Playing with Electron Configurations

I upgraded the table part of the Electron Configuration Interactive I used in the app I made for Practicing Writing out Electron Configurations. It’s now more interactive and embeddable.

Click on the green cell (in the 3d subshell) to start adding electrons. Clicking on the previous cell will remove electrons.

The full documentation is here.

Limiting Chemical Reactions

Figuring out the limiting reactant in a chemical reaction integrates many of the basic chemistry concepts including: unit conversions from moles to mass and vice versa; the meaning of chemical formulas; and understanding the stoichiometry of chemical reactions. So, since we’ll need a number of these, I wrote a python program to help me design the questions (and figure out the answers).

Program examples come zipped because they require the program file and the elements_database.py library:

Baking Powder and Vinegar (Common Molecules)

Limiting_component-Common.py: This has the baking powder and vinegar reaction limited by 5 g of baking soda. It’s nice because it uses a few pre-defined “common molecules” (which are defined in the elements_database.py library.

You enter the reactants and products and the program checks if the reaction is balanced, then calculates the moles and masses based on the limiting component, and finally double checks to make sure the reaction is mass balanced.

Limiting_component-Common.py

from elements_database import *
import sys

print "LIMITING REACTANT PROGRAM"
print 
print "  Determines the needed mass and moles of reactants and products if reaction is limited by one of the components"

c = common_molecules()

'''Create Reaction'''
rxn = reaction()
# Add reactants (and products)
#   Use rxn.add_reactant(molecule[, stoichiometry])
#       molecule: from molecule class in elements_database
#       stoichiometry: integer number
rxn.add_reactant(c.baking_soda,1)
rxn.add_reactant(c.hydrochloric_acid,1)
rxn.add_product(c.carbon_dioxide)
rxn.add_product(c.water, 1)
rxn.add_product(c.salt)

'''Print out the reaction'''
print 
print "Chemical Formula"
print "  " + rxn.print_reaction()
print 

'''Check if reaction is balanced'''
balanced = rxn.check_for_balance(printout=True)

'''Calculate limits of reaction'''
if balanced:
    rxn.limited_by_mass(c.baking_soda, 5, printout=True)

Outputs results in the Results table (using scientific notation):

LIMITING REACTANT PROGRAM

  Determines the needed mass and moles of reactants and products if reaction is limited by one of the components

Chemical Formula
  NaHCO3 + HCl  --> CO2 + H2O + NaCl 

Check for balance
 --------------------------------------------- 
| Element | Reactants | Products | Difference |
 --------------------------------------------- 
|   Na    |    1      |    -1    |     0      |
|   H     |    2      |    -2    |     0      |
|   C     |    1      |    -1    |     0      |
|   O     |    3      |    -3    |     0      |
|   Cl    |    1      |    -1    |     0      |
 --------------------------------------------- 
Balance is:  True

Given: Limiting component is 5 g of NaHCO3.
  Molar mass = 84.00676928
  Moles of NaHCO3 = 0.0595190130849

 Results
   ------------------------------------------------------------------ 
  | Molecule | Stoich.*| Molar Mass (g) | Moles req. |    Mass (g)   |
   ------------------------------------------------------------------ 
  |NaHCO3    |    1    |    84.0068     |  5.952e-02 |   5.000e+00   |
  |HCl       |    1    |    36.4602     |  5.952e-02 |   2.170e+00   |
  |CO2       |    -1   |    44.0096     |  5.952e-02 |   2.619e+00   |
  |H2O       |    -1   |    18.0156     |  5.952e-02 |   1.072e+00   |
  |NaCl      |    -1   |    58.4418     |  5.952e-02 |   3.478e+00   |
   ------------------------------------------------------------------ 
 * negative stoichiometry means the component is a product

  Final Check: Confirm Mass balance: 
     Reactants:    7.1701 g 
     Products:    -7.1701 g 
     --------------------------
          =      0.0000 g 
     --------------------------

General Example

If not using the common molecules database, you need to define the components in the reaction as molecules yourself. This example reacts magnesium sulfate and sodium hydroxide, and limits the reaction with 20 g of magnesium sulfate.

Limiting_component-General.zip

The main file is:

Chem_Exam-limiting.py

from elements_database import *
import sys

print "LIMITING REACTANT PROGRAM"
print 
print "  Determines the needed mass and moles of reactants and products if reaction is limited by one of the components"

# create reaction

rxn2 = reaction()
# Add reactants (and products)
#   Use rxn.add_reactant(molecule[, stoichiometry])
#       molecule: from molecule class in elements_database
#       stoichiometry: integer number
rxn2.add_reactant(molecule("Mg:1,S:1,O:4"))
rxn2.add_reactant(molecule("Na:1,O:1,H:1"), 2)
rxn2.add_product(molecule("Mg:1,O:2,H:2"))
rxn2.add_product(molecule("Na:2,S:1,O:4"))

'''Print out the reaction'''
print 
print "Chemical Formula"
print "  " + rxn2.print_reaction()
print 

'''Check if reaction is balanced'''
balanced = rxn2.check_for_balance(printout=True)

'''Calculate limits of reaction'''
if balanced:
    rxn2.limited_by_mass(molecule("Mg:1,S:1,O:4"), 20, True)

# print out masses
print "Masses Involved in Reaction"
print "  Reactants:"
for i in rxn2.reactants:
    #print "rxn", i
    print "    {m}: {g} g".format(m=i.molecule.print_formula().ljust(10), g=i.mass)
print "  Products:"
for i in rxn2.products:
    #print "rxn", i
    print "    {m}: {g} g".format(m=i.molecule.print_formula().ljust(10), g=-i.mass)

This program is slightly different from the common molecules example in that, at the end, it prints out masses calculated in a more easily readable format in addition to the other data.

Masses Involved in Reaction
  Reactants:
    MgSO4     : 20.0 g
    NaOH      : 13.2919931774 g
  Products:
    MgO2H2    : 9.69066512026 g
    Na2SO4    : 23.6013280571 g

When I have some time I’ll convert this to JavaScript like the molecular mass example.