Arrhenius Equation Activation Energy and Rate Constant K Explained

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Arrhenius Equation Activation Energy and Rate Constant K Explained

النص الكامل للفيديو

in this video we're going to go over the AR ranous equation where or the rate constant is equal to * raised to the / RT so what do these variables mean is the frequency factor is equal to times where is the Collision frequency and is the steric factor but for the most part for typical chemical kinetics question you really don't have to worry about or or EA is the activation energy that's how much energy you need to get the reaction started we're going to talk lot about that now is the energy constant and it's equal to 8.3145 and the units are Jewels per mole per Kelvin so therefore temperature is measured in kelvin you don't want to plug in the Celsius temperature in this equation the activation energy has the units Jews per mole it has to match with the units of now we need to understand the relationship between temperature and and and activation energy but before we do that you need to know how plays role in the rate law expression let's say if we have this rate law expression rate is equal to * is this first order reaction second order or is it zero order reaction what would you say now the exponent of is one so it's first order reaction which means that that if you double the concentration of reactant the rate of the reaction will double if you quadruple the concentration of the rate will quadruple so anytime you increase the concentration of reactant if it's first order or second order the rate will increase now if it's zero order reaction if you increase the concentration of that reactant the rate will not increase if it's zero order because let's say if you doubled it two to the0 power is one now if you double or if you increase the rate constant what's going to happen to the rate of the reaction will it increase or decrease if you increase the rate constant the rate of the reaction will go up now as you mentioned from the our heus equation depends on the activation energy which is EA and it depends on the temperature so if you can increase the temperature the rate constant will go up however if you decrease the activation energy the rate constant will also go up now typically when you increase the numerator the value of the whole fraction goes up but since it's on the exponent and sits there's negative sign it's kind of opposite to that usual Trend so it turns out when you decrease the activation energy the rate of the reaction goes up because goes up now let's draw potential energy diagram so here we have the reactants the products and this is the transition state also known as the activated complex the activation energy or at least the forward activation energy is the difference between the energy of the reactants and the activated complex the reverse activation energy is the difference between the activated complex and the energy of the products Delta the enthropy of the reaction is the products minus the reactants now what's going to happen if we add catalyst to this reaction what would catalyst do now you know Catalyst speeds up reaction but how exactly does it do that well what catalyst does it lowers the activation energy and it does so by providing the reaction an alternative pathway another way to get to the products and so that's how it lowers the activation energy by the way that reaction is it exothermic or endothermic anytime the products have less energy than the reactants they're low in energy it's an exothermic reaction now anytime you add catalyst the activation energy decreases when the activation energy decreases the rate con goes up and whenever goes up the rate of the reaction goes up as well when you increase the temperature the rate constant goes up and therefore the rate of the reaction will go up as well now if you increase the concentration of reactant if it's first order or second order and if it's not zero order then will stay the same is not affected by the concentration however the rate will increase if you increase the concentration of the reactant because the rate depends on and concentration of if it's first or second order reaction so if you increase the concentration or if you raise the temperature or if you add catalyst you can increase the rate of the reaction so now let's say if we start from this equation the uranous equation we're going to do is we're going to take the natural log of both sides starting from this equation we're going to come up with few other equations where if you're solving problem it might be useful to know those equations so right now we're going to have the natural log of is equal to the natural log of * raised to the other stuff now property of natural logs can allow us to separate single log into two logs for example Ln * Ln or Ln * is equal to Ln plus Ln so this is going to be like and this is going to be like so we're going to separate it into two separate natural logs so on the right side we're going to have LNA plus Ln raised to the over RT now another property of logs is you're allowed to move the exponent to the front so this is equal to 2 natural log so let's take this exponent and let's move it to the front so right now we have Ln is equal to LNA and then it's going to be minus over RT * Ln the natural log of is one so that's going to disappear and I'm going to switch these two so what we now have is natural log of is equal to EA over RT plus natural log of now I'm going to put this in slope intercept form so Ln is equal to over Time 1 / which is the same as EA over RT so this is like and this is plus it's in slope intercept form so and is the slope is negative EA over is the slope in the slope intercept form equation and one / is and the intercept which is is and so if we were to graph this function since LM represents we can put that on the AIS and 1 / represents so we can put that on the axis and the slope is negative so it should we should get straight line but going down and so therefore as 1 /t increases Ln decreases which means that decreases if and Goes Down goes down as well so if increases is the reciprocal of one/ that means Ln increases which mean goes up that's why we can say that as you increase the temperature the rate constant goes up and the rate of the reaction goes up as well now there's some other things to know about this equation and one of those things that you want to know is the slope we said that the slope which is is equal to over so if you ever need to find the activation energy the activation energy is * the slope so if you can find slope with this line by doing over one or you know by using equation Y2 - y1 is equal to X2 - X1 well you can calculate the activation energy but using that equation we're going to get another equation so here's what we're going to do let's replace with what it equals negative over so a/ is equal to this thing over run now is associated with Ln so it's going to be Ln K2 minus Ln K1 which is like Y2 minus y1 now is associated with 1 over so it's X2 is going to be 1 over T2 and X1 is going to be one over T1 now let's make some space now keep in mind Ln plus lnb was Ln * now turns out that Ln minus lnb is Ln / so using that fact Ln K2 minus Ln K1 is Ln K2 / K1 and if we so we have that and then 1 over T2 - 1 over T1 and if we multiply both sides by or negative these will cancel and so the activation energy is equal to times this whole equation now you might have seen this equation differently perhaps you've seen this equation like this Ln K2 over K1 is equal to EA / * 1 / T2 - 1/ T1 if you rearrange the equation you can get this equation this is like the standard form of the arous equation now if you need to solve for here's what we need to do let's say if you have Ln equals the base of Ln is ra to the is equal to so you can change it to this equation so using that fact this natural log has base so raised to everything on the right side is equal to to everything inside so that means that K2 over K1 is equal to raised to the EA over * 1 / T2 - 1/ T1 and if we multiply both sides by K1 this is how you could solve for the rate constant K2 so K2 is equal to K1 * raised to the netive EA / * 1 / T1 - 1/ T2 and make sure if you want to find rate constant the activation energy must be in Jews per mole don't plug in kles or you will get the answer wrong and keep in mind one KJ is th000 Jew so to go from kles to Jews multiply by th000 if you needs to go from Jews to kles divide by th000 so now you know how to find the rate constant and we use the other equation to find the activation energy so now sometimes you may need to find the temperature so let's see if we can rearrange the equation to get the temperature so let's start with this equation so in addition to the last form you also want to remember this form of the equation so let's multiply both sides sides by over EA so on the left side we're going to have Ln K2 over K1 and then it's going to be divided by EA on the right side well let's add the negative sign as well so negative so the negative will cancel will cancel and EA will cancel on the right side so we have 1 over T2 - 1 over T1 so what I'm going to do now is I'm going to take this term and move it to this side so one / T1 is negative on the right side but it's going to be positive on the left side if you add one over T1 to both sides so 1/ T1 minus Ln K2 divid K1 / EA is equal to 1 / T2 so therefore if we raise both sides to the Nega one 1 over T2 is going to flip to T2 so here's the other form of the equation if you need to calculate the temperature use this it's going to be 1 / T1 minus Ln K2 / K1 which is equal to well divided by EA and then raised to the minus one so that's what you need if you need to find the temperature let's put all the equations together and if you need to find rate constant use this equation it's going to be K1 * raised to the over and then 1 / T2 - 1 T1 and in order to find the activation energy we said that the activation energy is equal to Ln K2 / K1 there's negative sign in front of the and it's going to be divided by 1 1/ T2 - 1/ T1 so now you have the three forms of the equation so if you need to find the temperature use the first one if you need to find rate constant use the second and if you need to find the activation energy use the third and that is it for this video so thanks for watching and have great day
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