🙀Philosophy of Biology Unit 9 – Ecology and Ecosystems
Ecology studies how organisms interact with their environment and each other. It explores concepts like niches, habitats, and succession, examining relationships between living and non-living components of ecosystems. This field helps us understand the complex web of life on Earth.
Ecosystems consist of producers, consumers, and decomposers, linked through food webs and energy flow. Nutrient cycles and population dynamics shape community structure. Human activities significantly impact ecosystems, leading to biodiversity loss and environmental challenges that require careful management and conservation efforts.
Ecology studies the interactions between organisms and their environment at various levels of organization (individuals, populations, communities, ecosystems, biosphere)
Abiotic factors are non-living components of an ecosystem that influence organisms (temperature, light, water, soil)
Biotic factors are living components of an ecosystem that interact with each other (plants, animals, microorganisms)
Biotic interactions can be positive (mutualism), negative (competition, predation), or neutral (commensalism)
Niche refers to an organism's role and position within an ecosystem, including its resource use and interactions
Fundamental niche is the full range of conditions and resources an organism can theoretically use
Realized niche is the actual niche an organism occupies, limited by biotic interactions and resource availability
Habitat is the physical environment where an organism lives and includes both abiotic and biotic factors (coral reef, tropical rainforest)
Ecological succession is the gradual process of change in species composition and community structure over time (primary succession on bare rock, secondary succession after disturbance)
Ecosystem Components and Interactions
Ecosystems are composed of both biotic and abiotic components that interact with each other
Primary producers (autotrophs) convert light or chemical energy into organic compounds through photosynthesis or chemosynthesis (plants, algae, some bacteria)
Consumers (heterotrophs) obtain energy and nutrients by feeding on other organisms
Primary consumers (herbivores) feed on primary producers (rabbits, zooplankton)
Secondary consumers (carnivores) feed on primary consumers (hawks, sharks)
Tertiary consumers (top predators) feed on secondary consumers (lions, orcas)
Decomposers (detritivores) break down dead organic matter and recycle nutrients back into the ecosystem (bacteria, fungi)
Trophic levels represent the position of an organism in the food chain based on its feeding relationships (producers, primary consumers, secondary consumers)
Food webs illustrate the complex feeding relationships and energy flow among organisms in an ecosystem (marine food web, terrestrial food web)
Energy Flow and Nutrient Cycles
Energy flows through ecosystems in a unidirectional manner, from the sun to producers to consumers and eventually lost as heat
Trophic efficiency is the percentage of energy transferred from one trophic level to the next, typically around 10%
This low efficiency limits the number of trophic levels in an ecosystem (usually 4-5)
Biomass pyramids represent the amount of organic matter at each trophic level, with producers having the largest biomass
Nutrients cycle through ecosystems in biogeochemical cycles, moving between biotic and abiotic components
Carbon cycle involves the exchange of carbon between the atmosphere, oceans, and living organisms (photosynthesis, respiration, decomposition)
Nitrogen cycle includes nitrogen fixation by bacteria, uptake by plants, and return to the atmosphere through denitrification
Phosphorus cycle is sedimentary, with phosphorus weathering from rocks, uptake by organisms, and eventual deposition in sediments
Humans have significantly altered nutrient cycles through activities such as fossil fuel combustion and fertilizer use
Population Dynamics and Community Structure
Populations are groups of individuals of the same species living in a particular area
Population growth is influenced by birth rates, death rates, immigration, and emigration
Exponential growth occurs when populations increase by a constant percentage over time (bacteria in a petri dish)
Logistic growth occurs when population growth slows as it approaches the carrying capacity (deer in a forest)
Carrying capacity is the maximum population size an environment can sustain given available resources
Intraspecific competition occurs between individuals of the same species for limited resources (plants competing for light)
Interspecific competition occurs between individuals of different species for shared resources (lions and hyenas competing for prey)
Predation is an interaction where one organism (predator) feeds on another (prey), influencing population dynamics of both species
Symbiosis is a close, long-term interaction between two species, which can be mutualistic (both benefit), commensalistic (one benefits, one unaffected), or parasitic (one benefits, one harmed)
Biodiversity and Ecosystem Functioning
Biodiversity refers to the variety of life at all levels of organization, from genes to ecosystems
Species diversity is the number and relative abundance of different species in an area
Genetic diversity is the variety of genes within a species or population
Ecosystem diversity is the variety of ecosystems within a region
Biodiversity is important for ecosystem functioning, stability, and resilience to disturbances
Higher diversity often leads to greater productivity, nutrient cycling, and resistance to invasive species
Biodiversity provides numerous ecosystem services, such as pollination, pest control, and carbon sequestration
Biodiversity hotspots are areas with high species richness and endemism that are threatened by habitat loss (tropical rainforests, coral reefs)
Species-area relationship describes the increase in species richness with increasing area sampled, often used to estimate biodiversity loss due to habitat destruction
Ecological redundancy suggests that some species may perform similar roles in an ecosystem, providing a buffer against species loss
Human Impact on Ecosystems
Humans have significantly altered ecosystems through various activities, often leading to biodiversity loss and ecosystem degradation
Habitat destruction is the primary cause of biodiversity loss, as it reduces available space and resources for species (deforestation, urbanization)
Overexploitation of species through hunting, fishing, and harvesting can lead to population declines and extinctions (whales, elephants, rare plants)
Invasive species, often introduced by humans, can outcompete native species and disrupt ecosystem balance (zebra mussels, kudzu)
Pollution from human activities can harm organisms and alter ecosystem processes (oil spills, plastic waste, pesticides)
Climate change, largely driven by human greenhouse gas emissions, is causing shifts in species ranges, phenology, and interactions (coral bleaching, earlier spring arrivals)
Ecosystem management and conservation efforts aim to mitigate human impacts and protect biodiversity (protected areas, sustainable resource use, habitat restoration)
Philosophical Perspectives on Ecology
Ecocentrism is an ethical stance that values ecosystems and all living beings, not just humans
It emphasizes the intrinsic value of nature and the importance of preserving ecological integrity
Anthropocentrism is an ethical stance that places human needs and values at the center, often prioritizing human welfare over environmental concerns
Environmental ethics considers the moral status of non-human entities and the ethical implications of human actions on the environment
It explores questions such as the rights of nature, the value of biodiversity, and the responsibilities of humans towards other species
Ecological worldviews, such as deep ecology and ecofeminism, challenge dominant anthropocentric paradigms and advocate for a more harmonious relationship between humans and nature
The concept of ecosystem services highlights the benefits humans derive from ecosystems, providing an anthropocentric argument for conservation
The precautionary principle suggests that in the face of uncertainty, actions should be taken to prevent potential environmental harm
Environmental justice examines the disproportionate impact of environmental degradation on marginalized communities and advocates for fair distribution of environmental benefits and burdens
Practical Applications and Case Studies
Ecosystem-based management is an approach that considers the entire ecosystem, including humans, in decision-making and resource management (fisheries management, watershed protection)
Ecological restoration aims to assist the recovery of degraded or destroyed ecosystems (wetland restoration, mine site rehabilitation)
It involves removing stressors, reintroducing native species, and monitoring ecosystem recovery
Agroecology applies ecological principles to the design and management of sustainable agricultural systems (intercropping, biological pest control)
Urban ecology studies the interactions between organisms and their environment in urban settings, informing sustainable city planning and green infrastructure (urban parks, green roofs)
Bioremediation uses microorganisms to break down and remove pollutants from contaminated sites (oil spills, industrial waste)
Climate change adaptation strategies in ecology aim to enhance the resilience of ecosystems and species to changing conditions (assisted migration, habitat connectivity)
Ecological economics integrates ecological principles into economic analysis, recognizing the dependence of human well-being on ecosystem services (natural capital valuation, payment for ecosystem services)
Case studies, such as the reintroduction of wolves in Yellowstone National Park or the restoration of the Everglades, provide real-world examples of ecological principles and management practices in action