 36

True or False? Exercise typically increases ventilation rate.

Answer 36

True. Exercise causes an increase in ventilation rate as you take more breaths per minute.

Question 37

What are stomata?

Answer 37

Stomata are tiny pores in the lower epidermis of a leaf through which gas exchange occurs.

Question 38

Define transpiration.

Answer 38

Transpiration is the loss of water vapour from leaves by evaporation through the stomata.

Question 39

What is the function of the waxy cuticle on a leaf?

Answer 39

The waxy cuticle prevents gases and water vapour from leaving through the epidermis, ensuring that gas exchange occurs through stomata.

Question 40

True or False? Most stomata are found in the upper epidermis of a leaf.

Answer 40

False. Most stomata are found in the lower epidermis where the temperature is lower, reducing water loss.

Question 41

What is the main difference between palisade and spongy mesophyll tissue?

Answer 41

Palisade mesophyll contains many chloroplasts for maximum photosynthesis, while spongy mesophyll contains large air spaces between cells for gas exchange.

Question 42

What is the function of vascular bundles in leaves?

Answer 42

Vascular bundles form the veins in leaves and are responsible for the transport of substances around the plant, with xylem transporting water and mineral ions, and phloem transporting products of photosynthesis.

Question 43

What is the role of guard cells in a leaf?

Answer 43

Guard cells control gas exchange and water loss by opening or closing stomata.

Question 44

How does air movement affect transpiration rate?

Answer 44

More air movement leads to increased rates of transpiration by maintaining a steeper concentration gradient for water vapour diffusion.

Question 45

How does temperature affect transpiration rate?

Answer 45

Higher temperatures lead to higher rates of transpiration up to a point, as increased kinetic energy causes water molecules to evaporate faster.

Question 46

How does light intensity affect transpiration?

Answer 46

Higher light intensities increase the rate of transpiration up to a point, as stomata open in light to enable gas exchange for photosynthesis. After a point, the stomata may close to reduce water loss as temperatures rise.

Question 47

What is the effect of high humidity on transpiration?

Answer 47

Higher humidity levels reduce the rate of transpiration by decreasing the concentration gradient for water vapour diffusion.

Question 48

What is a potometer?

Answer 48

A potometer is a piece of equipment used to measure the rate of water uptake in plants, which is used to represent the rate of transpiration.

Question 49

Name two different types of potometer.

Answer 49

Two types of potometer are: Bubble potometer Mass potometer

Question 50

What are two advantages of transpiration for plants?

Answer 50

Two advantages of transpiration are: It provides a means of cooling the plant via evaporation It helps in the uptake of mineral ions through the transpiration stream

Question 51

True or False? The movement of water molecules during transpiration is by osmosis.

Answer 51

False. The movement of water molecules during transpiration is not by osmosis, as it does not cross a cell membrane.

Question 52

True or False? Plan diagrams should include individual cells.

Answer 52

False. Plan diagrams should not include individual cells, only tissue layers enclosed by lines should be present.

Question 53

List four rules for labelling plan diagrams.

Answer 53

When labelling your plan diagram remember to: Use a ruler to draw label lines, not freehand Avoid using arrowheads and make sure the label lines stop at the structure Make sure label lines do not cross each other Write all labels horizontally, not at different angles

Question 54

True or False? Plan diagrams can include shaded areas.

Answer 54

False. Plan diagrams cannot include shaded areas.

Question 55

How much space should a plan diagram fill up on a page?

Answer 55

A plan diagram should be big enough to fill up at least half the available space.

Question 56

What is stomatal density?

Answer 56

Stomatal density is the number of stomata per unit of area.

Question 57

Define the term leaf cast.

Answer 57

Leaf cast is an impression of a leaf's surface created by applying and peeling off a layer of nail varnish.

Question 58

True or False? A coverslip is required when examining a leaf cast under a microscope.

Answer 58

False. A coverslip is not required as a leaf cast isn't a biological sample, just an impression of one.

Question 59

What is the ideal range of stomata to count in a single field of view?

Answer 59

The ideal range of stomata to count in a single field of view is between 15 and 100.

Question 60

State the equation for calculating stomatal density.

Answer 60

Stomatal density = Mean number of stomata ÷ Area of field of view

Question 61

What does 'anomalous measurements' mean in the context of stomatal density?

Answer 61

Anomalous measurements are those that deviate from the expected measurements when counting stomata.

Question 62

What is the purpose of using a stage micrometer in this experiment to determine stomatal density?

Answer 62

The purpose of using a stage micrometer is to measure the diameter of the field of view at the same magnification used for counting stomata.

Question 63

Define the term 'reliability' in the context of scientific measurements. (NOS)

Answer 63

Reliability is the level of trust that can be placed in numerical measurements, increased by repeating measurements and obtaining consistent results.