РефератыИностранный языкRaRates Of Reaction Essay Research Paper Rates

Rates Of Reaction Essay Research Paper Rates

Rates Of Reaction Essay, Research Paper


Rates of Reaction


BACKGROUND INFORMATION


What affects the rate of reaction? 1) The surface area of the magnesium. 2)


The temperature of the reaction. 3) Concentration of the hydrochloric acid. 4)


Presence of a catalyst.


In the experiment we use hydrochloric acid which reacts with the magnesium to


form magnesium chloride. The hydrogen ions give hydrochloric acid its acidic


properties, so that all solutions of hydrogen chloride and water have a sour


taste; corrode active metals, forming metal chlorides and hydrogen; turn litmus


red; neutralise alkalis; and react with salts of weak acids, forming chlorides


and the weak acids.


Magnesium, symbol Mg, silvery white metallic element that is relatively


unreactive. In group 2 (or IIa) of the periodic table, magnesium is one of the


alkaline earth metals. The atomic number of magnesium is 12.


Magnesium(s) + Hydrochloric acid(aq) = Magnesium Chloride(aq) + Hydrogen(g)


Mg + 2HCl= MgCl2


+ H2


In the reaction when the magnesium hits the acid when dropped in, it fisses and


then disappears giving of hydrogen as it fisses and it leaves behind a solution


of hydrogen chloride.


The activation energy of a particle is increased with heat. The particles


which have to have the activation energy are those particles which are moving,


in the case of magnesium and hydrochloric acid, it is the hydrochloric acid


particles which have to have the activation energy because they are the ones


that are moving and bombarding the magnesium particles to produce magnesium


chloride.


The rate at which all reactions happen are different. An example of a fast


reaction is an explosion, and an example of a slow reaction is rusting. In any


reaction, reactants chemical reactions? products.


We can measure reactions in two ways:


1) Continuous:- Start the experiment and watch it happen; you can use a


computer ?logging? system to monitor it. I.e. Watching a colour fade or


increase.


2) Discontinuous:- Do the experiments and take readings/ samples from the


experiment at different times, then analyse the readings/samples to see how many


reactants and products are used up/ produced.


Reaction rate = amount of reactant used up


time taken


If the amount used up is the same each time then the only thing that changes is


the time taken.


so, reaction rate ? 1


time taken.


rate = K


time taken.


Where K is the constant for the reaction.


For particles to react:-


a) They have to collide with each other. b) They need a certain amount of


energy to break down the bonds of the particles and form new ones. This energy


is called the ?Activation Energy? or Ea.


When we increase the temperature we give the particles more energy which:


1) Makes them move faster which In turn makes them collide with each other more


often.


2) Increases the average amount of energy particles have so more particles have


the ?activation energy?


Both of these changes make the rate of reaction go up so we see a decrease in


the amount of time taken for the reaction and an increase in time taken.


= 1


Time taken reflects the rate of reaction.


Because temperature has an effect on both the speeds at which the particles


react and the activation energy they have a greater effect on the rate of


reaction than other changes.


A change in concentration is a change in the number of particles in a given


volume.


If we increase the volume:-a) The particles are more crowded so they collide


more often.


b) Although the average amount of energy possessed by a particle does not


change, there are more particles with each amount of energy;- more particles


with the activation energy.


a) is a major effect which effects the rate, but b) is a minor effect which


effects the rate very slightly.


In this experiment we are not concerned with whether the reaction is


exothermic or endothermic because we are concerned with the activation energy


needed to start and continue the reaction.


PREDICTIONS


I predict that as we increase the temperature the rate of reaction will


increase.


If we increase the temperature by 100C the rate of reaction will double.


I predict that if we increase the concentration of the acid the reaction rate


will increase.


If the concentration of the acid doubles, the rate of the reaction will also


double.


LINKING PREDICTION TO THEORY


Reaction Rate and Temperature.


The collision theory describes how the rate of reaction increases as the


temperature increases. This theory states that as the temperature rises, more


energy is given to the particles so their speed increases, this increases the


number of collisions per unit of time. This increase in collisions increases


the rate of reaction.


The collision theory explains how the rate of reaction increases, but it does


not explain by how much or by how fast the rate increases. The Kinetic energy of


a particle is proportional to its absolute (Kelvin) temperature.


1/2 mv2? T


But the mass of the particles remains constant so we can eliminate that part of


the equation so;


? V2?T


Therefore we can fit this into a formula:


V21/V22 = T1/T2


If we substitute the temperature into the formula we can work out the average


speed of the formula:


V21/V22 = 310/300


V 1= ?310/300V 2


= ?1.033V2


= 1.016V2


However if we look at this it is only 1.016 times greater than the speed at


300K, in other words we can see that it has only increased by 1.6%.


The frequency of the collisions depends on the speed of the particles, this


simple collision theory only accounts for the 1.6% increase in the rate, but in


practice the reaction rate roughly doubles in a 10K rise, so this simple theory


cannot account for an 100% increase in the reaction rate.


During a chemical reaction the particles have to collide with enough energy to


first break the bonds and then to form the new bonds and the rearranged


electrons, so it is ?safe? to assume that some of the particles do not have


enough energy to react when they collide.


The minimum amount of energy that is needed to break down the bonds is called


the activation energy (EA). If the activation energy is high only a small


amount of particles will have enough energy to react so the reaction rate would


be very small, however, if the activation energy is very low the number of


particles with that amount of energy will be high so the reaction rate would be


higher. An example of a low EA would be in explosives when they need only a


small input of energy to start their exceedingly exothermic reactions.


In gases the energy of the particles is mainly kinetic, however in a solid of a


given mass this amount of energy is determined by their velocities.


This graph below shows how the energies of particles are distributed.


This graph is basically a histogram showing the number of particles with that


amount of energy. The area underneath the curve is proportional to the total


number of particles. The number of particles with > EA is proportional to the


total area underneath the curve.


The fraction of particles with > EA is given by the ratio:


Crosshatched area under the curve


total area under curve


Using the probability theory and the kinetic theory of gases, equations were


derived for the distribution of kinetic energy amongst particles. From these


equations the fractions of particles with an energy > EA J mole-1 is represented


by the equation: e -Ea/RT where R= the gas constant (8.3 J K-1 mole -1)


T= absolute temperature.


This suggests that at a given temperature, T,


The reaction rate ? e -Ea/RT


If we use k as the rate constant, as a measure of the reaction rate we can put


this into the equation also.


k? e -Ea/RT


? k= A e -Ea/RT


The last expression is called the Arrhenius equation because it was developed


by Srante Arrhenius in 1889. In this equation A can be determined by the total


numbers of collisions per unit time and the orientation of the molecules when


the collide, whilst e -Ea/RT is determined by the fraction of molecules with


sufficient amounts of energy to react.


Putting the probability theory and the kinetic theory together this now gives


us a statement which accounts for the 100% increase in the rate of reaction in a


10K rise.


Reaction Rate and Concentration.


The reaction rate increases when the concentration of the acid increases


because:


If you increase the concentration of the acid you are introducing more particles


into the reaction which will in turn produce a faster reaction because there


will be more collisions between the particles which is what increases the


reaction rate.


METHOD.


To get the amount of magnesium and the amount of hydrochloric acid to use in


the reaction, we have to use an excess of acid so that all of the magnesium


disappears.


Mg + 2HCl= MgCl2


+ H2


1 mole 2 moles1 mole


1 mole


So, we can say that one mole of magnesium reacts with 2 moles of hydrochloric


acid.


If we use 1 mole of magnesium and 2 moles of hydrochloric acid we will get a


huge amount of gas, too much for us to measure. We would get 24,000 cm3 of


hydrogen produced where we only want 100 cm3 of hydrogen produced. So to get


the formula for the amount of moles that we have to use the formula:


Moles = mass of sample 100=0.004 moles.


volume with 1 mole24,000


To get the maximum mass we can use:


Mass = moles x RAM.


= 0.004 x 24


= 0.0096g


So, this is the maximum amount of magnesium we can use. To the nearest 0.01 of


a gram = 0.01. This is the maximum amount of magnesium we can use.


Because the reaction reacts one mole of magnesium to two moles of hydrochloric


acid we have to make sure that even with the lowest concentration of acid we


still have an excess of acid.


The acid that we were using was 2 moles per dm2 which means that it is 0.2


moles per 100 cm2 of acid.


We need to make the reaction work to have double the amount of magnesium. The


maximum number of moles that the magnesium needed was 0.004 moles so the amount


of acid that we needed was double that so that equals 0.008 moles. As you can


see from the table below we have the acid in excess throughout the experiment.


Amount of HCl (cm3)Amount of H2O (cm3)Moles of acid. 1000


0.2 75250.15 50500.1 25750.05 The reason why we


used 0.01g of magnesium was because it was therefore easy to measure because


there was not too much, or too little. Therefore we had no problem with too


much gas.


Apparatus


This is the apparatus we used to measure the amount of H2 that was produced in


the reactions. We measured the amount of gas that was given of every two


seconds to get a good set of results. We used this apparatus with the reaction


changing the concentration, and then the temperature. To accurately measure the


amount of gas given of we used a pen and marked on the gas syringe at the time


intervals.


This is the apparatus we used to measure how long it took for the magnesium to


totally disappear. We used this apparatus in both of the experiments, changing


the temperature and the concentration of the acid to water.


Temperature.


When we did the experiment changing temperature we used both of the sets of


apparatus. To get a fair reaction we had to keep the amount of magnesium the


same and the concentration of the acid. In the experiment we used 0.1g of


magnesium and the concentration of the acid was 50cm3 of acid to 50cm3 of water.


This is because if we used 100cm3 of acid the reaction would be too fast. Still


we had an excess amount of acid, so one mole of magnesium can react with two


moles of HCl. Concentration.


When we did the reaction changing the concentration we changed the


concentration until we had just enough for 1 mole of magnesium to react with two


of HCl. To get a fair reaction we had to keep the amount of magnesium the same


and the temperature. We used 0.1g of magnesium.


RESULTS


Temperature


From this graph you can see that if we do increase the temperature the rate of


reaction also increases, but it does not show that if you increase the


temperature the rate of reaction doubles.


This graph shows that there is an increase in the rate of reaction as the


temperature increases. This shows a curve, mainly because our results were


inaccurate in a number of ways. This is because the concentration is changed


during the experiment because at high temperatures the acid around the magnesium


is diluted. If this experiment was accurate it would be also a curve but if you


made it into 1/time the result would be a straight line showing a clear


relationship.


Even though I changed it to 1/time it still does not show a clear relationship


because of the factors mentioned in the conclusion. Concentration


This graph shows an increase in the amount of gas given off and the speed at


which it is given off. This graph also does not show the rate increase, it just


shows how it increases with a change in concentration.


This graph shows that if you increase the concentration of the molar solution of


the acid the time in which the Mg takes to disappear becomes a lot slower. This


does not show the rate at which this happens, the graph of rate vs. conc. would


show a straight line.


This shows a straight line, thus proving that there is a relationship between


the time it takes the magnesium to disappear and the concentration of the acid.


If we take a gradient of it, it would show the rate at which the reaction was


happening.


Because this shows a straight line we can say that it is a second order


reaction.


This graph shows a nearly straight line which shows that there is a


relationship between the temperature and the rate of reaction, as the


gradient shows the rate of reaction. If you look at this graph it comes out to


show that if you increase the temperature by 100C the gradient of the line is


doubled. This shows that rate ? temp.


This graph shows that if you increase the molar concentration of the acid, you


will increase the rate of reaction. From this you can see from the gradient,


that if you double the molar concentration of the acid the rate of reaction will


double because the gradient is a way of showing the rate of reaction.


If you compare the quantitative observations to see which the faster reaction


is you can see that after 10 seconds: Temp.2102030


4050 Amount of H2 produced after 10s7.5162554


57 83


Even though there is a greater increase in the amount of H2 given off in each


of the different reactions you can see that there is a change in the amount


given off, but between the temperatures 30 and 400C there is not much of a


change, this could be because of our human error, there should be a big change


in the amount given off. Molar conc.0.511.52 Amount of H2


produced after 10s6256090 This table shows a nice


spread of results throughout the range of concentration. It clearly shows that


the reaction is at different stages so is therefore producing different amounts


of H2. This shows also that the reaction is affected by the concentration of


the acid.


CONCLUSIONS


I conclude that if you increase the temperature by 10oC the rate of reaction


would double, this is because of using the kinetic theory and the probability


theory. Even though our results did not accurately prove this, the theory that


backs it up is sufficient. the kinetic theory explains that if you provide the


particles with a greater amount of kinetic energy they will collide more often,


therefore there will be a greater amount of collisions per unit time. The


probability theory explains that there is only a number of particles within the


reaction with the amount of Ea to react, so if you increase the amount of


kinetic energy there will be more particles with that amount of Ea to react, so


this will also increase the reaction rate.


If you double the concentration of the acid the reaction rate would also double,


this is because there are more particles in the solution which would increase


the likelihood that they would hit the magnesium so the reaction rate would


increase. The graph gives us a good device to prove that if you double the


concentration the rate would also double. If you increase the number of


particles in the solution it is more likely that they will collide more often.


There should be more H2 given off if we compare it across the range of


temperatures because the reaction is going quicker and so more H2 is given off


in that amount of time.


There is more H2 given off if you compare it to the range of concentrations


that you are using, this shows that the reaction is at different stages and so


is therefore producing different amounts of H2.


Also our results were not accurate but this could be because of a number of


reasons.


There our many reasons why our results did not prove this point accurately. -


At high temperatures the acid around the magnesium starts to starts to dilute


quickly, so if you do not swirl the reaction the magnesium would be reacting


with the acid at a lower concentration which would alter the results. – Heating


the acid might allow H Cl to be given off, therefore also making the acid more


dilute which would also affect the results. – When the reaction takes place


bubbles of H2 are given off which might stay around the magnesium which


therefore reduces the surface area of the magnesium and so the acid can not


react properly with it so this affects the results.


To get more accurate results, we could have heated the acid to a lower


temperature to stop a large amount of H Cl being given off. The other main


thing that could have helped us to get more accurate results is we cold have


swirled the reaction throughout it to stop the diluting of the acid and the


bubbles of H2 being given off.


If I had time I could have done the reactions a few more times to get a better


set of results. This would have helped my graphs to show better readings.

Сохранить в соц. сетях:
Обсуждение:
comments powered by Disqus

Название реферата: Rates Of Reaction Essay Research Paper Rates

Слов:3448
Символов:21871
Размер:42.72 Кб.