1. Energy and the Environment Science 30: Unit D Chapter 2: Sustainable energy

2. 2.2- Forms of Solar Energy  Solar Energy is recovered in 2 forms: 1.Passive: Energy is absorbed and distributed with no need of a mechanical device. 2.Active: Energy is absorbed but needs a device to pump heat to other parts of the device.  Solar Energy is recovered in 2 forms: 1.Passive: Energy is absorbed and distributed with no need of a mechanical device. 2.Active: Energy is absorbed but needs a device to pump heat to other parts of the device. Solar Energy

3. 1) Passive Energy  Passive solar design uses many features to maximize solar energy:  South facing windows to absorb energy.  Concrete floors to absorb radiation and transfer to other sections using conduction.  Convection currents created due to temperature differences.  Energy efficient building materials.  Roof overhang to prevent overheating in summer.  Passive solar design uses many features to maximize solar energy:  South facing windows to absorb energy.  Concrete floors to absorb radiation and transfer to other sections using conduction.  Convection currents created due to temperature differences.  Energy efficient building materials.  Roof overhang to prevent overheating in summer.

5. 2) Active technologies: Solar heat collector  Uses flat, black boxes to capture energy--- pipes inside have antifreeze that heats up ---pumped to collector--- heat exchanger = energy released to water tank.  Converts solar energy to thermal energy.  Uses flat, black boxes to capture energy--- pipes inside have antifreeze that heats up ---pumped to collector--- heat exchanger = energy released to water tank.  Converts solar energy to thermal energy.

7. 3) Earth energy systems (geothermal)  Similar to solar panels but use a loop of piping in the ground to collect heat.  Pipes filled with antifreeze --- heat from earth’s core --- used to heat building.  Used from the 1940’s on.  Expensive to install but little energy needed to operate = savings!  Similar to solar panels but use a loop of piping in the ground to collect heat.  Pipes filled with antifreeze --- heat from earth’s core --- used to heat building.  Used from the 1940’s on.  Expensive to install but little energy needed to operate = savings! Energy Sources

9. 4) Photovoltaic cells  Converts EMR into electric energy.  Photon absorbed--- electrons ejected (brighter source = more electrons).  Disadvantages:  Electric current is weak = used in small devices or hook many together to create a large current.  Only work in the light (not at night).  Produce only DC current  Expensive to produce.  Converts EMR into electric energy.  Photon absorbed--- electrons ejected (brighter source = more electrons).  Disadvantages:  Electric current is weak = used in small devices or hook many together to create a large current.  Only work in the light (not at night).  Produce only DC current  Expensive to produce.

11. 5) Hydroelectric Power  Moving water possess’ kinetic energy; hydroelectricity generates 19% of worlds electricity = renewable resource.  95% of Quebec’s energy comes from water.  Original source of energy is the sun → water heated by sun evaporates → carried by air currents → forms precipitation and falls at higher altitude. Creates potential energy.  Moving water possess’ kinetic energy; hydroelectricity generates 19% of worlds electricity = renewable resource.  95% of Quebec’s energy comes from water.  Original source of energy is the sun → water heated by sun evaporates → carried by air currents → forms precipitation and falls at higher altitude. Creates potential energy.

12. a) Hydroelectric Dams  Convert gravitational potential energy into electricity.  Store water in reservoir → higher the reservoir level = more kinetic energy created.  Force of water pushes against turbine blades → blades turn and generator convert kinetic energy into electrical energy. Transformers increase voltage.  Convert gravitational potential energy into electricity.  Store water in reservoir → higher the reservoir level = more kinetic energy created.  Force of water pushes against turbine blades → blades turn and generator convert kinetic energy into electrical energy. Transformers increase voltage.

13. Abraham Lake Dam Bighorn dam: -90m high -33km reservoir -Lake level fluctuates 40 m.

14. Wave Energy

15. b) Hydroelectric Power  Provide 5% of Energy in Alberta.  Power must be assessed based on economic, environmental and social concerns:  Renewable, emission free and 80% efficient, low per kWh cost.  Land loss due to reservoir filling (impedes movement of nutrients = ↓ fertility).  Leaching of metals into water = ↓ quality.  Loss of current cities/archeology sites.  Interactions with aquatic ecosystem/species.  Provide 5% of Energy in Alberta.  Power must be assessed based on economic, environmental and social concerns:  Renewable, emission free and 80% efficient, low per kWh cost.  Land loss due to reservoir filling (impedes movement of nutrients = ↓ fertility).  Leaching of metals into water = ↓ quality.  Loss of current cities/archeology sites.  Interactions with aquatic ecosystem/species.

16. 6) Wind Energy  Wind travelling through a smaller opening (tunnel) generates lots of kinetic energy.  SW corner of AB is well suited for this.  Solar energy converted to thermal energy = kinetic energy in air increases → kinetic energy of turbine → electrical energy of generator.  Convection currents create Westerly's that flow across Alberta.  Pincher Creek, Fort Macleod, Lethbridge are prime spots for wind power due to wind patterns.  Wind travelling through a smaller opening (tunnel) generates lots of kinetic energy.  SW corner of AB is well suited for this.  Solar energy converted to thermal energy = kinetic energy in air increases → kinetic energy of turbine → electrical energy of generator.  Convection currents create Westerly's that flow across Alberta.  Pincher Creek, Fort Macleod, Lethbridge are prime spots for wind power due to wind patterns.

18. a) Wind energy limitations  Fastest growing form of electricity generation in Canada; sun provides energy source (renewable).  Versatile (used for cities and homes).  Limitations:  Limited usage due to required conditions.  Variable energy source.  Inefficient conversion (30%) to electricity.  Land loss for wind farms.  Fastest growing form of electricity generation in Canada; sun provides energy source (renewable).  Versatile (used for cities and homes).  Limitations:  Limited usage due to required conditions.  Variable energy source.  Inefficient conversion (30%) to electricity.  Land loss for wind farms.

19. 7) Biomass  Biomass = amount of dried plant matter.  Chemical potential energy from recently living organisms.  Uses and effects:  Waste wood is combusted to create electricity (via turbines and generators).  CO 2 produced is absorbed by plants = carbon neutral process.  Sustainable resource as Carbon is replenished.  Biomass = amount of dried plant matter.  Chemical potential energy from recently living organisms.  Uses and effects:  Waste wood is combusted to create electricity (via turbines and generators).  CO 2 produced is absorbed by plants = carbon neutral process.  Sustainable resource as Carbon is replenished. Natural Resources

21. a) Biofuels  Convert biomass into a biofuel= produced from renewable resources.  Common types: methane (biogas), ethane (ethanol) and mixture (biodiesel).  Composition of fuels:  Methane= decomposing organics (landfills), human waste and manure.  Biodiesel = waste organics from industry (oil).  Ethanol = fuel wood, waste wood, manure, fuel crops (corn, soy) and plant waste.  Convert biomass into a biofuel= produced from renewable resources.  Common types: methane (biogas), ethane (ethanol) and mixture (biodiesel).  Composition of fuels:  Methane= decomposing organics (landfills), human waste and manure.  Biodiesel = waste organics from industry (oil).  Ethanol = fuel wood, waste wood, manure, fuel crops (corn, soy) and plant waste.

22. Ethanol in Gasoline  Produced using yeast to ferment sugars in plants = alcohol!  Ethanol blends with gasoline up to 10%; newer vehicles can use up to 85% blend.  Renewable source (crops regrown).  Benefits and concerns:  New crops absorb CO 2 ; create alternate energy source.  Land taken from crop growing for food; fertilizers used can harm environment.  Inefficient creation of fuel (low energy molecules created, high concentrations of ethanol = toxic).  Produced using yeast to ferment sugars in plants = alcohol!  Ethanol blends with gasoline up to 10%; newer vehicles can use up to 85% blend.  Renewable source (crops regrown).  Benefits and concerns:  New crops absorb CO 2 ; create alternate energy source.  Land taken from crop growing for food; fertilizers used can harm environment.  Inefficient creation of fuel (low energy molecules created, high concentrations of ethanol = toxic).

23. Cow Power

24. Landfill gas  Methane released in landfills as bacteria digest organic waste.  Collect fuel to create biogas.  Clover Bar Landfill (Edmonton) = produces enough biogas for electricity to 4600 homes.  Renewable source.  Methane released in landfills as bacteria digest organic waste.  Collect fuel to create biogas.  Clover Bar Landfill (Edmonton) = produces enough biogas for electricity to 4600 homes.  Renewable source.

25. Biofuel Energy

26. Hydrogen fuel  Hydrogen fuel cell functions as an electrochemical cell does; reactants supply circuit with constant energy.  Hydrogen enters at an electrode, oxygen enters at the opposite → hydrogen reacts and provides electrons (electricity) and ions that complete flow of charge.  Flameless combustion reaction.  Usage limited by high cost of catalysts/Hydrogen availability; very efficient and produce only water vapor as byproduct.  Hydrogen fuel cell functions as an electrochemical cell does; reactants supply circuit with constant energy.  Hydrogen enters at an electrode, oxygen enters at the opposite → hydrogen reacts and provides electrons (electricity) and ions that complete flow of charge.  Flameless combustion reaction.  Usage limited by high cost of catalysts/Hydrogen availability; very efficient and produce only water vapor as byproduct.

27. Hydrogen Cars

28. Transforming the Economy  Alberta is currently a Carbon economy (dependant on non-renewable resources).  Scientists predict that in the next 20 years, carbon economies will switch to hydrogen economies (dependant on renewable resources).  Requires creative combinations of energy sources.  Alberta is currently a Carbon economy (dependant on non-renewable resources).  Scientists predict that in the next 20 years, carbon economies will switch to hydrogen economies (dependant on renewable resources).  Requires creative combinations of energy sources. Eco City