How can it change?

Anything that has mass and takes up space Made up of elements (Periodic Table) Elements form bonds to make compounds

H = hydrogen C = carbon O = oxygen N = nitrogen P = phosphorus S = sulfur Cl = chlorine F = fluorine Br = bromine Na = sodium Ca = calcium Pb = lead Hg = mercury As = arsenic U = uranium

Protons—positive charge, different for every element Neutrons—neutral; can be the same for two elements; can be different for the same element Electrons—negatively charged; involved in the bonding of elements to one another to form compounds Make up all elements

Organic—contain at least two carbon atoms combined with atoms of one or more other elements, methane is the exception Inorganic—everything else Hydrocarbons Chlorinated hydrocarbons Carbohydrates (simple and complex) Proteins Nucleic acids Lipids

Forms and Laws

Capacity to do work or transfer heat Potential and Kinetic Transferred through convection, conduction, and radiation Energy efficiency is the measure of how much useful work is accomplished by a particular input of energy into a system

Connections and Organization

Any form of life is an organism

A group of individual s of the same species living in a particular place

Populations of different species living in a particular place, and potentially interacting with each other

Community of different species interacting with one another and with their nonliving environment of matter and energy

Parts of the earth’s air, water, and soil where life is found

EARTH AS A SYSTEM OF 4 SPHERES Atmosphere, Biosphere, Hydrosphere, Lithosphere, Anthrosphere

Atmosphere The Earth is surrounded by a blanket of air, which we call the atmosphere. It reaches over 560 kilometers (348 miles) from the surface of the Earth, so we are only able to see what occurs fairly close to the ground. Early attempts at studying the nature of the atmosphere used clues from the weather, the beautiful multi-colored sunsets and sunrises, and the twinkling of stars. With the use of sensitive instruments from space, we are able to get a better view of the functioning of our atmosphere. Life on Earth is supported by the atmosphere, solar energy, and our planet's magnetic fields. The atmosphere absorbs the energy from the Sun, recycles water and other chemicals, and works with the electrical and magnetic forces to provide a moderate climate. The atmosphere also protects us from high- energy radiation and the frigid vacuum of space. The envelope of gas surrounding the Earth changes from the ground up. Four distinct layers have been identified using thermal characteristics (temperature changes), chemical composition, movement, and density.

Layers of the Atmosphere Thermosphere—highest Mesosphere Stratosphere (contains ozone) Troposphere---layer we live in

Earth as a system Can you think of any other spheres that interact with the atmosphere? Biosphere? Hydrosphere? Lithosphere?

Biosphere The term "Biosphere" was coined by Russian scientist Vladimir Vernadsky in the The biosphere is the life zone of the Earth and includes all living organisms, including man, and all organic matter that has not yet decomposed. Life evolved on earth during its early history between 4.5 and 3.8 billion years ago and the biosphere readily distinguishes our planet from all others in the solar system. The chemical reactions of life (e.g., photosynthesis-respiration, carbonate precipitation, etc.) have also imparted a strong signal on the chemical composition of the atmosphere, transforming the atmosphere from reducing conditions to and oxidizing environment with free oxygen. The biosphere is structured into a hierarchy known as the food chain whereby all life is dependent upon the first tier (i.e. mainly the primary producers that are capable of photosynthesis). Energy and mass is transferred from one level of the food chain to the next with an efficiency of about 10%. All organisms are intrinsically linked to their physical environment and the relationship between an organism and its environment is the study of ecology. The biosphere can be divided into distinct ecosystems that represent the interactions between a group of organisms forming a trophic pyramid and the environment or habitat in which they live.

Biotic vs. Abiotic Bio = means life Biotic—living parts or components Abiotic—nonliving parts of components (air, water, temperature)

Earth as a System Can you think of any other spheres that interact with the biosphere? Atmosphere? Hydrosphere? Lithosphere?

Hydrosphere The hydrosphere includes all water on Earth. In one respect, planet Earth is a misnomer in that 71% of the earth is covered by water and only 29% is terra firma. Indeed, the abundance of water on Earth is a unique feature that clearly distinguishes our "Blue Planet" from others in the solar system. Not a drop of liquid water can be found anywhere else in the solar system. It is because the Earth has just the right mass, the right chemical composition, the right atmosphere, and is the right distance from the Sun (the "Goldilocks" principle) that permits water to exist mainly as a liquid. However, the range of surface temperatures and pressures of our planet permit water to exist in all three states: solid (ice), liquid (water), and gas (water vapor). Most of the water is contained in the oceans and the high heat capacity of this large volume of water (1.35 million cubic kilometers) buffers the Earth surface from large temperature changes such as those observed on the moon. Water is the universal solvent and the basis of all life on our Planet. It is an essential life-sustaining resource which led Benjamin Franklin to comment "When the well's dry, we know the worth of water."

Hydrosphere

Earth as a System Can you think of any other spheres that interact with the biosphere? Atmosphere? Biosphere? Lithosphere?

Lithosphere The lithosphere (from the Greek for "rocky" sphere) is the solid outermost shell of a rocky planet. On the Earth, the lithosphere includes the crust and the uppermost layer of the mantle (the upper mantle or lower lithosphere) which is joined to the crust. The lithosphere is broken up into different plates as shown by the picture.GreekplanetEarthcrustmantle The distinguishing characteristic of the lithosphere is not composition, but its flow properties. Under the influence of the low-intensity, long-term stresses that drive plate tectonic motions, the lithosphere responds essentially as a rigid shell and thus deforms primarily through brittle failure, while the asthenosphere accommodates strain through plastic deformation. Both the crust and upper mantle float on the more plastic asthenosphere. The crust is distinguished from the mantle, and hence the upper mantle, by the change in chemical composition that takes place at the Moho discontinuity. The thickness of the lithosphere varies from around 1.6 km (1 mi) at the mid- ocean ridges to approximately 130 km (80 mi) beneath older continental crust. The thickness of the continental lithospheric plates is probably around 150 kilometers (93 mi).plate tectonic asthenospherestrainplasticMoho discontinuity As the cooling surface layer of the Earth's convection system, the lithosphere thickens over time. It is fragmented into relatively strong pieces, called tectonic plates, which move independently relative to one another. This movement of lithospheric plates is described as plate tectonics. There are two types of lithosphereconvection tectonic plates

Lithosphere

Earth as a System Can you think of any other spheres that interact with the biosphere? Atmosphere? Biosphere? Hydrosphere?

Anthrosphere Man and his direct ancestors (hominids) have graced the planet for only about three million years. For almost all of this period the human population totaled less than 5 to 10 million individuals. Homo sapiens have increased their numbers exponentially from 1650 to present rising to the current population of 5.5 billion. If this growth continued unabated, the human population would reach 8 billion in the year 2000, 14 billion in the year 2010, 60 billion in the year 2020, and infinity by the year Of course, unlimited growth in an environment of finite resources is impossible because growth will eventually deplete the available resources and the population will collapse. Indeed one of the kindest things that the human species could do for planet Earth is to control the rate of growth of the anthrosphere.

Anthrosphere Interactions of Homo sapiens with all aspects of the environment We are going to look at each sphere, the interactions, and the solutions as well as the problems created by the human race.