Add Donor Formula with airSlate SignNow

Add donor formula

I have a semiconductor and what I have done is I've added dopants atoms to it so I've added it's a nd number of donors and I've also added in a number of acceptors so now how many number of electrons and holes do I have in my semiconductor so let's see what happens if I add a donor so if I add a donor and that donor atom ionizes so it it gives away an extra electron that it had to the lattice and it leaves behind a positively charged donor atom if there's no data - similarly a acceptor atom if it I know this it accepts electron from the lattice so it leaves a way of a cancer it leaves a positively positively charged hole in the lattice and also it generates a negatively charged acceptor atom which is which is not mobile and which is fixed so how do I find the number of number of electrons and holes in my semiconductor so let's let's start with you know something which is which seems like reasonable so let me write down you know what can I expect so the first thing I can expect is what I call as charge neutrality so that is if I'm adding adding donors and acceptors to my semiconductor these donors and acceptors are essentially neutral species they if they give away an electron they also leave away a positively charged positively charged donor or similarly this acceptor if it generates the whole it also leaves away a and negatively charged acceptor atom and the semi conductor if it was intrinsic what if I had not added any dopant atom this was also neutral so if I add ad donor or acceptor it's I'm hoping you know hit it remains neutral so what I can draw it as a condition for charge neutrality so I can say that the total positive charged I have is equal to the total negative charge I have so let's see what what's the total total positive charge I can have so the total positive charge I can have is that I can have holes and I can if I add donor atoms and they ionize so this they leave behind this positively charged oprah donor atom so this is also adds to my positively positive charge and that what is the total number of negative charge I have so if i have electrons they will each electron will add one negative charge so if i have n electrons i have n negatively charged number of negative charges similarly if my acceptor atom ionizes it will leave behind a negatively charged negatively charged atom in the lattice so this is my total amount of negative charges and what I'll further assume is that I have what I had further assume as I assume complete ionization of G's complete ionization of these of these atom and what that mean is that I'll assume that if I'm adding donor atoms if I'm adding if I'm adding any number of donors all of them will ionize and they'll produce nd plus number of nd plus number of positively charged atoms and you know equivalent number of electrons similarly I'll assume complete ionization of my acceptor atoms as well so I can rewrite this rewrite this condition and what I'll assume is that nd plus is equivalent to nd similarly what I'll assume is that an a-minus is equal to na so I can rewrite this equation and what I say is P plus and D is equal to n plus and so this should have been you should write my a better so this is my this is my this is my a which was looking like a D so so what's the other condition I can write so I can use this big big law that we derived in the derived in the last of you know previously in one of the videos that is the law of mass action and we saw this this law of mass action which is a very important law which says that the product of my product of my electrons and holes it remains constant and is equivalent to the square of the intrinsic carrier density in my semiconductor so now if I if I need to solve for n NP I have to of equations so this is my equation number 1 and this is my equation number 2 so I have two variables and I have two equations so let's you know it's it's it's looked like no it's a binomial equation so i can submit all four n first let me find out how many number of electron life so I'll replace for P in this equation and I'll replace I'll take P express it in in in the form of number of electrons and then then replace it in this equation so I have this equation which says P plus nd is equal to n plus na so I can say I can subtract nd from both sides I can subtract nd from both sides and I'm left with P is equal to plus n a minus and D so now I can do is take this value of P and substitute as an it into this equation so it becomes n times n plus n capital and a minus Capital and D is equal to NI square so now this is a quadratic equation in terms of n so let me collect all the term which has n square which is this n multiplied by this end plus all the terms which have n which is this n a minus nd so this coefficient is capital na - and D dines and and then I have the constant term which is minus ni square which is minus ni square so now this is a quadratic equation so it has that form ax squared plus BX plus C equal to 0 so the solution of this solution for this is n equal to minus B which in this case is in minus of n a minus and D plus minus b square minus 4ac which in this case is in a minus nd square and minus times 4 is 1 and C is minus ni square so it becomes plus 4 ni square and whole thing another square root and divide it by 2 so you know let's let's rewrite it in a little bit more little more coherent way so I can instead of writing minus na minus nd by 2 I can write nd minus n a by 2 and then I can take this 2 inside this square root so it becomes a it becomes a 4 and I can you know further rewrite this as plus minus so I can I'm trying to generate similar looking terms inside and outside nd minus na square plus ni square now we know that the total number of number of number I can have this positive turn and I can have this negative term and if I look at this negative term this is bigger than what's out here and I know that the total number of electrons cannot be you're definitely negative otherwise you know that doesn't make any sense so this negative term will be negative term will be ruled out of this equation so that the final formula that I get for my number electrons is equal to nd minus n a by 2 plus nd minus n a square of that plus ni square and I can do the same exercise for the number of holes and you know you can repeat that and you know follow the same steps but all that happens is that instead of nd the position of this nd and na is replaced otherwise the formula and otherwise that the formula looks pretty much the same so number of holes I have is this plus in a minus in d square plus ni square and you can further see that if I multiply this equation multiplied there is these two these two terms I further get NP equal to NI square so that's you know that's another another kind of checkpoint that these formulas are are correct so I get these you know these these formulas for the number of number of electrons and holes I have but these are still you know these are still not very easy to comprehend so let me first simplify this further so I can simplify this further by assuming that I can simplify this further for a few cases so I can assume that then we assume that the number of donors minus the number of acceptors is much larger than the intrinsic carrier density so let's say maybe I'm adding maybe I'm adding 10 to power 15 donors and I'm only adding 10 to power 12 except toys in my intrinsic carrier density for a semiconductor like Silicon is 10 to power 10 so in that case how many number of electrons do I get so I get a term of nd minus na by 2 from here and then I can ignore this term so I get another nd minus na by 2 term from here so overall the total number of Tron's I get is essentially equal to nd minus n a and what is the number of holes I have so the number of holes I have I can calculate by using the last mass action and I can say the number of holes I have is equal to NI squared divided by nd minus na and this is going to be much larger than ni square because nd minus na is much greater than n I so have a overall n type doped semiconductor and for that I can simply write my number of electrons and holes by using this formula now I can further simplify this also if I have the opposite condition so if I have in a minus nd is much greater than a nice if that is the case I have a much more number of acceptor atoms and now subtraction of this concentration of acceptor and donors is greater than greater than ni and in that case in that case I can write down the number of holes I have so I can write down the number of holes I have using this formula so I'll get na minus nu by 2 term from here and inside this term this term the nd minus this term would be much greater than much greater than this term so I'll get another na minus nd by 2 from there so the total number of holes I have is I will get as na minus nd and correspondingly I can write that the number of electrons I have is equal to NI square divided by the concentration of holes which is na minus nd so I can I can simplify this formula further for the case when I have nd minus na greater than ni or I have an a minus nd greater than ni