TSC 4064 Waste management – Math, Science, & Technology

chapter summaries

Chapter1

I can define a contaminant as an agent that causes changes in the physical, chemical or biological properties of an environment or an organism.
I can describe bioaccumulation as being the accumulation, in an organism, of a contaminant originating in its environment or food
I can explain bioaccumulation in trophic levels (bio amplification)
I can define bioconcentration as a special case of bioaccumulation where an organism accumulates a contaminant while in direct contact with its habitat (sources other than its food)
I can define the toxicity threshold of a substance as the minimum quantity of a substance that can produce a considerable harmful effect on an organism
I can describe factors that influence the toxicity of a contaminant (e.g. concentration, characteristics of the environment in which it is released, nature of the organisms with which it comes into contact, duration of exposure)
I can describe the concept of ecological footprint
I can explain the usefulness of the concept of ecological footprint
I can describe the treatments used to decontaminate wastewater
I can describe method of biodegrading pollutants (eg. phytoremediation)

I can name contaminants found in the soil
I can define the concept of soil depletion
I can explain how human activity contributes to soil depletion
I can define the buffering capacity of the soil as its ability to limit pH variations
I can explain the advantages of a soil with good buffering capacity
I can name contaminants found in the air
I can describe the effect of prevailing winds on the dispersion of pollutants in a given region
I can apply the direction of the prevailing winds in Quebec to how contaminants are spread.
I can describe the changes related to the circulation of phosphorus (e.g. erosion of rocks, degradation of fertilizers)
I can name contaminants found in the hydrosphere.
I can describe the catchment area and how contaminants are spread from the lithosphere into the hydrosphere.
I can describe the consequences of eutrophication.
I can describe how human activities speed up eutrophication.

I can locate the groups and periods in the periodic table
I can describe he common characteristics of a family (eg. number of valence electrons, chemical reactivity)
I can associate the number of electronic shells in an element with the number of its period
I can represent an atom’s electron configuration using the simplified notation
I can represent an atom of an element using the simplified atomic model (which must include numbers of protons and neutrons in the nucleus)
I can associate the atomic number of an element with the number of protons it has
I can describe the concept of relative atomic mass (don’t mix it up with the average atomic mass)
I can calculate the average atomic mass (don’t mix it up with the relative atomic mass)
I can define an isotope as the atom of an element where the nucleus contains a different number of neutrons giving the atom a different atomic mass.
I can define a radioactive isotope as an isotope that has an unstable nucleus
I can determine the number of valence electrons in an element
I can define “nuclear stability” as the cohesion of the nucleus resulting from the fact that an atom has an optimal number of neutrons
I can represent the decay if I was given the half-life of an isotope
I can define “radioactivity” as the emission of particles or energy by the nuclei of atoms following nuclear transformations

I can apply nomenclature and notation rules to name a molecule or write the molecular formula for binary compounds
I can represent atoms using Lewis notation
I can represent binary compound using he Lewis notation.
I can recognize common polyatomic ions (e.g. NH4+, OH-, NO3-, CO3-2, SO4-2, PO4-3) by their name, their formula or their composition
I can define a covalent bond as a bond involving the sharing of electron
I can represent a covalent bond schematically
I can identify molecules containing covalent bonds (e.g. N2, CO2)
I can define an ionic bond as a bond involving the gain or loss of an electron
I can represent an ionic bond schematically
I can identify molecules containing ionic bonds (e.g. NaCl, NH4OH)
I can associate the presence of an ionic bond with an electrolytic substance
I can associate the strength of an electrolyte with its degree of dissociation, qualitatively speaking.
I can represent the presence of dissociation schematically (like ones on page 191).
I can represent the lack of dissociation schematically (like ones on page 191)
I can distinguish between nuclear fusion and nuclear fission
I can associate the use of radioactivity with technological applications (e.g. radiation therapy, carbon dating)

Part 1 of 2

Part 2 of 2

I can define the concept of mole
I can express a quantity of matter in moles
I can express a number of particles using Avogadro’s number
I can describe the periodicity of certain properties of the elements (e.g. chemical reactivity, atomic radius, electronegativity)
I can define the concept of solubility
I can determine the concentration of an aqueous solution (mol/L)
I can represent a precipitation reaction using the particle model
I can prepare a solution with a specific concentration from solid
I can prepare a solution with a specific concentration from a stock solution

I can recognize an acid-base neutralization reaction based on its equation
I can determine the molecular formula of the salt formed during an acid-base neutralization reaction
I can use the pH value to describe the acidity/basicity of a solution
I can associate oxidation reactions with chemical equations in which oxygen gas is one of the reagents
I can associate known chemical reactions with decomposition or synthesis reactions (e.g. respiration, photosynthesis, combustion, digestion)
I can balance a chemical equation
I can determine the quantity of reagents or products using stoichiometric calculations

I can select the right equipment for the right function.
*ex. NEVER measure liquid using a beaker.
I can use the equipment correctly and safely.
I can follow the lab safety protocol. Tie up long hair, closed toe shoes, no food and drink, etc.
Given the scenario & the goal of an experiment:
- I can explain the scientific principles
- I can formulate a hypothesis related to the context of the scenario and justifies it
- I can design an experimental procedure by choosing the best measuring instruments
- I can conduct the experiment accordingly to my procedure safely
- I can record all relevant data and observations
- I can analyze the result and produces an appropriate analysis
- I can verify the hypothesis
- I can assess the validity of the measurements and of the result
- I can propose a solution to the problem in the scenario