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Learn about the difference between potential and kinetic energy, the laws of thermodynamics, and how energy flows through food chains. Explore the chemistry of life and the role of macromolecules. Understand energy conversion efficiency and the processes of photosynthesis and cellular respiration. Discover how energy is conserved and transformed in various systems.
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Bell Ringer • What is the difference between potential and kinetic energy?
Standard: CommunitiesCLE3255.3.3 Apply the first and second laws of thermodynamics to explain the flow of energy through a food chain or web. • Objectives: • Briefly review the basic chemistry of life. • Distinguish among the types of energy. • Apply the laws of thermodynamics in regards to energy flow in a food chain/web and the “Rule of 10.”
Chapter 4 From Chemistry to Energy to Life
Vocabulary • Energy • Potential energy • Kinetic energy • Chemical energy • First law of Thermodynamics • Second law of Thermodynamics • Autotrophs • Primary producers • Photosynthesis • Cellular Respiration • Heterotrophs • Geothermal Energy • Chemosynthesis
Macromolecules are Building Blocks of Life • 4 Types of Macromolecules • Proteins • Nucleic Acids • Carbohydrates • Lipids
Proteins • Made of long chains of amino acids • What do proteins do? • Provide Structure • Transport Substances • Anitbodies (defend against invaders) • Carry Messages • Act as Enzymes (promote chemical reactions)
Nucleic Acids • Carry hereditary (genetic) information and direct the production of proteins. • Two Types • Deoxyribonucleic acid(DNA) contains the hereditary information. • Ribonucleic acid (RNA) directs the building of proteins.
Carbohydrates • Organic compounds consisting of carbon, hydrogen, and oxygen. • Used for energy • Build structures such as leaves, lobster shells, and fingernails.
Lipids • Include • Fats • Waxes • Steroids • Donot dissolve in water • Used for energy storage, membranes, and hormones.
Cells • Cells - the most basic units of organization. • Biologists classify organisms into two groups based on cell structure • Eukaryotic - cells with organelles (internal structures that perform specific functions), including a nucleus • Prokaryotic - single-celled and lack organelles and a nucleus
Energy Fundamentals • What can energy do to matter? • Change position • Change physical composition • Change temperature
Fundamental Types of Energy • Potential Energy • Energy of position • Examples: rock on a cliff, book on a shelf • Kinetic Energy • Energy of motion • Examples: rock falling off of a cliff, book falling off of a shelf
What is chemical energy? Special type of potential energy that is held in the bonds between atoms. What are some other examples of potential and kinetic energy?
First Law of Thermodynamics • Physical law stating that energy can change from one form to another but cannot be created or lost. The total energy in the universe remains constant and is said to be conserved.
Second Law of Thermodynamics • Physical law stating that the nature of energy tends to change from a more ordered state to a less ordered state. Entropy increases. • Entropy – the degree of disorder in a substance, system, or process
Energy Conversion Efficiency • The degree to which we successfully capture energy • The ECE is the ratio of useful output of energy to the amount that needs to be input. • Gasoline – 16% of energy is used to power automobile, rest is converted to heat • “Regular” or Incandescent Light Bulbs – 5% of energy
Energy Conversion Examples • Gasoline – 16% of energy is used to power automobile, rest is converted to heat • “Regular” or Incandescent Light Bulbs – 5% of energy is converted to light we use, rest escapes as heat • 15% efficiency of current solar energy technology
Electrolysis of water 50%-70% • Electric motors 30-60% • Household refrigerators low end systems ~ 20%; high end systems ~ 40-50% • Fluorescent lamps 28% • Electric shower 90-95% (Overall it would be more efficient to use a heat pump, requiring less electric energy) • Electric heaters around 95% (all energy is always converted into heat anyway) *http://www.azimuthproject.org/azimuth/show/Energy+conversion+efficiency
How efficient are food chains? • Assignment: Review Energy Pyramid Handouts • Use handouts to help you answer the Energy Pyramid Worksheet (worth 10 points)
Light Energy • The sun supplies energy to those organisms that are able to use it to produce their own food; autotrophs, or primary producers. • Autotrophs turn light energy from the sun into chemical energy in a process called photosynthesis.
Photosynthesis • Sunlight powers a series of chemical reactions that convert water and carbon dioxide into sugars and oxygen, providing energy that the organism can use. • Provides food for plants/animals. • The equation: Energy + 6CO2 + 6H2O C6H12O6 + 6O2
Cellular Respiration • The chemical energy created by photosynthesis is used by organisms in the process of cellular respiration. • Releases chemical energy • This extraction of energy occurs in both autotrophs and heterotrophs, or consumers.
Cellular Respiration (contd.) • Cells use the reactivity of oxygen to convert glucose back into water and carbon dioxide, and release energy to perform tasks within cells. • The equation: C6H12O6 + 6O2 6CO2 + 6H2O + Energy (notice it is opposite of photosynthesis)
Geothermal Energy • Another major source of energy besides light • Radiation from radioactive elements deep in the Earth heats the interior of the planet • Causes volcanoes, hot water geysers, and produces geothermal energy
Hydrothermal Vents • Utilize chemical energy instead of light energy • Hydrothermal vents are areas in the deep ocean from which jets of geothermally heated water emerge. • Communities at the vents depend on bacteria at the base of the food web. These bacteria fuel themselves by chemosynthesis, producing sugars.
Chemosynthesis • Process by which bacteria use hydrogen sulfide (H2S) to transform inorganic carbon into organic compounds • Like photosynthesis because: • uses H2O and CO2 to produce sugar • energy in sugar is released during cellular respiration
Bell Ringer • Why are photosynthesis and cellular respiration dependent on one another?
Standard:Embedded Inquiry • CLE3255.Inq.6 Communicate and defend scientific findings. • Objective: Evaluate major hypotheses for the origin of life on Earth.
The Origin of Life • Early Earth: • Formed 4.5 billion years ago • Millions of years, Earth bombarded (hit) by stray material in solar system • Volcanic and tectonic activity was severe • Ultraviolet radiation was intense • Atmosphere – lacked oxygen • Mostly CO2, carbon monoxide (CO), hydrogen, ammonia, methane, H2O vapor
Proposed Hypotheses:Primordial Soup • The heterotrophic hypothesis • Life evolved from a soup of simple inorganic chemicals—carbon dioxide, oxygen, and nitrogen—dissolved in the ocean. • Termed heterotrophic because first life forms used organic compounds as energy source. • Scientists have modified their ideas about early atmospheric conditions, seems less likely to represent what actually happened.
Proposed Hypotheses:Seeds from Space • Idea that bacteria from space crashed to Earth on meteorites and started life here. • The Murchison meteorite, which fell in Australia in 1969, contained many amino acids which survived impact. • Comets have brought large amounts of water, possibly organic compounds, to Earth. • Hypothesis is becoming more plausible (believable) with continued research.
Proposed Hypotheses:Life from Depths • The chemoautotroph hypothesis • Idea that early life was formed in deep-sea vents where sulfur was abundant. • Chemoautotrophs - base of food chain, using chemosynthesis • Some of the most ancient ancestors of today’s life forms likely lived in extremely hot and wet environments.