| Word | Definition (or diagram/translation) |
|---|---|
| Particle Theory of Matter | Theory that describes the composition and behaviour of matter as being composed of small particles with empty space |
| Matter | Substance that has mass and occupies space |
| Mechanical Mixture | A heterogeneous mixture which one can physically separate |
| Suspension | A heterogeneous mixture where insoluble solid particles are distributed throughout a fluid, floating freely/td> |
| Alloy | A combination of 2+ metals |
| Mixture | A substance that is made up of at least 2 types of particles |
| Qualitative property | A property of a substance that is not measured and doesn't have a numerical value, such as colour, odour, and texture |
| Qualitative observation | An numerical observation |
| Precipitate | A solid that separates from a solution |
| Density | A measure of how much mass is contained in a given unit volume of a substance; calculated by dividing the mass of a sample of its volume (mass/volume) |
| Element | Element An element is made up of the same atoms throughout, and cannot be broken down further |
| Metal | a solid material that is typically hard, shiny, malleable, fusible, and ductile, with good electrical and thermal conductivity |
| Pure substance | A substance that is made up of only one type of particle |
| Atom | The smallest unit of matter found in substances |
| Solution | A uniform mixture of 2 or more substances |
| Colloid | is substance with small particles suspended in it, unable to be separated by gravity |
| Emulsion | A mixture of 2 insoluble liquids, in which one liquid is suspended in the other |
| Physical Property | Characteristic of a substance that can be determined without changing the makeup of the substance |
| Characteristic | A physical property that is unique to a substance and can be used to identify the substance |
| Periodic Table | a table of the chemical elements arranged in order of atomic number, usually in rows, so that elements with similar atomic structure (and hence similar chemical properties) appear in vertical columns. |
| Compound | Compounds are chemically joined atoms of different elements |
| Non-Metal | A substance that isn’t a metal |
| Physical Change | A change in which the composition of the substance remains unaltered` and `no new substances are produced |
| Chemical Change | A change in the starting substance and the production of ONE or more new substances Original substance does not disappear BUT the composition is rearranged |
| Molecule | Two or more non-metal atoms joined together |
| Diatomic Molecules | Molecules that only consists of 2 elements `H O F BR I N CL` - `hyrodgen`, `oxygen`, `fluorine`, `bromine`, `iodine`, `nitrogen`, `chlorine`. |
| Ions | A Charged particle, that results from a loss (cation - positve, less electrons) or gain (anion - negative, more electrons) of electrons when bonding |
| Electron | Negatively Charged |
| Proton | Positively Charged |
| Neutron | Neutral Charged | Ionic Charge | The sum of the positive and negative charges in a ion |
| Covalent Bond | The sharing of electrons between atoms when bonding |
| Valence Electrons | Number of electrons on the most outer orbit/shell of the element |
## Quantitative physical Properties
- **```Density```**: amount of ```stuff``` (or mass) per unit volume (g/cm3)
- **```Freezing Point```**: point where water solidifies (0oC)
- **```Melting Point```**: point where water liquefies (0oC)
- **```Boiling Point```**: point where liquid phase becomes gaseous (100oC)
## Common Qualitative Physical Properties
|Type|Definition|Example|
|:---|:---------|:------|
|Lustre|Shininess of dullness
### Trends On The Periodic Table
- The first column are the `Alkali metals`.
- They are shiny, have the consitency of clay, and are easily cut with a knife.
- They are the **most reactive** metals.
- They react violently with water.
- Alkali metals are **never found as free elements in nature**. They are always bonded with another element.
- The second column are the `Alkaline earth metals`.
- They are **never found uncombined in nature**.
- The last column are the `Noble gases`.
- **Extremely un-reactive**.
- The second last column are the `Halogens`.
- The **most reactive non-metals**
- They **react with alkali metals to form salts**.
- The middle parts are the `transition metals`.
- They are good conductors of heat and electricity.
- Usually bright coloured.
- They have properties similar to elements in their same family
- Many of them combine with oxygen to form compounds called oxides.
- The rows outside the table are the `Inner tranistion metals`.
- The **left** to the **staircase** are the metals and the **right** are the non-metals. The ones touching the **staircase** are the `metalloids`.
### How To Read An Element
## History of The Atom
|Person|Description|Picture|
|:-----|:----------|:------|
|Democritus|All matter can be divided up into smaller pieces until it reaches an unbreakable particle called an ATOM (cannot be cut)
|
|John Dalton|- Billbard model, atoms of **different elements are different**
|
|
|Ernest Rutherford|- Discovered that the postively charged **nucleus**. 
|
|
|Niels Bohr|- Discovered that electrons **orbit the nucleus in fixed paths**, each electron has a **definite** amount of energy, further from nucles = more energy.
|
|James Chadwick|- Discovered the neutron, mass of neutron = mass of proton (basically)
|
## Carbon
## Atoms
- Subscripts - tells us how many of the atom are there, for example N2 means there are 2 nitrongen atoms.
- Use distrubutive property if there are brackets and a subscript, for example, (CO)2 is equilivant to C2O2.
- Atoms are stable if they have a full valence shell (noble gases)
- Each family has the same amount of valence electrons as their family number, so `alkali metals` would have 1 valence electron, `alkaline earth metals` will have 2, `halogens will have` 7 and `noble gases` would have 8.
- They will also have the same amount of protons as their `atomic number`.
- **Number of protons = Number of electrons**.
- **Number of neutrons = mass - atomic number/number of protons**.
## Bohr-Rutherford / Lewis-Dot Diagrams
- **Bohr-Rutherford**
- Draw nucleus, and draw the apprioate number of orbits.
- Put number of **protons** and **neutrons** in the nucleus.
- Draw the correct number of electrons in each orbit
- **Lewis-Dot Diagrams**
- Draw element symbol
- Put the right number of valence electrons around the symbol, perferably in pairs
### Bonding
- To combine 2 atoms, each element wants to be stable. So they each want a full valence shell, (outer shell) so they are stable.
- They can either `gain`, `lose` or `share` electrons in order to become stable.
- Example:
- Oxygen and Hydrogen, in order to become stable, they all need 8 valence electrons. Hydrogen has 1, oxygen has 6, so we bring in another hyrdogen and we let them share all their electrons, turning into H2O, or water.
- Use **arrows** to show gaining or losing electrons.
- **Circle** to show sharing of electrons.
## Naming of Ionic Bonds
1. Write cation (metal) first
2. Write anion (non-metal) second
3. Change the ending of the non-metal to ```ide```.
## Decomposition
- A chemical change used to break compounds down into simpler substances
- Energy must be ADDED
- Using electricity
- Adding thermal energy
## Catalyst
- Substance that accelerates a chemical change without being consumed OR changed itself
## Uses of Hydrogen Peroxide
- On cuts/scraps
- Blood has a catalyst = see bubbling O2
- Cleans contact lenses
- Bubbling removes dirt
- Bleaches
- React with compounds that provide color
- RESULT = no colour (bleach blond hair/teeth)
# Unit 3: Biology
## Terms
- `Habitat`: Placce where organisms live
- `Biotic`: Living components (their remains AND features)
- Bears, insects, micro-organisms, nests
- `Abiotic`: Non-living components
- Physical/chemical components
- Temperature, wind, humidity, precipitation, minerals, air pressure
- `Sustainability`: **The ability to maintain natural ecological conditions without interruption, weakening, or loss of value.**
- `Community`: Individual from all of the DIFFERENT populations (communities of different species)
- `Ecosystem`: Term given to the community and its interactions with the abiotic environment
- `Sustainable Ecosystem`: An ecosystem that is maintained through natural processes
- `Ecological niche`: Every species interacts with other species and with its environment in a unique way. This is its role in an ecosystem (e.g. what it eats, what eats it, how it behaves, etc.)
- `Biodiversity`: The variety of life in a particular ecosystem, also known as biological diversity.
- Canada is home to about 140 000 to 200 000 species of plants and animals. Only 71 000 have been identified.
- `Species Richness`: the number of species in an area.
- Diverse ecosystem = high species richness.
- Higher close to the equator.
- Ex. Amazon rainforest home to more than 200 species of hummingbirds, Ontario only has a single species.
- `Population`: A group of organisms of one species that interbreed and live in the same place and time.
- Population often change due to both **natural and artifical** factors (human activity).
- `Carry Capcity`: The maximum population size of a **particular species** that a given ecosystem can sustain.
- `Pollution`: harmful comtaminants released into the enviornment.
- `Bioremediation`: the use of micro-organisms to consume and break down environmental pollutants.
- `Photosynthesis`: The process in which the Sun’s energy (LIGHT) is converted (put together with) into chemical energy AS GLUCOSE (sugar).
- `Succession`: The gradual and usually predictable changes in the composition of a community and the abiotic condtions following a disturbance.
- `Producer`: Organism that makes its own energy-rich food using the Sun’s energy.
- `Consumer`: Organism that obtains its energy from consuming other organisms.
- `Eutrophication`: Overfertilzation of staganat bodies of water with nutrients
- `Heterotrophs` Organisms that feed on others
- `Bioaccumulation`: The process by which **toxins accumulate in the bodies** of animals. (Eg, DDT). **They cannot be easily excreted from the body.**
- `Bioamplification`: The **increase in concentration of a substance** such as a pesticide as we move up trophic level within a food web. **It happens because of bioaccumulation**. (Sometimes called `biomagnification`).
- `Oligotrophic` Bodies of water that are **low** in nutrients. (clear water, opposite to `eutrophic`).
- `Watershed` (drainage basin): Area of land where **ALL WATER** drains to a single river or lake.
- `Invasive Species`: A non-native species whose intentional or accidental introduction negatively impacts the natural environment.
## The Spheres of Earth
### Atmosphere
- The layer of `gases` above Earth's surface, extending upward for hundreds of kilometers.
- `78% nitrogen gas`.
- `21% oxygen gas`.
- `< 1% argon, water vapour, carbon dioxide & other gases`.
- Critical to (almost all) life on Earth.
- Acts like a **blanket & moderates surface temperature**.
- Insulation prevents excessive **heating** during the day & **excessive cooling** during the night.
- Average surface temperature droup from **15C to -18C**.
- Blocks some **solar radiation (most ultraviolet light)**.
### Biosphere
- The regions of Earth where `living organisms` exist.
- Describes **the locations in which life can exist within the lithosphere, atmosphere and hydrosphere**.
- Biosphere is thin in comparison to diameter of the Earth.
- ALL conditions required for **life must be met and maintained within this thin layer of ground, water, and nutrients to survive**.
### Hydrosphere
- All the `water` found on Earth, above and below the Earth's surface.
- Includes
- **Oceans**
- **Lakes**
- **Ice**
- **Ground Water**
- **Clouds**
- 97% of water on Earth **is in the oceans**.
### Lithosphere
- The `hard part` of Earth's surface.
- **Rocky outer shell of Earth**.
- Consists of:
- **Rocks and minerals that make up mountains, ocean floors, and Earth's solid landscape**
-Thickness: **50 - 150km**.
## Energy Flow
- `Law of Conservation of Energy`: Energy **can not** be **created** or **destroyed**. It can only be transformed or transfeered.
- Note that Photosynthesis and Cellular respiration are nearly **THE EXACT OPPOSITE**.
### Types of Energy
- #### Radiant Energy
- Energy that travels through EMPTY SPACE
- #### Thermal Energy
- Form of energy TRANSFERED DURING HEATING/COOLING
- Keeps the Earth's surface warm
- CANNOT provide organisms with energy to grow & function
- #### Light Energy
- VISIBLE forms of radiant energy
- Can be used by some organisms (CANNOT be stored)
- #### Chemical Energy
- Used by living organisms to perform functions (growth, reproduction, etc.)
- MUST be replaced as it is used
### Photosynthesis
- Plants use the sun to make energy in the form of glucose or sugar.
- Animals cannot make their own food (glucose, energy)
- Must get our food from plants.
- Plants are the first step in the food chain
- Oxygen released during photosynthesis is necessary for all living things
### Cellular Respiration
- Process of converting sugar into carbon dioxide, water and energy
- Makes stored energy available for use
- Takes place in the mitochondria
1. Original energy stored in the sugar is released
2. Occurs continuously
3. Does NOT require light energy
- **BOTH** producers **AND** consumers perform cellular respiration
- ALL humans are consumers (unless you’re the hulk)
#### Steps in Cellular Respiration
- Mitochondria takes in nutrients
- Glucose and Oxygen
- Breaks both nutrients down
- Creates energy for the cell
- #### REVERSE of Photosynthesis
- Sugar breaks down into **CARBON DIOXIDE** and **WATER**
- Release of energy when this happens
## Feeding Relationships
- Energy flow through an ecosystem in one direction, from the sun or inorganic compounds to autotrophs (producers) and then to various hetrotrophs (consumers).
- Food are a series of steps in which organisms transfers energy by eating or eaten (pg. 43).
- Food webs show the complex interactions within an ecosystem (pg. 44).
- Each step in a food chain or web is called a `trophic` level. Producers make up the first step, consumers make up the higher levels. E.g. first trophic level are producers, second trophic level are primary consumers, etc.
- Detrivores + scavengers are off to side (with all arrows pointing on it.
- **First Trophic Level**: `Plants`.
- `10% rule`, Only 10% of energy is stored in each organism, 90% of energy is lost (heat consumption).
## Ecological Pyramids
- Food chains and food webs do not give any information about the numbers of organisms involved.
- This information can be shown through ecological pyramids.
- An ecological pyramid is a diagram that shows the amount of energy or matter contained within each trophic level in a food web or food chain.
|Pyramid|Description|Picture|
|:------|:----------|:------|
|Pyramid of Biomass|Show the **total** amout of `living tissue` available at each `trophic` level. This shows the amount of tissue available for the next `trophic` level. 
|Numbers Pyramids|Shows the number of organisms at each trophic level per unit area of an ecosystem. 
|
|Energy Pyramid|Shows the amount of energy input to each trophic level in a given area of an ecosystem over an extended period.
|
**NOTE FOR ENERGY PYRAMIDS**: In nature, ecological
efficiency varies from `5%` to `20%` energy available between successive trophic levels (`95%` to `80%` loss). About 10% efficiency is a general rule. `Rule of 10’s` at each level.
## Cycles
|Cycle|Picture|
|:----|:------|
|Water Cycle|
|
|Carbon Cycle|
|
|Nitrogen Cycle|
|
## Water Cycle
- Continuous movement of water on, above and below the surface of the Earth
### Key Terms:
- Water moves from one reservoir to another (ocean to
atmosphere, river to lake)
- Evaporation, Condensation, Precipitation, Percolation (Infiltration, water seeping into ground), Run-off, transpiration (plants losing water to air)
- Forms: Solid (ice), Liquid (water), Gas (vapour)
### STEPS/PROCESS:
- Exchange of energy leads to:
- Temperature Change, Climate
- Condenses 🡪 occurs during cooler temp
- Evaporation 🡪 happens during warmer temp
- **Evaporation**:
- purifies the water
- New fresh water for the land
- **Flow of liquid water and ice**
- Transports minerals across the globe
- **Reshaping the geological features of Earth**
- Erosion and sedimentation
### Human Inpacts
- Humans building dams (flooding is a problem!)
- Deforestation contributes to global warming, hence melting glaciers and causing flooding in cities
- (Also less transpiration from clear cutting) – pg. 48
- Factories and cars pollute the air, leading to acid precipitation
- Oil spills destroy aquatic ecosystems
## Carbon Cycle
- Fourth most abundant element in universe
- Building block of all living things
- Main Pathway – in and out of living matter
-
### STEPS/PROCESSES
- All living organisms contain carbon.
- CO2 is a waste product of cellular respiration
- Plants use carbon dioxide and water to form simple sugars (photosynthesis)
- Light Energy --> Chemical Energy
- Carbon dioxide is `returned to the enviornment by:
1. `Resipiration` in plants, animals & micro-organisms.
2. `Decay` caused by micro-organisms (decompoers).
3. `Combustion` i.e. Burning fossil fuels.
- **Phtosynthesis**
- CO2 is converted to glucose using water and sunlight
- **Cellular Respiration**
- Breaks down glucose to release energy, expel CO2
- **Oceans are a HUGE carbon sink**.
### Human Impacts
- **Mining & burning fossil fuels**: Speed up release of CO2 to the atmosphere.
- **Deforestation & clearing vegetation**: ↑ CO2 in atmosphere.
- **Acid rain**: release CO2 from limestone.
- CO2 in the atmosphere is now higher than it has been in at least **800 000 years**.
## Nitrogen Cycle
- The most abudant gas in the atmopshere (~78%)
- `Nitrogen Fixation`: The process that causes the strong two-atom nitrogen molecules found in the atmopshere to break apart so they can combine with other atoms.
- `Nitrogen gets fixed`: Whenit is combined with oxygen or hydrogen.
- An essential component of DNA, RNA, and protenis - the building blocks of life.
- Atmopspheric nitrogen = N2
- Most living organisms are `unable` to use this form of nitrogen
- Therefore, must be **converted** to a usable form!
### STEPS/PROCESSES
### Nitrogen Fixation
- Most of the nitrogen used by living things is taken from the atmosphere by certain bacteria in a process called `nitrogen fixation`.
- These microorganisms convert nitrogen gas into a variety of nitrogen containing compounds such as nitrates, nitrites, and ammonia
- Lightning and UV radiation also fix small amounts of it
- Humans add nitrogen to soil through fertilizer
- 3 ways nitrogen to get fixed
1. Atmopheric Fixation
- Lightning Storms
- stroms and fuel burning in car engines produce nitrates, which are washed by rain into soil water.
2. Industrial Fixation
3. Biological Fixation
- 2 types
1. Free living Bacteria
- Highly specialized bacteria live in the soil and have the ability to combine atmospheric nitrogen with hydrogen to make ammonium(NH4+).
- Nitrogen changes into ammonium.
2. Symbiotic Relationship Bacteria
- Bacteria live in the roots of legume family plants and provide the plants with ammonium(NH4+) in exchange for the plant's carbon and a protected biome.
- `Nitrites` are absorbed by plant roots and converted to plant protein.
- `Nitrates` **can be absorbed by other plants** to continue the cycle.
- `Denitrifying bacteria` convert soil nitrates into N2 gas
- This is a `loss` of N2 from the cycle
### Human Impacts
- Nitrates also `enters` the cycle **through the addition of nitrogen rich fertilizers to the soil** – made industrially from nitrogen gas (Eutrophication – pg. 60)
- Factories release NO compounds (acid rain)
## Nutrient Recycling
- There is a `limited` amount of `nutrients` on earth
- e.g. you are probably aware of the water cycle – where water is
constantly being `recycled` in nature.
- There are similar cycles for all nutrients.
- When plants and animals die, their nutrient content is `not wasted`.
- Bacteria and fungi decompose the remains and release the nutrients back into the abiotic environment (i.e. into the soil, nearby water and air).
- Nutrients are then taken up by other plants and used to make new organic material.
- This material is passed on down the food chains and is reused by all the chain members.
- When death occurs for these members, the nutrients are again returned to the abiotic environment and the cycling of nutrients continues in this circular way.
- This ensures that there is no real longterm drain on the Earth’s nutrients, despite millions of years of plant and animal activity.
## Changes In Population
- The carry capcacity of an ecosystem depends on numerous biotic and abiotic factors.
- These can be classified into two categories.
1. `Density dependent factors`
2. `Density independent factors`
### Density Independent Factors
- DIF’s can affect a population no matter what its density is. The effect of the factor (such as weather) on the size of the population **does not** depend on the **original size** of the population.
- Examples:
- unusual weather
- natural disasters
- seasonal cycles
- certain human activities—such as damming rivers and clear-cutting forests
### Density Dependent Factors
- DDF’s affect a population **ONLY** when it reaches a certain size. The effect of the factor (such as disease) on the size of the population depends on the **original size** of the population
- Examples:
- Competition
- Predation
- Parasitism
- Disease
## Relationships
1. **Symbiosis**
- Two different organisms associate with each other in a close way.
- Is the interaction between members of `two different species` that live together in a close association.
- **Mutualism (+/+)**
- Both species benefit from the relationship.
- (eg. human intestine and good bacteria, bees and flowers, clownfish and sea anemone, cattle egret and cow).
- **Commensalism (+/0)**
- one species benefits, the other is **unaffected**.
- (eg. beaver cutting down trees, whales and barancles).
- **Parasitism (-/+)**
- one species is harmed, the other **benefits**.
- (eg. lice and humans, mosquito and humans).
- **Competition (-/-)**
- neither species benefits. Can be harmed. (-/-).
- **Neutralism (0/0)**
- both species are unaffected (unlikely).
- True neutralism is extremely unlikely or even impossible to prove. One cannot assert positively that there is absolutely no competition between or benefit to either species.
- Example: fish and dandelion
| + | Parasitism and Predation | Commensalism | Mutalism |
|---|---|---|---|
| 0 | Neutralism | Commensalism | |
| - | Competition | Parasitism and Predation | |
| - | 0 | + |
### Tundra
* Most **NORTHERN** biome of Canada.
* Low temperatures + lots of **PERMAFROST**
* Low decomposition rate.
* Plants grow slower due to cold
* `Species`: Polar bears, Caribou, Arctic foxes.
### Boreal Forest
* **Largest** biome in Canada.
* Warmer weather+plenty rainfall.
* Acidic Soil - Limits variety of plants + slows down decomposition.
* `Species` Grey wolves, conifers, moss, black bears.
### Grassland
* Moderate rainfall (supports grass not trees).
* Dry $`\rightarrow`$ Fire $`\rightarrow`$ Fire prevents larges trees from growing.
* Very **Fertile** black soil (high decomposition rate)
* Large portions of this biome are replaced by farms in Canada.
* `Species`: Bison, Snakes, fescue grasses, voles.
### Temperate Deciduous Forest
* Layers of canopy trees, understorey trees, shrubs, ground vegetation.
* Variety oof plants + species.
* Fast decomposition rate (warm temperatures).
* Large portions of this biome used by humans for cities.
* `Species`: Shrews, decidious trees, deer, black bears.
### Mountain Forest
* Temperatures vary with elevation
* Windy + cool summers
* Heavy precipitation on leeward side of mountains
* `Species` Elk, cougar, large coniferous trees, ferns.
## Introducing Ecosystems
- Most ecosystems are **SUSTAINABLE**.
### Ecosystem Services
- **Cultural Services**
- Benefits relating to our enjoyment of the environment.
- Ex. Recreational, aesthetic and spiritual experiences when we interact with natural surroundings.
- Ecotourism: tourists engage in environmentally responsible travel to relatively undisturbed natural areas.
- Ex. Canada’s Wilderness.
- **Ecosystem Products**
- Humans use products produced by the ecosystem.
- Hunt animals and harvest plants, lakes/oceans supply us with seafood.
- **Terrestrial:** ecosystems: medicines, fibres, rubber and dyes.
- **Forestry**: largest industries and employers.
- Regulate and maintain important abiotic and biotic features of environment.
- Cycle water, oxygen, and nutrients.
- Help protect us from physical threats.
- Plant communities protect the soil from wind and water erosion.
- Ecosystems act as sponges.
- Absorb water and slowly release it into the groundwater and surface water (reduces erosion and protects against flooding, filters the water).
- Protect land from storms along coasts where wave damage erodes the shoreline.
- Mangroves
#### Monetary Value of Ecosystem Services
- Very difficult to put a dollar value to it.
- Dollar value of cleaning the air/water, moderating climate and providing paper fibre, medicines and other products is HIGH.
- Ranges into the trillions of dollars/year (maybe 60 trillion?).
- Provides valuable services that are free and renewable.
### Successions
- Natural ecosystems are in a state of equilibrium (their biotic and abiotic features remain relatively constant over time).
- Equilibrium is established when abiotic conditions are stable.
- Photosynthesis and cellular respiration are balanced.
- Populations are healthy and stable.
- Small ecosystems are in a constant state of change.
- Forest fire or disease outbreak can cause short-term changes on a local level.
- Types
- #### Primary
- on newly epxposed ground, such asa following a volcanic eruption.
- #### Secondary
- in a partially distrubed ecosystem, such as following a forest fire.
- Human caused disturbances.
- Results in gradual changes as plants, animals, fungi and micro organisms become established in an area.
- In both terrestrial and aquatic ecosystems.
#### Benefits of Succession
- Provides a mechanism by which ecosystems maintain their long term sustainability.
- Allows ecosystems to recover from natural or human caused disturbances.
- Offers hope (New Orleans, New Jersey, Florida, Puerto Rico).
- Time needed is very long.
- Original cause of disturbance must be eliminated.
- Not all disturbances can be repaired.
- Disturbances can be repaired through human actions that support the natural processes of succession.
### Human Impacts To Species
- Increase rate of **EXTINCT** species.
- HIPPO
- Habitat destruction + fragmentation (divide lands into pieces)
- Invasive species.
- Pollution + pesticides.
- Over Population
- Overexploitation (overfishing, overhunting etc).
#### Status of Endangered Life in Canda
- Do not have to be driven to extinction for there to be ecological consequences.
- Population falls below critical level = ecological niche can no longer be filled.
- Consequences for abiotic and biotic features.
- **Extirpated**: no longer exists in a specific area.
- **Endangered**: facing imminent extirpation or extinction.
- **Threatened**: likely to become endangered if factors reducing its survival are not changed.
- **Special Concern**: may become threatened or endangered because of a combination of factors.
### Eutrophication
#### The Problem
- Lack or no dissolved oxygen, produces toxic algae, ugly.
- Colour, smell, and water treatment problems.
- Animal waste = nutrients.
- Examples
- Parks in china.
- Hanoi, vietnam.
#### Solutions
- Water cycling, through the use of watermills or waterfalls.
- People removing decomposing plants, collecting waste/garabage.
- Aerator.
### Resource Management
#### Forestry Practices
- Canadian economy rely heavily on forests.
- Difficult to find a balance between commerical demands and ecological integrity.
- Forest certifications are given to people that use safe practices
### Wildlife Management
- **`Stewardship`** (sustainable harvesting) must always be remembered!
- Inuit people had small populations and knew how their enviornments worked, European settlers changed all of that!