John Lennon Quote Essay

John Lennon Quote Essay John Lennon Quote Essay Word Count: 250+ According to John Lennon, â€Å" Life is what happens while you are making other plans†. Little do you all know this is true because what goes on while you are sitting there minding your own business? Life does not stop when you stop, life moves on and never stays the same. There may be some people out there who really do think that the world revolves around them, but little do they know its all just a lie. And honestly you never know what you miss because every second that you close the door, a million more open for you to explore. Quite frankly life will never again be the same as we know it because every mille-second, something changes whether it be a person whom you think you have known all your life or a person that you might meet in your mere future. The changes will add up quickly, and no matter how hard you try nothing can ever stay the same. You never know something so dramatic may change in an instant or it could take some time. For instance transfe rring high schools last November was a big leap for me, I can not tell you enough how hard it was to get used to not being around the people I grew up with. Although, now I have friends here that I can count on to have my back yet I wills always have friends from my previous school that will always be there too. I never knew how difficult things were until I was the one making the big sacrifice and leaving all I had ever known behind me. I never would have thought about moving or not graduating with all

How to Calculate Normality of a Solution

How to Calculate Normality of a Solution The normality of a solution is the gram equivalent weight of a solute per liter of solution. It may also be called the equivalent concentration.  It is indicated using the symbol N, eq/L, or meq/L ( 0.001 N) for units of concentration. For example, the concentration of a hydrochloric acid solution might be expressed as 0.1 N HCl. A gram equivalent weight or equivalent is a measure of the reactive capacity of a given chemical species (ion, molecule, etc.). The equivalent value is determined using the molecular weight and valence of the chemical species. Normality is the only concentration unit that is reaction dependent. Here are examples of how to calculate the normality of a solution. Key Takeaways Normality is a unit of concentration of a chemical solution expressed as gram equivalent weight of solute per liter of solution. A defined equivalence factor must be used to express concentration.Common units of normality include N, eq/L, or meq/L.Normality is the only unit of chemical concentration that depends on the chemical reaction being studied.Normality is not the most common unit of concentration, nor is its use appropriate for all chemical solutions. Typical situations when you might use normality include acid-base chemistry, redox reactions, or precipitation reactions. For most other situations, molarity or molality are better options for units. Normality Example #1 The easiest way to find normality is from molarity. All you need to know are how many mole of ions dissociate. For example, a 1 M sulfuric acid (H2SO4) is 2 N for acid-base reactions because each mole of sulfuric acid provides 2 moles of H ions. 1 M sulfuric acid is 1 N for sulfate precipitation since 1 mole of sulfuric acid provides 1 mole of sulfate ions. Normality Example #2 36.5 grams of hydrochloric acid (HCl) is a 1 N (one normal) solution of HCl. A normal is one gram equivalent of a solute per liter of solution. Since hydrochloric acid is a strong acid that dissociates completely in water, a 1 N solution of HCl would also be 1 N for H or Cl- ions for acid-base reactions. Normality Example #3 Find the normality of 0.321 g sodium carbonate in a 250 mL solution. To solve this problem, you need to know the formula for sodium carbonate. Once you realize there are two sodium ions per carbonate ion, the problem is simple: N 0.321 g Na2CO3  x (1 mol/105.99 g) x (2 eq/1 mol)N 0.1886 eq/0.2500 LN 0.0755 N Normality Example #4 Find the percent acid (eq wt 173.8) if 20.07 mL of 0.1100 N base is required to neutralize 0.721 g of a sample. This is essentially a matter of being able to cancel out units to obtain the final result. Remember, if given a value in milliliters (mL), its necessary to convert it to liters (L). The only tricky concept is realizing the acid and base equivalence factors will be in a 1:1 ratio. 20.07 mL x (1 L/1000 mL) x (0.1100 eq base/1 L) x (1 eq acid/1 eq base) x (173.8 g/1 eq) 0.3837 g acid When to Use Normality There are specific circumstances when its preferable to use normality rather than molarity or other unit of concentration of a chemical solution. Normality is used in acid-base chemistry to describe the concentration of hydronium (H3O) and hydroxide (OH-). In this situation, 1/feq is an integer.The equivalence factor or normality is used in precipitation reactions to indicate the number of ions that will precipitate. Here, 1/feq is once again and integer value.In redox reactions, the equivalence factor indicates how many electrons can be donated or accepted by an oxidizing or reducing agent. For redox reactions, 1/feq may be a fraction. Considerations Using Normality Normality is not an appropriate unit of concentration in all situations. First, it requires a defined equivalence factor. Second, the normality is not a set value for a chemical solution. Its value can change according to the chemical reaction being examined. For example, a solution of CaCl2 that is 2 N with respect to the chloride (Cl-) ion would only be 1 N with respect to the magnesium (Mg2) ion. Reference The use of the equivalence concept. IUPAC (archived).