Introducing Environmental Science and Sustainability 1 Introducing Environmental Science and Sustainability

The Environment (Earth) Life has existed on earth for 3.8 billion yrs Earth well suited for life

Human Impacts on Environment: Population Earth’s Human Population is at 7.5 billion Growing exponentially Hans Rosling- Won’t Exceed 11 Billion

Global Fertility From Worldbank.org

Population and Poverty 1 in 4 people live in extreme poverty

Global Poverty From Worldbank.org

Gap Between Rich and Poor Highly Developed Countries (HDC) Complex industrialized bases, low population growth, high per capita incomes Ex:

Gap Between Rich and Poor Less Developed Countries (LDC) Low level of industrialization, very high fertility rate, high infant mortality rate, low per capita income Ex:

The World by Income From Worldbank.org

Types of Natural Resources Non Renewable Resources Renewable Resources * Note:

Consumption Unsustainable Consumption Occurs when the level of demand on a country’s resources damages or depletes the resource enough to reduce the quality of life for future generations Developing Countries Developed Countries Stats: HDC 86% Al 76% timber harvested 68% energy produced 61% meat eaten 42 % of fresh water consumed Generate 75% world pollution and waste

Consumption From Worldbank.org

Ecological Footprint The average amount of land, water and ocean required to provide that person with all the resources they consume Earth’s Productive Land and Water 11.4 billion hectares Amount Each Person is Allotted (divide Productive Land & Water by Human Pop.) 1.68 hectares Average Global Ecological Footprint of each person 2.87 http://www.footprintnetwork.org – The Living Planet Report (Global Footprint Network)

Ecological Footprint Humans have an ecological overshoot

World Footprint (global hectares)

Ecological Footprint Comparison

Environmental effect of technologies IPAT Model Measures 3 factors that affect environmental impact (I) I = P A T Environmental Impact Number of people Affluence per person Environmental effect of technologies

Environmental Sustainability

Environmental Sustainability The ability to meet current human need for natural resources without compromising the needs of future generations

Tragedy of the Commons Garrett Hardin (1915–2003) Solving Environmental Problems is result of struggle between: Short term welfare Long term environmental stability and societal welfare Common pool resources Garrett used Common Pastureland in medieval Europe to illustrate the struggle

Sustainable Development- Systems Concept Economic development that meets the needs of the present generation without compromising future generations

Environmental Science An interdisciplinary study of human relationship with other organisms and the earth Biology Ecology Geography Chemistry Geology Physics Economics Sociology Demography Politics

Earth System and Environmental Science A set of components that interact and function as a whole Global Earth Systems Climate, atmosphere, land, coastal zones, ocean Ecosystem A natural system consisting of a community of organisms and its physical environment

Earth Systems and Environmental Science Negative feedback Change triggers a response that counteracts the changed condition

Feedback Positive feedback Change triggers a response that intensifies the changing condition

Scientific Method

Controls and Variables in Experiment A factor that influences a process The variable may be altered in an experiment to see its effect on the outcome Control The variable is not altered Allows for comparison between the altered variable test and the unaltered variable test

Five Steps to Addressing An Environmental Problem Five steps are idealistic Case Study: Lake Washington

Assessing Environmental Problem Case Study: Lake Washington Large, freshwater pond Suburban sprawl in 1940’s 10 new sewage treatment plants dumped effluent into lake Effect = excessive cyanobacteria growth that killed off fish and aquatic life

Assessing Environmental Problem Case Study: Lake Washington Scientific Assessment Aquatic wildlife assessment done in 1933 was compared to the 1950 assessment Hypothesized treated sewage was introducing high nutrients causing growth of cyanobacteria Risk Analysis After analyzing many choices, chose new location (freshwater) and greater treatment for sewage to decrease nutrients in effluent

Assessing Environmental Problem Case Study: Lake Washington Public Education/Involvement Educated public on why changes were necessary Political Action Difficult to organize sewage disposal in so many municipalities Changes were not made until 1963! Evaluation Cyanobacteria slowly decreased until 1975 (gone)

Assessing Environmental Problem Case Study: Lake Washington Results