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Chemistry Lab is an event where participants must learn the year's selected aspects of chemistry and perform a lab or a set of labs regarding those topics.
Since this events rotates topics, each topic constitutes its own page. For topic-specific information, please see the topic rotation, as this page only contains general information that applies to all topics.
Chemistry Lab has been held every year in division C since 1987.
- 1 Topic Rotation
- 2 Description
- 3 General Chemistry
- 4 Event Strategy
- 5 Links
Chemistry Lab typically rotates between several topic area, with two topics at a time, and one topic rotating in/out each year.
As of 2019, the following materials are allowed:
- Category C Eye Protection (Required)
- Lab coat, closed-toed shoes, etc.—see rule 2.c for exact safety parameters (Required)
- 1 double-sided note sheet per team (sheet protectors and lamination allowed)
- 1 stand-alone, non-graphing, non-programmable calculator per student
- This section includes general chemistry knowledge that is applicable to most or all topics. For information on specific topics, see the section on Chemistry Lab Topics.
- Main article: Chem Lab/Periodicity
The periodic table of the elements organizes the known elements by properties.
They are numerically ordered by their atomic number, which is the number of protons in the nucleus of an atom. The elements are arranged so they are in columns with similar chemical properties. These columns are called groups. Rows are called periods, and display properties known as periodicity.
The Merriam-Webster dictionary defines stoichiometry as "a branch of chemistry that deals with the application of the laws of definite proportions and of the conservation of mass and energy to chemical activity". Stoichiometry deals with calculations about the masses (sometimes volumes) of reactants and products involved in a chemical reaction. It is a very mathematical part of chemistry. The most common stoichiometric problem will present you with a certain amount of a reactant and then ask how much of a product can be formed. For example, a problem might provide the equation 2A + 3B → 3C and ask, "given 25 grams of B and unlimited amount of A, how much C will be produced?" This is called a mass-mass problem. These problems can be solved in 4 simple steps.
- Make sure the chemical equation is correctly balanced.
- Using the molar mass of the given substance, convert the mass given in the problem to moles.
- Construct a molar proportion (two molar ratios set equal to each other) following the guidelines set out in other files. Use it to convert to moles of the unknown.
- Using the molar mass of the unknown substance, convert the moles just calculated to mass.
Other forms of stoichiometric problems are finding the limiting reactant and finding the percentage composition. You can find out more about these in the links below.
The process is very similar when given gases (using the ideal gas law), solutions (using molarity) or molecules (using Avogadro's number)
Stoichiometry can be approached in precisely the same way one would approach dimensional analysis. And, when in doubt, convert to moles.
There are five main types of reactions (single displacement, double displacement, decomposition, synthesis, and combustion). Each of them has a specific form that they take. If you encounter problems dealing with reactions on the test, knowing the basic types can be very helpful because then you will be more likely to see the pattern and understand how to complete the reaction.
Also called single replacement reactions. Single displacement reactions are oxidation-reduction reactions in which an element and a compound react to form another element and a compound. This reaction takes on the form
- A + BC → AC + B
So the lone elemental reactant, A, forms a compound with C, forcing B out to become an element itself. In order for this to occur, A and B are usually metals that form a cation when compounded with C.
The direction in which the reaction proceeds depends on each element's position in the activity series. A has to be more likely to oxidize than B, because otherwise B will just simple stay in solution and A will remain untouched.
Double displacement reactions are similar to single replacement, but they are usually not oxidation-reduction reactions. Instead of just one element being traded, double displacement reactions have two similarly formed compounds reacting to form other compounds.
- AB + CD → AD + CB
This type of reaction is especially important in aqueous solutions, since most precipitation reactions are double displacement reactions. Precipitation occurs when AB and CD are both soluble in water, and when put together, either AD or BC is an insoluble compound and thus precipitates out of the solution. For more information about solubility, see Chem Lab/Aqueous Solutions.
In decomposition, a compound decomposes into its constituent parts.
- AB → A + B
This type of reaction usually occurs when the compound AB is unstable, since breaking a chemical bond requires energy. Since it takes energy to break a bond, the vast majority of decomposition reactions are endothermic.
Synthesis reactions are the opposite of decomposition reactions. These reactions have two elements or components bonding together to form a larger compound.
- A + B → AB
Since this reaction forms a bond, it is exothermic.
Combustion reactions are reduction-oxidation reactions (also called redox reactions) involving oxygen or another oxidizing agent. Combustion reactions are also exothermic reactions since they give off heat. The most common combustion reactions form carbon dioxide, water, and energy. For example, here is the combustion reaction for methane:
- CH4 + 2O2 → CO2 + 2H2O + energy
Combustion can also occur with nitrogen instead of carbon. There is also combustion with only hydrogen and oxygen, and in this case only water forms as product.
- 2H2 + O2 → 2H2O + energy
Since combustion reactions are among the most common exothermic reactions, it is a good idea to know the combustion reactions of several important compounds, or at least know how to go about finding it quickly. Since all of them have a similar form, you can guess what the products will be, which will make it easier. For example, for the combustion of a hydrocarbon in oxygen, the two products will be water and carbon dioxide, since the oxygen attaches itself to both carbon and hydrogen parts.
Oxidation and Reduction
- Main article: Chem Lab/Electrochemistry
Oxidation and reduction reactions are those where reactants see a net gain or loss of electrons. Typically, losses and gains occur in pairs, with the electrons lost in one chemical species being gained by another. To remember which is which, it may be helpful to use the acronym OIL RIG, or Oxidation is Loss, Reduction is Gain. This is a simple way of remembering that whatever is oxidized loses electrons and whatever is reduced gains electrons. The phrase LEO the lion says GER also works, which refers to "Lose Electrons-Oxidation; Gain Electrons-Reduction."
- Main article: Chem Lab/Aqueous Solutions
An aqueous solution is a solution where the solute is dissolved in water.
- Main article: Chem Lab/Equilibrium
Equilibrium refers to properties of chemical solutions which respond to changes in concentration (as well as other factors such as temperature).
- Main article: Chem Lab/Thermodynamics
- See also, the page for the separate event Thermodynamics.
Thermodynamics is the study of the interaction of energy transfer and systems of matter.
Acids and Bases
- Main article: Chem Lab/Acids and Bases
Acids and bases are two complementary classes of substances displaying unique properties, most notably the production of H+ ions (for acids) and OH- ions (for bases) in solution.
- Main article: Chem Lab/Titration Race
A titration is a controlled chemical procedure that involves adding a known amount of one substance, typically in solution (the titrant) to another solution, typically until neutralization. This is frequently done with acids and bases.
- Main article: Chem Lab/Gas Laws
Gas Laws refer to the chemical and thermodynamic laws governing the physical behavior of and reactions involving gases.
Like all events, Chem Lab requires a strategy for you to be able to do your best.
- It is very helpful if one or both partners has taken AP Chemistry, since some of the topics covered in this event are advanced and not covered in normal high school chemistry classes.
- Try to split the work between you and your partner so that in studying, you can cover both topics.
- If you get a longer test, ask if you can remove the staple and split the test, so that you can cover more of the test in less time.
- Try to arrange your team so that you have one person who is good at quickly performing labs and one person who is good at computations and writing. This should facilitate the labs.
- Make sure to work not just quickly, but efficiently, on the labs. Do them as quickly as you can, but if you end up with inaccurate results then going quickly didn't help you a whole lot. Also, do not take shortcuts unless you are absolutely, positively sure you can.
- Make sure you have all of your protective equipment, as you may be disqualified if you do not have it.
- Stoichiometry links
- Study for the AP Chem test
- Some Chemistry tests
- Solubility rules and evolved gases list for aqueous systems
- Chem lab video: oxidation/reduction
- Infinity Flat's Chem Notes 1
- Infinity Flat's Chem Notes 2
- Bay Area students' guide to Chemistry Lab