Chapter 36: Population Growth

Chapter 36: Population Growth

Population: Population Concepts interbreeding group of same species Carrying Capacity: maximum population size an ecosystem can sustainably support Critical Number: minimum population size required for its survival

Growth Rate: change in population size per unit time e.g. 10% increase per year accounts for births and deaths Growth rate = Birth rate - Death rate e.g. 10% = 15% - 5% A population is stable, at equilibrium if: Birth rate = Death rate (immigration, emigration also affect population size)

Population Growth Patterns Unchecked population growth will be exponential population increase by the same factor over time (e.g., doubling per generation) can result in a population explosion Exponential growth will eventually resolve into one of 2 basic growth patterns

J-curve Carrying Capacity S-curve (@ equilibrium)

J-curve Growth Occurs when populations undergo exponential growth beyond carrying capacity followed by a crash

S-curve Growth

S-curve growth (aka logistic ) population level hovers around carrying capacity due to environmental resistance typical of established species in stable ecosystems J-curve growth exponential growth beyond carrying capacity followed by crash associated w/ introduced species, loss of predator, habitats that fluctuate may be temporary & resolve to S-curve over time

Environmental Resistance All factors (biotic & abiotic) that limit or resist population increase Density-dependent factors: environmental resistance factors that change in response to population density usually biotic (predators, disease, food supply) provide more resistance as population expands, less as it shrinks (keeps pop. at carrying capacity) Density-independent factors: resistance that is unrelated to population density usually abiotic (changes in weather, fire, )

Predator/Prey Population Cycles Predators provide a form of density-dependent environmental resistance: predator numbers increase/decrease in response to prey populations 160 Snowshoe hare Hare population size (thousands) 120 80 40 Lynx 9 6 3 Lynx population size (thousands) keeps prey populations in check 0 0 1850 1875 1900 1925 Year

Key Terms for Chapter 36 population, growth rate carrying capacity, critical number J-curve, S-curve growth environmental resistance

Chapter 37: Communities & Ecosystems 1. Biological Communities 2. Energy Flow in Ecosystems 3. The Cycling of Matter

1. Biological Communities

Communities and Niches Community: all interacting, living organisms in a given region consists of many different & diverse species, each with a unique niche or role Niche: sum of a species use of resources food, living space, environmental requirements unique for each species, but can overlap between species

How do Species Interact?

Competition Intraspecific: within same species most common type of competition members of same species share same niche important part of natural selection Interspecific: between different species less common since different species tend to have different niches occurs between species with overlapping niches e.g., plants competing for space, sunlight & water

Competitive Exclusion If 2 different species occupy same niche, one will outcompete and eliminate the other evolution selects for species with unique niches

Predator & Prey All species that don t produce their own food (e.g., photosynthesis) or feed on dead, waste material (detritus feeders) prey on other organisms: 3 basic Predator Preyrelationships: *Carnivore Herbivore Herbivore Producer (plant) Parasite Host

Predators have an Important Role Keep other species in balance, their removal can lead to overgrowth of prey, severely disturbing ecosystem balance. Species with essential roles for ecosystem balance are called keystone species: usually predators that prevent domination of the ecosystem by one species e.g. starfish control mussel populations otters & lobsters control urchin populations wolves control deer populations

Symbiotic Relationships Symbiosis: a close, prolonged association between two species Mutualism (both species benefit) e.g., plants & insects; coral & algae many species depend on such relationships for survival Commensalism (one benefits, other unharmed) e.g., barnacles on a whale, epiphytes Parasitism (one benefits, one is harmed) e.g., mistletoe, tapeworms host usually survives

2. Energy Flow in Ecosystems

What is an Ecosystem? a distinct biological community and its abiotic environment biotic = living or derived from living things living organisms and their products, remains abiotic = unrelated to living things non-living matter (water, air, minerals ) ecosystems are functional units of sustainable life

Examples of Ecosystems ecosystems are defined by their plant life biomass varies greatly among ecosystems biomass = dry weight of living material

Energy and Matter in Ecosystems Energy constantly flows through ecosystems solar energy is the ultimate source (usually) converted to chemical PE via photosynthesis passes through the food web, gradually being dissipated as heat Matter is recycled within ecosystems organic material is continually built and broken down using the same elements (requires energy!) **Earth continually gains and loses energy, while matter is essentially confined to the planet**

Energy flows in/out, Matter is recycled Energy flow Chemical cycling Light energy Chemical energy Heat energy Chemical elements

Energy is Transferred by Feeding There are 3 major trophic (feeding) categories: 1) Producers (autotrophs) convert energy of sunlight to food energy by photosynthesis 2) Consumers require food produced by other living organisms feed on producers, or each other herbivores, carnivores, omnivores

3) Detritus Feeders feed on nonliving organic matter dead organisms, organic waste include the decomposers (mostly bacteria & fungi) break down organic material completely very important for recycling nutrients **Without detritus feeders, ecosystems would collapse!**

**There is also a detritus food chain ** Trophic Relationships Trophic levels of the Food Chain : 1 st trophic level = producers photosynthesizers (plants, phytoplankton) 2 nd trophic level = herbivores primary consumers eat producers 3 rd trophic level = carnivores secondary consumers eat herbivores 4 th trophic level = bigger carnivores tertiary consumers eat carnivores

Trophic level Quaternary conusumers Hawk Killer whale Tertiary consumers Terrestrial food chain Snake Mouse Secondary consumers Tuna Herring Aquatic food chain Primary consumers Grasshopper Zooplankton Producers Plant Phytoplankton

Energy Transfer is Inefficient Tertiary consumers Secondary consumers Primary consumers 1,000 kcal 10 kcal 100 kcal ~10% of food energy is transferred to each successive trophic level! Producers 10,000 kcal 1,000,000 kcal of sunlight

Where does this Food Energy go? Most is lost as heat due to respiration used to meet the energy needs of the organism Some is not consumed not all potential food is eaten Not everything is digested digestion is usually incomplete, and some material is indigestible (fiber, etc) Only ~10% is incorporated into organic molecules i.e., potential food for other organisms thus biomass decreases by ~90% at each trophic level

Energy & Human Food Production Trophic level Secondary consumers Human meat-eaters Primary consumers Human vegetarians Cattle Producers Corn Corn Due to inefficient food energy transfer, animal-based food production is much less efficient and more expensive than plant-based food production.

3. The Cycling of Matter

All matter in Ecosystems is Recycled We will focus on the cycling of 3 key elemental nutrients between abiotic reservoirs and organic material: Carbon Nitrogen Phosphorus

The Carbon Cycle CO 2 in atmosphere Photosynthesis Cellular respiration the cycling of carbon between CO 2 & organic molecules Burning of fossil fuels and wood Carbon compounds in water Detritus Higher-level Primary consumers consumers Decomposition

Summary of the Carbon Cycle Carbon from CO 2 in the atmosphere or water is fixed into organic molecules by photosynthesis. this is how carbon enters the food web Carbon in organic molecules eventually returns to atmosphere (or water) in molecules of CO 2 due to: respiration fires volcanic activity burning of fossil fuels* ***Increased CO 2 due to fossil fuel burning results in global warming and lowering of ocean ph***

The Nitrogen Nitrogen in atmosphere (N 2 ) Cycle Nitrogen fixation Nitrogen-fixing bacteria in root nodules of legumes Nitrogen-fixing soil bacteria Detritivores Decomposition Ammonium (NH 4 + ) Assimilation by plants Nitrates (NO 3 ) Denitrifying bacteria Nitrifying bacteria the cycling of nitrogen between N 2, inorganic ammonium & nitrate ions & organic molecules

Summary of the Nitrogen Cycle Nitrogen fixation is one of the most important processes on earth! converts nitrogen compounds in the atmosphere (mainly N 2 ) to ammonium ions (NH 4+ ) nitrifying bacteria convert NH 4+ to nitrate (NO 3- ), the most easily assimilated form of nitrogen for plants plants cannot use atmospheric nitrogen (N 2 ) directly nitrogen thus enters the food web through plants Atmospheric nitrogen is fixed by: cyanobacteria (blue-green algae) in water various soil bacteria and fungi on land

more on the Nitrogen Cycle Denitrification is a microbial process that produces N 2 from nitrates returns nitrogen to the atmosphere, completes the cycle Most nitrogen actually cycles between plants, consumers, & detritus feeders which metabolize organic nitrogen compounds back to NH 4 + **Human activity (synthetic fertilizers, fuel burning) results in excess fixed nitrogen entering ecosystems**

The Phosphorus Cycle the cycling of phosphorus between inorganic phosphate & organic molecules Geologic uplift of rocks Weathering of rocks Sedimentation Runoff Leaching Soil Rain Plant uptake of PO 4 3 Plants Consumption Decomposition

Summary of the Phosphorus Cycle Phosphorus originates as inorganic phosphate (PO 4 3- ) in rocks, leaches into soil & water, and is incorporated into organic compounds by plants Decomposition of dead tissue & animal wastes release inorganic phosphate back into soil to re-enter the food web via plants. **Agricultural runoff (synthetic fertilizer, animal waste), untreated sewage release an excess of phosphorus (& nitrogen) into ecosystems, causing imbalance** due to overgrowth of algae, bacteria & certain plants

Key Terms for Chapter 37 ecosystem, community, niche competition, predation, keystone species symbiosis: mutualism, commensalism, parasitism producer, consumer, autotroph, heterotroph herbivore, carnivore, omnivore, detritus feeder trophic levels, food web, biomass Relevant Review Questions: 1-3, 5, 7, 8, 10, 11, 13