Concepts in Ecology

Question 1

What is ecology?

Answer 1

The scientific study of the interactions between organisms and the environment to determine organisms’ distribution and abundance.

Question 2

What are the different types of ecology?

Answer 2

1. Organismal Ecology
2. Population Ecology
3. Community Ecology
4. Ecosystem Ecology
5. Landscape Ecology
6. Global Ecology

Question 3

What is Organismal Ecology?

Answer 3

Studies how an organism’s structure, physiology, and behaviour (in animals) meet environmental challenges

Question 4

What is population ecology?

Answer 4

Analyzes factors that affect population size and how/why it changes over time.

Question 5

What is community ecology?

Answer 5

Examines how interactions between species, such as predation and competition, affect community structure and organization.

Question 6

What is ecosystem ecology?

Answer 6

Emphasizes energy flow and chemical cycling among various biotic and abiotic components of an ecosystem

Question 7

What is the ecological hierarchy?

Answer 7

Individuals: individual organisms of a certain species

Population: group of individuals of the same species living in an area

Community: group of populations of different species in an area

Ecosystem: community of organisms as well as the abiotic factors they interact with.

Question 8

What is a landscape/seascape?

Answer 8

Mosaic of connected ecosystems.

Question 9

What is landscape ecology?

Answer 9

Focuses on the exchanges of energy, materials, and organisms across multiple ecosystems.

Question 10

What is the biosphere?

Answer 10

Global ecosystem: sum of all the planet’s ecosystems and landscapes.

Question 11

What is global ecology?

Answer 11

Examines the influence of energy and materials on organisms across the biosphere.

Question 12

What is a biome?

Answer 12

Major life zones characterized by vegetation types (terrestrial) or by the physical environment (aquatic biomes)

Question 13

What is the equation for population growth?

Answer 13

Change in population size = births + immigrants - deaths - emigrants

Question 14

What are the different models that can predict population growth rate?

Answer 14

1. exponential population growth
2. logistic population growth

Question 15

What is the exponential model of population growth?

Answer 15

Exponential growth model assumes idealized conditions, unlimited resources, constant birth and death rates, and no migration.

Question 16

what is the mathematical prediction of exponential population growth?

Answer 16

dN/dt = rN

dN/dt: rate of change of population size
r: per capita rate of increase
N: population size

Question 17

What is the formula to find the annual per capita rate of increase (r)?

Answer 17

r = b - m

r: per capita rate of increase
b: annual per capita birth rate
m: annual per capita mortality rate

Question 18

What is the logistic population growth model?

Answer 18

Model that limits growth by incorporating carrying capacity and describes how a population grows more slowly as it nears its carrying capacity.

Question 19

what is carrying capacity (K)?

Answer 19

maximum population size the environment can support.

Question 20

What factors limit growth to a carrying capacity in a large population?

Answer 20

Competition, disease and predation

Question 21

What is the mathematical prediction of population growth?

Answer 21

dN/dt = rN * (K-N)/K

dN/dt: rate of change of population size
r: per capita rate of increase
N: population size
K: carrying capacity

Question 22

What is the life history of an organism? What are the three traits it includes?

Answer 22

Traits that affect an organism’s schedule of reproduction and survival. Includes:

1. Age at which reproduction begins
2. How often organism reproduces
3. How many offspring produced during each reproductive cycle.

Question 23

What are life history traits?

Answer 23

evolutionary outcomes reflected in development, physiology, and behaviour of an organism

Question 24

What is the difference between iteroparity and semelparity

Answer 24

Semelparity: species reproduce once and die (big bang reproduction), favoured in highly variable environments

Iteroparity: species produces offspring repeatedly throughout its life, favoured in dependable environments

Question 25

What are ecological trade offs?

Answer 25

An improvement in the status of number of offspring/resources for nurturing is necessarily associated with a decline in or loss the other.

Question 26

What are the types of life history trade-offs?

Answer 26

r-selection/density-independent: selection for traits that maximize reproductive success in uncrowded environments.

K-selection/density-dependent: selection for traits that are sensitive to population density and favoured at high density

Question 27

What is the difference between r-selected and K-selected species?

Answer 27

r-selected: small, fast-growing organisms that live in unstable environments and produce a large number of offspring

K-selected: large, slow-growing organisms that live in stable environments and produce only a few offspring that they can give a lot of care to

Question 28

What are the structural features of communites?

Answer 28

1. species richness
2. biodiversity
3. Keystone species

Question 29

What are Dynamic features of communities?

Answer 29

1. competition
2. predation
3. Herbivory
4. Symbioses

Question 30

What is the difference between structural and dynamic features of communities?

Answer 30

structural: the types and numbers of species present

dynamic: how populations interact with eachother

Question 31

What is biodiversity?

Answer 31

Total number of species, their evenness, composition, and genetic diversity.

Question 32

What is exploitative conservation/direct value of biodiversity?

Answer 32

Functions of individual species that serve humans directly (e.g. food/agriculture, medicine, energy, materials)

Question 33

What is the difference between species richness and species evennness?

Answer 33

species richness: measure of the number of different types of species in an ecosystem

species evenness: measure of the relative abundance of each species

Question 34

What are interspecific interactions?

Answer 34

Interactions between species in a community that may affect the survival and reproduction of each species. They are summarized as +, -, or 0. Includes competition, predation, herbivory, parasitism, mutualism, and commensalism.

Question 35

What is interspecific competition?

Answer 35

-/- interaction that occurs when individuals of different species compete for a resource that limits their growth and survival

Question 36

What are types of interspecific competition?

Answer 36

Exploitative: inderect interactions (resource usage)

Interference: direct interaction (prevent usage)

Question 37

What does an organism allocate its energy to at varying levels of competition?

Answer 37

low competition: growth
moderate competition: growth and reproduction
high competition: growth, reproduction and survival

Question 38

What is competitive exclusion?

Answer 38

Local elimination of the inferior competitor due to a reproductive advantage.

Question 39

What is an ecological niche?

Answer 39

Specific set of biotic and abiotic resources that an organism uses in its environment to fit into the ecosystem.

Question 40

What is the difference between a fundamental niche and a realized niche?

Answer 40

Fundamental: niche potentially occupied by that species, but varies due to competition.

Realized: portion of fundamental niche that the species actually occupies

Question 41

What are the similarities and differences of weather and climate?

Answer 41

Similarities: highly variable, high impact on life, abiotic component of ecosystem

Differences: Weather refers to a specific time and place, climate refers to long term weather patterns on a local, regional or global scale

Question 42

What determines Global climate pattens?

Answer 42

Determined largely by solar energy (causes temp variations which drive evaporation and circulation of air and water) and Earth’s movement in space (causing latitudinal variations in climate).

Question 43

What does the angle at which sunlight hits the earth affect?

Answer 43

intensity and amount of heat and light per unit of surface area

Question 44

How do global air circulation and precipitation patterns play major roles in determining climate patterns?

Answer 44

1. Water evaporation + warm wet air masses in tropics release water and cause high precipitation
2. Dry descending air masses create arid climates
3. Air flowing close to earth’s surface creates predictable global wind patterns
4. Cooling trade wins blow from east to west in tropics while prevailing westerlies blow from west to east in temperate zones.

Question 45

What does elevation affect?

Answer 45

Temperature and Humidity

Question 46

What are Chinooks?

Answer 46

Warm winds that rush down the east side of the Rocky Mountains. Warm Pacific air travels over the mountains, cooling and losing a lot of moisture

Question 47

What are microclimates?

Answer 47

Essentially uniform local climate of a usually small site or habitat determined by fine-scale differences in temp, humidity, and light.

Question 48

What is population density?

Answer 48

Structural feature of population that denote the number of individuals per unit area or volume.

Question 49

What is the difference between crude density and ecological density?

Answer 49

Crude: total number of individuals per unit of the total space

Ecological: number of individuals per unit of the habitat space

Question 50

What is dispersion?

Answer 50

Pattern of spacing among individuals within the boundaries of the population. Includes clumped, uniform, and random dispersion.

Question 51

What is the difference between clumped, uniform and random dispersion?

Answer 51

Clumped: individuals aggregate in patches

Uniform: individuals are evenly distributed

Random: The position of each individual is independent of other individuals

Question 52

What are the three hypothetical survivorship curves?

Answer 52

Type I: low mortality in youth, high mortality in old age

Type II: constant death rate over the organism’s life span

Type III: high mortality in youth and low mortality in survivors

Question 53

What is resource partitioning?

Answer 53

Two or more similar species coexisting where each species only uses part of the available resources.

Question 54

What is predation? What regulates predator and prey populations?

Answer 54

Exploitative +/- interaction between species in which a predator species kills and eats the prey species.

Predatory populations are regulated by food availability, Prey populations are regulated by predation.

Question 55

What is Herbivory? What does it result in?

Answer 55

Exploitative +/- interaction in which an organisms eats parts of a plant or alga.

May result in promotion of plant growth, plant diversity, and mammal communities in grassland.

Question 56

What is symbioses?

Answer 56

All interactions when individuals live in direct and intimate contact with on another; includes mutualism, parasitism, commensalism, altruism.

Question 57

What is mutualism?

Answer 57

(+/+) interspecific interaction that includes obligate/facultative mutualism, trophic mutualism, defensive mutualism, and reproductive mutualism

Question 58

What is the difference between obligate and facultative mutualism?

Answer 58

Obligate: One species cannot survive without the other

Facultative: both species can survive alone

Question 59

What is trophic mutualism?

Answer 59

Both the engaged partners obtain nutrients and energy from each other in a complementary way, both the partners are specialized in such ways.

Question 60

What are two examples of mutualism?

Answer 60

1. Mycorrhizae: fungi absorb water + nutrients, plant gives fungi food
2. Algae provide oxygen for developing salamander embryos, while embryos provide nutrients that facilitate growth of algae

Question 61

What is defensive mutualism and an example?

Answer 61

One species receives protection against predators or parasites in exchange for offering shelter or food to its partner species. (e.g. aphid provides energy source for ants, ants protect aphids)

Question 62

What is reproductive mutualism?

Answer 62

One species increases the reproductive success of the other species, while obtaining nutrients in return. (e.g. plant-pollinator relationship, animals eat fruit and spread seeds in droppings)

Question 63

What is parasitism?

Answer 63

(+/-) symbiotic interaction where the parasite derives its nourishment from the host which results in negative impacts on host fitness (growth, survival, reproduction, increased mortality)

Question 64

What is commensalism?

Answer 64

(+/0) Interaction between species that benefits one species and neither harms nor helps the other

Question 65

What are two examples of commensalism?

Answer 65

1. Clownfish get protection from predators from stinging anemone, having no effect on anemone
2. Remora attaches itself to shark and save energy by remaining stationary and snacks on shark kills.

Question 66

Why is commensalism difficult to confirm?

Answer 66

Any close association between species likely affects both species even if only slightly.

Question 67

What is altruism ad an example?

Answer 67

Behaviours that increase the fitness of another individual, even to the point of potential detriment for themselves. May include reciprocal altruism (individuals sharing food with individuals whom they have received food)

Question 68

What is trophic structure?

Answer 68

Feeding relationships between organisms in the community. Includes food chains (who eats whom) and food levels (branching food chain with complex trophic interactions)

Question 69

What are the trophic levels from bottom to top?

Answer 69

Producers, Primary consumers, Secondary consumers, Tertiary consumers, Apex predators.

Question 70

What is a keystone species?

Answer 70

Species that maintains the local biodiversity of ecosystem and has a disproportionately large effect on community structure, diversity and abundance, relative to its biomass/abundance.

Question 71

What is the result of the removal of a keystone species?

Answer 71

1. Reduced biodiversity and ecosystem degradation
2. Surge in species population, potentially outcompeting and displacing other species (top-down trophic cascade)

Question 72

What is an example of a keystone species?

Answer 72

Sea otters prey on sea urchins and prevent them from overpopulating the seafloor, devouring kelp forests that provide cover and food for many other marine animals.

Question 73

What is a community disturbance?

Answer 73

Disturbance changes a community by removing organisms or changing resource availability (fire, flood, human activity).

Question 74

Why is intermediate disturbance able to foster greater diversity than high or low disturbance?

Answer 74

Species that thrive at both early and late successional stages can coexist.

Question 75

What do high and low level disturbance exclude?

Answer 75

High: slow growing species
Low: Dominant species exclude less competitive species

Question 76

What are succession mechanisms?

Answer 76

Sequence of community and ecosystem changes after a disturbance.

Question 77

How does energy flow through food webs?

Answer 77

Solar energy is harnessed and transformed into biomass and heat, openly flowing through the system.

Question 78

How do nutrients flow through the food webs?

Answer 78

Nutrients are recycled in a closed system, where inputs, transformations and losses happen at any point.

Question 79

What is the rule of thumb in the trophic pyramid?

Answer 79

Only about 10% of energy stored in organic matter in a given trophic level is converted to organic matter in the next trophic level.

Question 80

What are detritivores?

Answer 80

Decomposers that get their energy from detritus (nonliving inorganic material); usually prokaryotes and fungi

Question 81

What are the reservoirs of carbon?

Answer 81

Carbonate rocks: mostly inaccessible (64e6 Gt)

Atmospheric CO2: Biologically available for carbon fixation (548 Gt)

Dissolved CO2: biologically available (630 Gt)

Biomass: Biologically available (610 Gt)