Experiment #7
Date performed: March 4, 2014
Presented by: Sam Tabah(I.D.#1402433) & Giuliano Amato(I.D.#1328425)
General Chemistry 202 Nya-05 (00006)
Vanier college
Part A.
Objective: The objective of this lab was to determine the standard heat formation (∆H°F) of MgO, using a calorimeter and determining the enthalpy of two reactions. Applying Hess’ law we were able to determine the standard heat formation of MgO.
Introduction
Energy exchanged in a chemical reaction can either be in the form of heat or light. If light is involved a glow is seen, if heat is involved the temperature of the system will change(lab manual page 35). The amount of heat exchanged under constant pressure is called the enthalpy change, this can either be endothermic or exothermic. Endothermic if heat is absorbed by the reaction (positive sign), and exothermic if heat is released by the reaction (negative sign). If a reaction is reversed, the sign of ΔH is also reversed. The heat change that results from the formation of one mole of a compound from its elements in the regular states is known as its standard heat of formation (∆°f). The specific heat of the solution is the amount of heat required to raise the temperature of 1 gram of the solution by 1°C.
To find the enthalpy change of a reaction using a calorimeter we added the Mg and MgO solids to two HCl solutions in two separate Styrofoam cups, and using a thermometer and taking note of the temperature change every 30 seconds for 7.5 minutes we then plotted this on a graph. Extrapolating the points from the final temperature after the 7.5 minutes, through where the heat of the reaction begins cooling, we were able to determine the maximum heat that would have been achieved if their was no heat loss in the reaction. Using this and the initial temperature we found ∆T for both of the reactions. We then calculated our masses of solutions by weighing precisely the amount of Mg and MgO used, as well as the masses of the HCl solutions. The specific heat of solution was given which was 4.184 J/g°C. Using the formula q=(∆T)(Specific heat of solution)(Mass of solution) we were able to determine the amount of heat released by the reactions. Knowing our limiting reagents this let us calculate the enthalpy changes of each reaction in Kj/mol. The enthalpy change for reaction 3 was given. Applying Hess’ law using all three equations we were able to determine the heat of formation (∆°f) of MgO in Kj/mol.
Experimental
Refer to lab manual pages 38-39, also refer to attached pre-lab.
Data/Results
Reaction of Mg + 2H Mg +H2
Initial temp: 19°C
Extrapolated temp: 60.8°C
Temperature difference (∆T): 41.8°C
Mass of Styrofoam cup: 3.533g
Mass of Styrofoam cup and solution: 64.194g
Mass of HCl solution: 60.661g
Quantity of heat released: 10.71680 Kj
Mass of Mg used: 0.616g
Amount of Mg used: MM: Mg = 24.31g/mol (.616g Mg)(1mol/24.31g Mg) =.0253 mols of Mg used.
This chart is of reaction temperature, over seven and a half minutes, of the equation Mg(s) + 2H(Aq) Mg(Aq) + H2. We added Mg to our 2H+ and noted down the temperature change at every 30 seconds. We then extrapolated the values back from our final temperature through the point in where the cooling started. This made it possible for us to determine ∆T for the reaction.
∆T= Our initial temperature was 19°C and the extrapolated temperature was 60.8°C. Text. –Tint. = 41.8°C(∆T)
Mass of solution = We added the mass of the HCl solution with the mass of Mg used: 60.661g+0.616g =61.277g of solution
Specific heat capacity was given as 4.184 J/g°C because the solution is mostly water.
Quantity of heat released = ∆T × Mass of solution × Specific heat of solution: q= (61.277g)(4.184J/g°C)(41.8°C) = 10,716.80J 10,716.80 ÷ 1000 = 10.71680 Kj = q solution qrxn= −qsoln qrxn= −10.71680 Kj
∆Hrxn = qrxn/mol of solid used
∆Hrxn= −10.71680Kj/.0253mols =−424 Kj/mol
Reaction of MgO + 2H Mg + H2O
Initial temp: 19°C
Extrapolated temp: 31.45°C
Temperature difference: 12.45°C
Mass of Styrofoam cup: 3.546g
Mass of Styrofoam cup and solution: 63.990g
Mass of HCl: 60.444g
Quantity of heat released: 3.20119Kj
Mass of MgO used: 1.010g
Amount of MgO used: MM MgO: 24.305 + 16.00= 40.305 g/mol
(1.010g MgO)(1 mol/40.305g)= 0.025 mols of MgO used
This chart has the same legend as the previous one but it is for the reaction MgO(s) + 2H(Aq) Mg(Aq) + H20(L). Again, extrapolating the values back made it possible to find maximum temperature reached and determine ∆T.
By using the same methods of calculations seen above we obtain the heat released for this reaction.
Quantity of heat released = ∆T × Mass of solution × Specific heat of solution: q= (61.45g)(4.184J/g°C)(12.45°C) = 3,201.19J 3,201.19J÷ 1000 = 3.20119 Kj = q solution qrxn= −qsoln qrxn= −3.20119Kj
∆Hrxn = qrxn/mol of solid used
∆Hrxn= −3.20119Kj/0.025mols =−128 Kj/mol
Hess’ Law
Using Hess’ law we can use all three reactions to determine the heat of formation of magnesium oxide. Equation 1 releases 424 Kj of energy , 2 releases 128 Kj, and 3 releases 285 Kj . Because they are releasing this energy during the reaction they are exothermic and therefore are negative vaues. We use Hess’ law and combine these three reactions calculating them algebraically, for equation 2 we need to reverse the reaction for it to fit in our equation to use Hess’ law.
To perform the reaction Mg(s) + ½02 MgO we need to use Hess’ law because if not it would give off an uncontrollable flame which would make it impossible to use a calorimeter. Some errors that may have occurred in our data would be; from the transferring of the Mg or MgO to the Styrofoam cup, we may have spilled some, from the heat loss to the surroundings seeing as they were only Styrofoam cups that weren’t covered, and also because of our human reflex that may have caused small error in temperature readings.
1.) Mg(s) + 2H(aq) Mg(aq) +H2 ∆H= −424 Kj
2.) MgO(s) + 2H(aq) Mg(aq) + H20 ∆H= −128 Kj
3.) H2(g) + ½O2(g) H2O(L) ∆H= −285.5 Kj
Mg(s) + ½O2(g) MgO(s) ∆H=???
1) Mg(s) + 2H(aq) Mg(aq) +H2 ∆H= −424 Kj
Reversed:2) Mg(aq) +H2O(L) MgO + 2H ∆H= 128 Kj 3) H2(g) + ½O2(g) H2O(L) ∆H= −285.5 Kj
Mg(s) + ½O2(g) MgO(s) ∆H= −581.5 Kj
Conclusion After finding the ∆H of equations 1 and 2 we were able to apply Hess’ law to determine the standard heat of formation of MgO. The ∆H of reaction 1 was −424 Kj, for 2 ∆H= −128 Kj and for 3 (given value) ∆H= −285.5 Kj. After applying Hess’ law we found the the ∆H°F for the reaction Mg(s) + ½02 MgO was −582 Kj/mol. This tells us that in the formation of MgO there is 582 Kj of energy released.
Part B.
∆H.lattice > ∆H.hydration = endothermic process The process of dissolving NH4Cl is endothermic. In order for the crystal solid to dissociate into ions, energy must be absorbed, in this case the lattice energy was overcome and the solid separated into ions and no solid was left. Knowing that the solid completely dissolved in the solution we are able to determine that the lattice energy is greater then the hydration energy meaning that the reaction is endothermic. After the dissociation of the NH4Cl the temperature of the water dropped from 16°C to 9°C this is because the ions are cooling down the water in an exothermic process, known as hydration energy.
An example of a exothermic process is the burning of a candle, the candle is giving off heat to its surroundings. A good example of an endothermic process is photosynthesis. Plants absorb energy from the sun allowing them to produce food and grow.
Part C.
Energy exchanged in a chemical reaction can either be in the form of heat or light. If light is involved a glow is seen, if heat is involved the temperature of the system will change (lab manual page 35).
During this experiment we observed that when the clear liquid luminol is mixed with potassium ferricyanide a white blue glow of light is created from the mixture. The energy transformation in this experiment creates this glow, it is created from the decay of a high energy intermediate to a lower energy product, the excess energy is seen visually as photons and produce the blue glow.
When matter is changed there is always a transfer of energy. Whether it be in the form of heat or pressure. For matter to change states the particles either have to get “excited” or “calmed”. The more you heat particles the more excited they get. This will produce a gas if heated high enough. The more the particles are cooled the more they slow down and eventually if cooled enough arrive at a solid state.
You May Also Find These Documents Helpful
-
Initial and Final Temperature of Three Different Consecutive Trials of Magnesium and Hydrochloric Acid Reactions…
- 2480 Words
- 10 Pages
Good Essays -
From the results recorded it was identified that activity A and C had exothermic reactions, whilst activity B had an endothermic reaction. Each of the activities had initially begun with 23.4/8/9oC, however, within one minute of adding the 2nd reactants, the results began showing, as seen from the graph. Activity A and C had risen in temperature, with A gaining 4oC and in total of 2 minutes having the temperature of 27.9oC along with C increasing by 2.2oC and within 2 minutes of the experiment having the temperature of 26oC. Activity B however was the anomaly in the test, as the temperature went lower, by 1.9oC as within 2 minutes, the Ammonium Chloride and water had the temperature of 21oC. Furthermore the line graph shows Activity A and C rising to its highest peak, although it eventually reduces. Activity A for example, was rising until it reached 27.9oC and it continuously decreased, until the 10 minute mark had reached having the final temperature similar to the initial temperature. A similar thing occurred to Activity C however, as its highest peak was 26oC (2 minutes in the test), and the final temperature having a 0.1oC difference from the initial temperature.…
- 500 Words
- 2 Pages
Good Essays -
A chemical reaction often indicated by a transfer of energy measured in heat. By measuring this heat transfer in a constant pressurized environment, the enthalpy of the reaction can be used to infer certain information about a specific reactions reactants and products. The transfer of heat from outside sources in would be described as an endothermic reaction. Contrary, when a reaction releases heat out to its surroundings it is described as an exothermic reaction.…
- 633 Words
- 3 Pages
Better Essays -
4. There are three modes of molecular motion associated with energy. Identify the mode(s) of molecular motion available to helium gas (He) and compare to those of nitrogen gas (N2). Which gas has the higher molar heat capacity? Explain.…
- 898 Words
- 4 Pages
Good Essays -
Under conditions of constant pressure the heat absorbed or released is termed enthalpy (or "heat content"). We do not measure enthalpy directly, rather we are concerned about the heat added or lost by the system, which is the change in enthalpy (or ΔH The quantity of heat gained or lost by a system, ΔH, is dependent upon, the mass, m, of the system: the more massive an object the more heat needed to raise its temperature, the change in temperature, (ΔT): the larger the temperature change in a system the more heat exchanged, and the nature of the substance(s) making up the system. The last quantity is defined by the heat capacity of the system. For a given substance, the specific heat capacity is defined as the quantity of heat needed to raise 1 gram of the substance by 1 degree Celcius. Specific heat capacity has units of joules per degree Celcius per gram, J.g-1.ºC-1.The three quantities combine to give the quantity of heat gained, or lost, by a system:…
- 2451 Words
- 10 Pages
Good Essays -
Analyzing thermodynamic properties of a reaction: Bomb calorimeters are being used to measure the output of heat energy of a system which includes, the enthalpy changes of a system meaning the enthalpy change of formation, combustion, neutralization and atomization. This careful analyzing of may reactions thermodynamic properties could result in convenience in the future as many future scientists utilize this information gathered readily.…
- 505 Words
- 3 Pages
Good Essays -
Calculate the heat of reaction assuming no heat is lost to the calorimeter. Use correct significant figures.…
- 895 Words
- 4 Pages
Powerful Essays -
The purpose of this lab was to confirm the chemical formula of magnesium oxide by comparing the masses of pure magnesium solid prior to any reaction and magnesium oxide solid after a reaction between all of the magnesium and oxygen from the air when heated from a Bunsen burner in a crucible. Using molar masses of both magnesium and oxygen, an expected percent composition, by mass, was found and compared to our experimental results.…
- 1886 Words
- 8 Pages
Better Essays -
The purpose of this lab is to determine the enthalpy of reaction for the burning of one mole of magnesium in oxygen. Although the reaction is exothermic, the ∆HRXN will be determined by using calorimetry and then using Hess’s Law to manipulate the data collected to yield the answer needed.…
- 580 Words
- 3 Pages
Satisfactory Essays -
Purpose: This lab taught procedures for determining heat of capacity of a calorimeter and measuring enthalpy of change for three reactions. It also enforced methods of analyzing data obtained through experimentation and calculating enthalpy. These procedures are used in the branch of thermodynamics known as thermochemistry which is the study of energy changes that accompany chemical reactions. Concepts from this lab can be used to determine the potential energy of a chemical reaction. Much of the energy people depend on comes from chemical reactions. For example, energy can be obtained by burning fuel, metabolizing of food or discharging a batter.…
- 2424 Words
- 10 Pages
Good Essays -
Abstract: The purpose of this lab was to see how magnesium reacts with oxygen. This reaction must be forced with heat. As magnesium changes to magnesium oxide the mass increased.…
- 347 Words
- 2 Pages
Good Essays -
Energy change, such as endothermic and exothermic reactions, production of a gas (fizzing or bubbling), a formation of a precipitate, or an unexpected color change.…
- 663 Words
- 3 Pages
Satisfactory Essays -
We were given KOH and KNO3 as our salts. We weighed the calorimeter and water then subtracted accordingly o get the mass of the calorimeter and that of the water. The lab instructed on the amounts of water and salt to be used. The initial temperature of the water in the KOH reaction was 22.8 degrees Celsius and the final temperature of the mixture determined from the graph was 37.0 degrees Celsius. The graph of the KOh showed it to be an exothermic salt and the KNO3 to be and endothermic salt because of the change in the temperature indicating either absorbing or giving off of heat by the salts. This the change in temperature of the solution of the KOH and water is + 28880 J and the heat change of the salt is 82.6 J. Thus the total heat change, in the reaction is -2960 J. To determine the DeltaHs (J/g salt), divide the totalt heat of change by the measure mass of the salt resulting in -590 J/g. The same process was followed for KNO3 but this solution had a -5.9 degree Celsius temperature change this producing a negative total heat change of water and the slat in the solution giving a +13000 J in the reaction. DeltaHs is then determines to be 250 J/g. The expected value of DeltaHs of KNO3 is +354 J/g and for KOH, -1026 J/g. The error for the KNO3 is -27.5% and for the KOH it is 42.5%. These errors are high but not uncommon for the experiment. They are caused because the salts are in a solid form and thus after the peak of temperature of solution is found, the remainder of the graph is flawed because salt is still in the process of dissolving. This dissolving still of the salts is giving off or absorbing heat thus making the extrapolated change in the temperature of solution to be small. The temperature of solution being too small results in the total heat change being too small, giving the DeltaHs value as in the case of KOH too high (not negative enough) and in the KNO3…
- 1355 Words
- 6 Pages
Powerful Essays -
While waiting on the water to boil, retrieve a piece of unknown metal to be identified and record its ID letter and its mass. Once the mass of the unknown metal is recorded, put the metal into the boiling water. While waiting on the water and the metal to achieve the same thermal equilibrium, get a coffee cup and measure its mass. Then pour about 50mL of water into a coffee cup, measure the mass of the water and the coffee cup and then determine the mass of the water alone (mass of water and coffee cup – mass of coffee cup). Record the temperature of the boiling water on the hot plate with the metal and then record the temperature of the water in the coffee cup before adding the metal. Use the string attached to the metal to transfer the metal from the hot water bath to the calorimeter. Using a piece of cardboard to cover the top of the calorimeter, record the temperature of the water in the calorimeter. Repeat the experimental procedure three more…
- 1030 Words
- 5 Pages
Better Essays -
Calorimetry is the measurement of the quantity of heat exchanged during chemical reactions or physical changes. For example, if the energy from an exothermic chemical reaction is absorbed in a container of water, the change in temperature of the water provides a measure of the amount of heat added.…
- 490 Words
- 2 Pages
Satisfactory Essays