Primary production I & II

Question 1

What is the main driver of primary production?

why is it so important?

Answer 1

photosynthesis

it fixes carbon from the atmosphere

Question 2

What is significant about the primary producton in the oceans?

Answer 2

• Little primary production in open ocean (50 g C m-2 a-1) (light penetration at surface)
• high production along the shores (100) and upwelling areas (300)
• production varies with space and time
• change of pp with season
• terrestrial production is relatively higher

Question 3

What is the most commom phytoplankton species in the ocean?

Answer 3

Dinoflaggelltes

• photoantotrophic
• mixotophic (way of energy requirement changes through out life cycles)

Question 4

Describe the simplyfied process of photosynthesis and how respiration occurs

Answer 4

chemical reaction left to right -> photosynthesis

chemical reactoin right to left -> respiration

Question 5

how is the rate of photosynthesis measured when observing phytoplankton?

Answer 5

Light (photosynthesis & respiration) and dark bottle (respiration only) incubations

Measure

Oxygen concentration

Uptake of 14C

Rate given as mg C m-3 h-1 or mg C mg chl a-1 m-3 h-1

Question 6

What factors affect primary production?

Answer 6

Light

nutrients

mixed layer depth

Question 7

define the term ‘compensation depth’

Answer 7

light limit where phytoplankton can grow

variations in light availability occurs daily, seasonally and with latitude

Question 8

Why is the ocean blue?

Answer 8

blue light penetrates the deepest and has the most energy -> blue light reflected back and received by the eyes.

Question 9

What do accessory pigments do?

Answer 9

They absorb other parts of the light spectrum beyond the general capacity

Question 10

What happens to phytoplankton when it is below the compensation point?

Answer 10

It requires more energy then it can produce with photosynthesis and therefore respirates

Question 11

how does phytoplankton react when it is above the compensation point?

Answer 11

it produces enough excess energy to reproduce and grow

Question 12

What determins the turn over rate of phytoplankton?

Answer 12

Nutrients

• macro nutrients: N, P, O, C, S
• micro nutrients: Fe, Mn, Zn, Na, Cl
• Availability affects growth

Question 13

How does algae affect the benthos when it sinks?

and how are the effects measured?

Answer 13

When algae dies it sinks to the bottom and increases the nitrogen content of the benthos

Evidence

• very low concentrations in surface waters
• redfield ratio (N:P) in seawater = 15:1, tissue 16:1 -> excess to P
• Enrichements experiments

Question 14

What is the mixed-layer depth (D m) and how does it affect primary production?

Answer 14

Mixed-layer depth (Dm) effected by: wind and temperature

Question 15

How did Sverdrup predict the spring bloom in the North Atlantic?

Answer 15

He made simple assumptions by

• observing and measuring the uniform biomass,
• linear PI curve (radiance between light and photosynthesis),
• constant respiration,
• instantaneous mixing,
• no nutrient limitation and exponential decline in light intensity

then he calculated it using a simple equation

Question 16

why is the critical depth (D cr) deeper in the summer?

Answer 16

because there is more sun (longer days) and clearer water

Question 17

How does phytoplankton behave in the North Atlantic?

Answer 17

Winter:

shallow critical depth (D cr) and low production

well mixed and no thermocline

D cr << D m

Spring:

longer days

deeper D cr

reduced mixing

developing thermocline -> stratification

D cr > D m

Summer

warmest, low wind

no mixing, strong thermocline

low production as nutrients are exhausted and predation pressure of zooplankton is high

D cr >> D m

Fall

cooling, increasing wind

thermocline weakens and mixing begins

a convective overturn (warmth) is responsible for a second smaller peak in production in the late summer

Question 18

Why is the surface water clearer in the summer (increased D cr) but the production is low?

Answer 18

Warm low-density water at the surface holds little nutrients with cold heavy nutrient-rich water below.

Division of nutrients occurs but is slow

strong winds can create upwelling events and convective overturn causes some mixing

Question 19

How does phytoplankton behave in the tropics?

Answer 19

little change in season > no difference with persistent no mixing and strong thermocline

D cr >> D m all year long

• depleted nutrients in the shallows (clear water) with storms as only means of mixing*
• deep D cr and deep thermocline*

Question 20

How does phytoplankton behave in the Polar Oceans?

Answer 20

Intense but short-lived production (24h light during short summer)

Winter (dark)

cold, icy, stormy

No thermocline, well mixed

D cr << D m

Spring

cold

No thermocline, well mixed

D cr << D m

Summer (lots of light)

warmest

Slight thermocline, mixing

D cr < D m

Fall

cooling

No thermocline, well mixed

D cr << D m

Question 21

How does phytoplankton behave in coastal areas?

Answer 21

-> more production then open ocean

Exhibit different production cycles to open ocean

Greater productivity

Reasons:

• Terrestrial runoff supplies nutrients
• Water depth < Dcr (limited by bottom)
• No permanent thermocline (isolates nutrients)
• Light usually limiting

Seasonally

High turbidity

-Benthic productivity

Question 22

What are upwelling events?

Answer 22

Constant trade winds blow parallel to the shores and water moves offshore (Ekam transport and Coriolus effect) -> nutrient-rich water gets sucked up from the depth

-Highly productive

(in 1971 20% of the global fish catch came from the Peruvian upwelling system

• Concentrated on a small area (<0.1%)
• supports a high biomass of birds and seals

Question 23

How can algal blooms in the ocean be created artificially?

Answer 23

Adding iron (Fe +) which is critical for phytoplankton but available in low quantities

It could possibly be a CO2 sink as a mitigation strategy for climate change

Primary production increases when Fe+ is added but quick respiration of algae does not create a CO2 sink effect