A Rap on Bonds

 

1.Now here’s a little story I've got to tell

2.about some bonds that I know so well

3.it started way back in history

4.with ionic, covalent and, what’s that, chemistry!

5.Electrostatic attractions named Ionic Bonds

6.caused by the attraction of a positively charged ions

7.and also ions that are, negatively charged.

8.The metal in an ionic bond loses an electron

9.and also one atom, the

10.non-metal gains an electron

11.Now let’s talk about covalent bonds

12. where the electrons are shared between the atoms.

13.Well enough about that, let’s get to the fact

14.That valence electrons have much to do with that.

 

15.Found in the outermost shell of an atom

16.exist what we call valence electrons

17.Ionic and covalent bonds differ in the extent

18.of electrons shared by atoms to form the bond that’s it.

19.There’s a difference to note

20.on what you should expect

21.on determining

22.what bond is happening.

23.When one atom draws electrons toward itself

24.better than the other, this is an ionic bond.

 

25.When the atoms are approximately equal

26.in their ability to draw electrons toward themselves

27.the atoms share the pair of electrons

28.more or less equally, and the bond is covalent.

29.I have much more to say about four more things

30.You think this story's over but it's ready to begin

 

31.Now one of those things is electronegativity

32.an ability to attract a bonding pair of electrons.

33.Electronegativity increases

34.across a period due to the fact that the number of charges on the nucleus increases.

35.Another thing is,

36.As you go down a group, electronegativity decreases

37.because the bonding pair of electrons is

38.distant from the attraction of the nucleus.

39.So, the next part is ionization energy

40.the energy needed to remove the outermost electron.

41.from a neutral atom in the gas phase.

42.It gets larger as it goes across a row of the periodic table

43.because the force of attraction between the nucleus

44.and an electron becomes larger as the number of protons

45.in the nucleus of the atom becomes larger.

46.It becomes larger as we go down a column

47.the electron being removed spends less of its time

48.near the nucleus of the atom,

49.therefore taking less energy to remove the electron from the atom.

50.Time to move on to the next part of the song.

51.Electron affinity amount of energy released

52.when an electron is added to a neutral atom

53.or molecule in gaseous state

54.to form a negative ion

55.Time to move on cause I'm running out of time

56.Atomic Radius is what’s next in line

57.it’s how we determine the size of an atom.

58.so the electrons are not held as tightly as you move down a group.

59.Therefore it increases and it decreases

60.as you move across the period from left to right

61.cause more protons in the nucleus has a stronger pull

62.That’s all I have to say, that concludes this rap.

Video

 

Sources:

Beastie Boys - Paul Revere

http://www.chemguide.co.uk/atoms/bonding/electroneg.html

http://chemed.chem.purdue.edu/genchem/topicreview/bp/ch7/ie_ea.html

The Mole Project

Avogadro's number is related to any mole substance because the number that Avogadro made was to convert particles into moles of any substance. The number is..... 6.022 x 10^23.
 

 

Converting a recipe from moles to standard cooking measurements

This table is used to adjust the following recipes:       

                                   Moles                 Grams

Flour                            2.66               319.47664 

baking soda                0.0335             2.814201

salt                              0.036              2.103948

butter                          1.084              236.53422

sugar                           0.44                150.61068

brown sugar                0.31                106.11207

eggs                            0.624              99.947952

vanilla                         0.062               9.433238

chocolate chips            2.82                338.69328

Recipe of ANZAC Biscuits:

In this recipe, 0.63 moles of water has been reduced to 0.45 moles of water.
 .63
------ = 1.4%
 .45
So by using the percent yield I am going to calculate the changes that need to be made.

The adjusted recipe would be:
Flour: 1.9 moles
Rolled oats: 1.26 moles
Brown sugar: 1.26 moles
shredded coconut: 1.06 moles
Almonds: 0.68 moles
Cranberries: 0.69 moles
Butter: 0.85 moles
Honey: 0.64 moles
water: 0.45 moles

Oatmeal Chocolate Cookies:

In this recipe, 0.72 moles of Rolled Oats has been reduced to 0.50 moles of Rolled Oats.

 0.72

-------- = 1.44%

 0.50

So by using the percent yield I am going to calculate the changes that need to be made.

The adjusted recipe would be:

Flour: 2.96 moles

Rolled Oats: 0.5 moles

Butter: 2.625 moles

Eggs: 1.3 moles

Walnuts: 0.53 moles

Sugar: 1.74 moles

Brown Sugar: 1.91 moles

Chocolate Chips: 2.64 moles

Baking Soda: 0.17 moles

Vanilla: 0.14 moles

Chocolate Chip Cookies:

In this recipe, 3.8 moles of Chocolate Chips has been reduced to 2.5 moles of Chocolate Chips

The ratio is 1.52

Flour:  4.8
Coco Powder: .697
Butter: 2.48
Eggs: .5
Walnut: .5
Sugar: 2.20
Brown Soda: .164
Vanilla: .131

Drop Sugar Cookies with Walnuts:

In this recipe, 5.33 moles of flour has been reduced to 4.33 moles of flour.

The ratio is 1.23

Flour: 4.31
Butter: 1.91
Eggs: .39
Walnuts: .78
Sugar: 3.40
Baking Soda: .203
Vanilla: .252

1. You want to 6 make grilled cheese sandwiches (use the equation below, Bd = bread and Ch = Cheese) and you have 13 slices of bread and 5 slices of cheese. How may grilled cheese sandwich can you make? And what is the limiting reagent?
                                                            2Bd + Ch→Bd2Ch
You have 13 slices of bread
You have 5 slices of cheese
                                                                               13
You need 2 slices of bread to make 1 sandwich, so ----  is 6.5. You can make 6 sandwiches with the bread.
                                                                                2
                                                                             5
You need 1slice of cheese to make 1sandwich, so --- is 5.You can only make 5sandwiches with the cheese.
                                                                             1
The limiting reactant is cheese.


2. You are having some friends over for dinner you want to make 8 cheese burgers, you have 8 hamburger patties, 12 bums, 7 slices of cheese, 18 slices of tomato, 16 pieces of lettuce and 9 slices of onion. Use the equation below (where buns = B, hamburger patty = H, cheese = Ch, tomatoes = T lettuce = L and onion = O) to determine how many cheese burgers you can make (what’s your theoretical yield?) and what the limiting reagent is? Hint you may need to balance the equation first.
                                               B+ H+ Ch+ 2T+ 2L+O → BHChT2L2O

Considering  cheese is the limiting reagent and there are only 7 slices of  them you can only make 7 sandwiches.

3. Balance the chemical equations below. Find the limiting reagent and the theoretical yield if there is one gram of each reagent.

 

 

Sources:

Ms. Del Bosque 

Boyle's Law

Robert Boyle is what the Boyle's Law is named after.

In 1655, Boyle moved to Oxford where he made Robert Hooke his assistant and together they constructed the most famous piece of experimental equipment related with Boyle, the vacuum chamber or air-pump.

This law appears in an appendix written in 1662 to his work New Experiments Physio-Mechanical, Touching the Spring of the Air and its Effects in 1660 (Hunter).

This law describes the relationship between pressure and volume of gases, so if the pressure is doubled then the volume will be halved.
 

Some examples of the relationship between pressure and volume are:
-The bubbles exhaled by a scuba diver grow as the approach the surface of the ocean. (The pressure exerted by the weight of the water decreases with depth, so the volume of the bubbles increases as they rise.) 
-Deep sea fish die when brought to the surface. (The pressure decreases as the fish are brought to the surface, so the volume of gases in their bodies increases, and pops bladders, cells, and membranes). 

 This is a graph of the relationship between volume and pressure.

This law determines that for the same amount of a gas at constant temperature, P*V=constant.

P = pressure (measured in atm)
V = volume (measured in Liters)
 This equation is derived from the Ideal Gas Law equation P * V = n * R * T
                                                                                              ^      ^           ^
                                                                                 pressure x volume = constant

Example problem:
A gas has a pressure of 1.01 atm and occupies a volume of 6.4 L. If the gas is compressed to a volume of 1.05 L, what will its pressure be, assuming constant temperature? Answer in units of atm.
                                  Explanation:
V1 = 6.4 L                                                                                          V1 = 1.05 L

P2 = 1.01 atm                                                                                     P2 = ?

                                 Applying Boyle's Law,

P1V1 = P2V2

         P1 V1          (1.01 atm) (6.4 L)

P2 =  ------   =    --------------------

          V2                    1.05 L

     = 6.15619 atm

 Sample problems:
1. The initial pressure was 3 atm while the volume was 2 L. What would the volume be if  the pressure rose to 6 atm?

2. The initial pressure was 380 atm while the volume was 6 L. What would the volume be if  the pressure rose to 760 atm?

3.  The initial pressure was 5.2 atm while the volume was 0.555 L. What would the pressure be if  the volume rose to 2.14 atm?

4. The initial volume and pressure of the gas is 2L, 3 atm. Assuming the temperature and moles of gas is constant, what is the pressure if the volume is reduced to 1.25 L?

5. Four liters of carbon dioxide have a pressure of 1.5 atmospheres. If the original pressure was .9 atmospheres, what was the original volume?


Answer Key:
1. V2 = 1L
2. V2 = 3L
3. P2 = 1.349 atm
4. P2 = 4.8 atm
5. V₁= 6.666... L

sources:

pic: http://www.sil.si.edu/digitalcollections/hst/scientific-identity/CF/by_name_display_results.cfm?scientist=Boyle,%20Robert

http://www.bbc.co.uk/history/historic_figures/boyle_robert.shtml

campus.udayton.edu/~hume/Boyle/boyle.htm‎
http://antoine.frostburg.edu/chem/senese/101/gases/faq/everyday-gas-laws.shtml
graph: www.citycollegiate.com

Created by: Celesta Monsivaiz

Solutions and Solubility

Solutions and Solubility

1. Solutions

2.  Molarity

3. Molality formula

4. Dilutions formula

5. Solubility

Solutions

What is a solution?

A solution is a homogeneous mixture in which one substance is dissolved in another substance.

For example:

 In this example the substance being dissolved is salt and it is being dissolved in water.

There are three factors that affect the rate of solutions (how fast they dissolve) and affect solubility:

1. Stirring 

2. Particle size (the smaller the better, it covers more surface area)

3. Thermal energy (heat) 

Temperature (thermal energy) is different for gases. Unlike liquid and solids, gases become less soluble as the temperature increases.

Molarity

Molarity represents the number of moles of solute per liter of solution.

          moles

M =  -------

          liters

i. How many grams of CaCl2 are in 350 mL of 2.0 M CaCl2 solution?

First you have to figure out what the moles are by using the formula for molarity (above).

So the equation would be moles= Molarity x Liters

plug in the numbers and solve:

                          m = 2 x 0.35 (you convert 350 ml to liters, so you get 0.35 L)

                          m = 0.7

Now that you know moles you can solve for grams by using the formula g = moles x mm (molar mass).

To find molar mass of CaCl2 use the periodic table. It will end up being 110.984.

Plug in the numbers and solve:

                          g = 0.7 x 110.984

                          g = 77.689                That's the answer!

ii.What is the molarity of 2.5 L of solution that contains 1.0 mol MgCl2?

To solve for molarity plug the numbers into the equation and solve:

                          M = 1.0 / 2.5 L

                          M = 0.4 M           That's the answer!

iii. How many moles of solute are present in 400 mL of 2.0 M KNO3?

To solve for moles use the molarity formula to solve for moles, so the equation would be m = M x L.

Plug in the numbers and solve:

                          m = 2 x 0.4 (convert 400 ml to liters, so that it's 0.4 L)

                          m = 0.8 m               That's the answer!

Molality formula 

Molality represents the number of moles of solute per kilogram of solvent.

           moles

m =  ----------

        kilograms

i. Calculate the molality of a solution that has 1.5 moles added to 675 g of solvent.

To solve for molality use the formula above to solve.

Plug in the numbers and solve:

                 m = 1.5 / 0.675 (convert 675 g to kg by dividing by 1,000 to get 0.675 kg)

                 m =  2.22 m             That's the answer!

Dilutions formula

The formula is M1 x V1 = M2 x V2

i. If you dilute 70.0 mL of 5.0 M NaCl to make a 350.0 mL of solution, what is the molarity 

of the dilute solution?

Use the formula above to solve:

                      M1 x V1 = M2 x V2

                      5.0 x 70 = M x 350

                      350 = M x 350                               Divide 350 on both sides

                      1 = M                                           That's the answer!

ii.If you had 40.0 mL of a 3.00 M hydrochloric acid solution and you wanted to dilute it to

2.00 M, what would be the new volume?

Use the formula above to solve:

                       M1 x V1 = M2 x V2

                       3 x 40 = 2 x V

                       120 = 2 x V                               Divide 2 on both sides

                       60 = V                                      That's the answer!

Solubility 

The solubility rules are:

i. How much KNO3 will dissolve in 50 mL of water that is at 30 °C? ___180_g_______ 

ii. If you stir 20 grams of KNO3 in 100 mL of water that is at 50°C, will all of it dissolve? 

___yes____ 

iii. A solution that contains 120 grams of MgSO4 in 100 mL of water at 80°C would 

be saturated, unsaturated, or supersaturated? _____supersaturated__________

Chemical Reactions

Chemical Reactions

Goes over:

1. Balancing chemical equations

2. Writing skeleton equations

3. Redox reaction

4. Classify reactions

5. Predict the products

Balancing chemical equations

Law conservation of mass states that matter can be changed from one form into another, mixtures can be separated or made, and pure substances can be decomposed, but the total amount of mass remains constant.

To balance equations there has to be the same number of atoms for each element on both sides of the equation.

1)  _SiI4  + _ Mg  → _ Si +  _MgI2

            This is not a balanced equation because if you write down the atoms for each element on both sides of the equation it will be unequal:

Reactants                    Products
Si _1_                            Si _1_
I _4_                              I _2_
Mg _1_                          Mg _1_

         Iodine doesn't have the same number of atoms, so to balance this equation place coefficients in front of the terms to change the number of atoms.
1)  _SiI4  +  _2_Mg  →  _ Si  +  _2_MgI2

       To see if it's balance write down the number of atoms for each element on both sides of the equation:

Reactants.                 Products
Si _1_.                         Si _1_
I _4_.                           I _4_    (the coefficient 2 is multiplied with I2 to produce 4)

Mg _2_                        M_2_   (the coefficient 2 multiplies with an invisible 1 to get 2)

Now it is balanced!

2)  _ (NH4)2O  +  _Cr(BrO3)3  →  _Cr2O3  +  _ NH4BrO3

Let's see if it's balanced:

Reactants                    Products
N_2_                          N_1_
H_8_                          H_4_
O_10_                        O_6_
Cr_1_                         Cr_2_
Br_3_                         Br_1_
*Now when there are parenthesis the subscript is distributed to the elements inside the parenthesis.

Nitrogen, Hydrogen, Oxygen, Chromium, and Bromine are not balanced, let's balance them.
2)  _3_ (NH4)2O  +  _2_Cr(BrO3)3  →  _Cr2O3  +  _6_ NH4BrO3

More examples of unbalanced equations being balanced using coefficients
3)  _K3PO4  +  _HCl  →  _KCl  +  _H3PO4
_K3PO4  +  _3_HCl  →  _3_KCl  +  _H3PO4

4)  _C3H6  +  _ O2  →  _CO2  +  _H2O
_2_C3H6  +  _9_ O2  →  _6_CO2  +  _6_H2O

5)  _Ca(ClO3)2  → _CaCl2  +  _O2
     _Ca(ClO3)2  → _CaCl2  +  _3_O2

Writing skeleton equations

To write a skeleton equation just write the symbols that represent the names of the substance and put subscripts that are necessary. You don't have to balance skeleton equations unless asked to do so.

1)  potassium iodide  +  lead (II) nitrate  → potassium nitrate  +  lead (II) iodide
     KI  +  Pb(NO3)2 → KNO3  +  PbI2
Balance it:
     _2_KI  + _Pb(NO3)2 → _2_KNO3  +  PbI2

2)  mercury (II) oxide →  mercury +  oxygen
      HgO →  Hg +  O
It's already balanced because each element has the same number of atoms on both sides.

3)  calcium +  aluminum chloride →  calcium chloride +  aluminum
      Ca  +  AlCl3 →  CaCl2  +  Al
Balance it:
      _3_Ca  +  _2_AlCl3 →  _3_CaCl2  +  _2_Al

4)  mercury (I) nitrate +  sodium carbonate →  sodium nitrate +  mercury (I) carbonate
      HgNO3  +  Na4C →  NaNO3  +  Hg4C
Balance it:
      _4_HgNO3  +  _Na4C →  _4_NaNO3 + Hg4C

5)  potassium bromide +  aluminum nitrate →  potassium nitrate +  aluminum bromide
      KBr  +  Al(NO3)3 →  KNO3 +  AlBr3
Balance it:
      _3_KBr +  Al(NO3)3 →  _3_KNO3  +  AlBr3

Redox reaction

A redox reaction (oxidation-reduction reactions) is a reaction in which electrons are transferred. To identify what has been oxidized and reduced in a redox reaction look for a change in the oxidation number of an element. In oxidation the oxidation number increases. In reduction the oxidation number decreases. 

How to find the oxidation number of the bold element:

1)  I2  Since it is an element by itself it has an oxidation of 0.
2)  Cr2O7^-2  There is always an element to start with when trying to figure out the oxidation number. This is the order from which you start with oxygen, hydrogen, group 1A, 2A, Ag, Zn, Cd, Al, and group 7A.
In this equation start with oxygen. Oxygen has a oxidation number of -2 then multiply it with its subscript 7. Then equal this to -2 (its charge), the missing number to make this equation equal -2 is -12. Divide -12 with 2 (the subscript of Cr) to give you -6, the oxidation number of Cr.
3)  HMnO4  Oxygen has an oxidation number of -2, multiply it with its subscript 4. Since the middle element is the unknown oxidation number, take the oxidation number of the left element (hydrogen has oxidation number of +1) and add it to the equation. The equal is to 0 (if it doesn't have a charge it is always equal to 0), the missing number is -7, the oxidation number of Mn.

               1)   2 Rb  +  3 F2  -->   2 RbF
oxidation:     0             0              +1  -1  
This is a redox reaction because there was a change of oxidation. Since Rb oxidation number increased it is oxidized. Since F decreased it's reduced.

               2)   2 K  +  1 Zn(NO3)2  -->  1 Zn  +  2 KNO3
oxidation:     0         -8    6  -2                0        +1 +5 -2
This is a redox reaction because there was a change of oxidation. Since Zn and K oxidation number increased it's oxidized. Since N decreased it's reduced.

               3)  1 CaCO3   -->  1 CaO  +  1 CO2
oxidation:  +2 +4 -2             +2 -2       +4 -2
This is not redox because all oxidation numbers stayed the same.


 Classify reactions 

Synthesis: two elements as reactants to make one product. Think of it like eating a sandwich then drinking a smoothie and it mixes together in your stomach in the end.

2Ca + O2 --> 2CaO

Decomposition: one reactant breaks apart into its elements. Think of it like a peanut, you break it apart to get to separate things.

2H2O2 --> 2H2O + O2

Single replacement: characterized by having an element and a compound as reactants and the products are another element and another compound. Think of it as a giraffe, the one with the longer neck takes the place to breed then with one with a shorter neck.

Fe + CuSO4 --> Cu + FeSO4 

Combustion: a hydrocarbon reacts with oxygen to produce carbon dioxide and water. Think of it like dough and cows to make cookies and milk (no avoiding it).

CH4 + 2O2 --> CO2 + 2H2O

Double replacement: two compounds as reactants and the products are two other compounds. Think of it like its Halloween and you and your friend switch candy.

NaCl + KBr --> NaBr + KCl

                      1)AlCl3(aq)  +  Na2SO4(aq)  -->  Al2(SO4)3(s)  +  NaCl(aq)
When balanced:
                  _2_AlCl3(aq) + _3_Na2SO4(aq) --> Al2(SO4)3(s) + _6_NaCl(aq)
Since Cl was with Al then ended up with Na and SO4 was with Na then ended up with Al it is a double replacement.

                     2)  Zn(s)  +   S8(s)  -->   ZnS(s)
When balanced:   _8_Zn(s) + S8(s) --> _8_ZnS(s)
Since the reactants Zn and S come together to form one compound as a product it is showing synthesis.

                     3)  Al2S3(s)  -->  Al(s)  +  S8(s)
When balanced:   _8_Al2S3(s) --> _16_Al(s) + _3_S8(s)
Since the compound AlS separated to produce Al and S it showed decomposition.

                     4)  H2SO4(aq)  +  Fe(s)  -->  H2(g)  +  FeSO4(aq)
It's already balanced, atoms of each element on either side of the equation has the same number of atoms.
In the equation Fe takes the place of H creating FeSO4 because it is more active, this shows single replacement.

                    5)  C12H22O11(g)  +  O2(g)  -->  CO2(g)  +  H2O(g)
When balanced: C12H22O11(g) + _12_O2(g) --> _12_CO2(g) + _11_H2O(g)
In the equation the products are CO2 and H2O. When the reactants contain C, H and O and the products are carbon dioxide and water, combustion has occurred.
               

Predict the products

A net ionic equation includes only the components of the reaction that undergo a change.
To write a net ionic equation:
1) write a molecular equation (you do not need to balance it yet)
2) break apart into ions all strong acids, strong bases,  and soluble salts (unless they are present as a solid, liquid, or gas).
3) make sure to leave all solids, liquids, and gases together
4) Remove all spectator ions (= ions that occur unchanged in any way from the reactant side to the product side)

Sources
http://www.chem.wisc.edu/deptfiles/genchem/sstutorial/Text1/Tx14/tx14
http://chemistry.tutorvista.com/inorganic-chemistry/redox-potential.html?view=simple
http://chemistry-group4.blogspot.com/2010/03/decomposition
http://citadel.sjfc.edu/students/jas05321/e-port/Reactions%20Study%20Guide.html