 Now, I will I will move from there to simple temperature dependence of magnetism ok. So, you have a material let us say f electrons you have or d electrons you have whatever you have. You know at room temperature magnetic moment value is whatever x 2 let us say 2 or magnet whatever it is. You know there is a value the moment you are cooling it down for room temperature or from a high temperature to room temperature whatever it is the moment you are cooling it down those spin previously you are having now will get an opportunity to realign usually molecules means you can have different spin organized in a different fashion. Let us say you have 10 different domain 10 different metal centers those 10 different metal centers are having spin one up another down another up and shown it is a mixture of up and down. Let us say it is a mixture of up and down this is the particular temperature let us say this is room temperature or whatever temperature you want. Now, you cool it down you cool down the sample what will happen this you know randomly oriented spin will get some particular orientation it will try to freeze you will be able to freeze this spin more and more if you decrease the temperature you start with 1000 degree centigrade come to room temperature magnetic moment value will increase for the sample. This is the behavior you are expected to see for paramagnetic complex. So, random spin little bit organized further organized. Now, that is the kind of behavior you should expect for paramagnetic species sometime what happens is once spin of one molecule is influencing the spin of other molecule how it is let me give you an example here. Let us say this is a spin this is the d orbital of one atom or one metal center this is the d orbital of another metal center. Now, in absence of anything in between if there is no bridging between these two metal center this is spin up this is spin up half and half. So, total spin should be half plus half one, but in presence of a ligand or bridging species having two electrons what will happen these ligand will ligand spin will be down this is up this is down that there is a bond formation if this is down this is going to be up that will enforce this spin to be down to start with you have up spin for this up spin for that two centers up up since they are bridged by a second ligand something let us say oxide O 2 minus it has two unpaired electrons let us say you have copper 2 plus or copper 3 plus oxide copper copper 2 plus oxide copper 2 plus copper 2 plus is d 9 one unpaired electron oxide two unpaired electron ok two unpaired electrons and then another copper 2 plus another unpaired electron. Let us say you are having copper oxide copper 2 plus 2 plus 2 minus there is net charge is going to be let us say 2 plus does not matter. Now, this is a d 9 electronic configuration this is a d 9 electronic configuration one spin up one spin up one unpaired electron one unpaired electron oxide is having two unpaired electron what it is have making it essentially since this is a coupled species this spin or this copper is bonded with oxide this oxide is also bonded with that this will enforce this up spin to go down. So, this is copper spin this is your oxide one on spin that will mean that this will go up and this spin will go down it is spin pairing they will try to pair it up. So, up down up down overall although it is a d 9 electronic system it was supposed to be paramagnetic unpaired electron means it is paramagnetic net effect is due to these exchange it will become diamagnetic ok. So, what I am trying to tell you is that knowing the whole thing is important just individual metal center is not good enough to tell the bulk properties of the compound or bulk properties of the material you need to know what they are bound with how they are bound with are they communicating with each other ok. So, it is a very interesting phenomenon you can see the magnetic properties can be communicated if it can be decreased there is other orientation where it can be increased by having some interaction. So, both decrease and increase is possible right. So, this is where what actually you see kind of these anti ferromagnetic behavior you see it is after certain temperature you can see the magnetic moment value is decreasing. So, because they are interacting after that temperature they are interacting with other molecule in a way that will canceling some of the spin it could also increase as you see for ferromagnetic cases. So, it is nothing, but electronic spin are varying different wage with respect to temperature it may be pairing up or it may be getting more unpaired ok. Therefore, you see of course, this is nothing, but more of a paramagnetic, but the increment with respect to temperature is huge all of a sudden right. So, it is increasing increasing as you decreasing the temperature, but at certain after certain temperature you see that there is a jump or the slope is changing right. So, something is happening in terms of electronic arrangement that is all it says ok. Now, you can see the read about these of core temperature and whatever this needle temperature and so on I think you have studied it before ferromagnetic, anti ferromagnetic and paramagnetic you study from a book ok magnetization ok. So, if you see if you are if you are trying to magnetize one species let say with a magnet you are trying to magnetize another species what essentially happening is you are reorienting the spin of those molecule ok. So, for example, this is the magnetization if you want if you can reverse the spin this is going to lead to that neutralization right it is nothing, but changing the spin all up all down one up one down how many up how many down going to determine the magnetic properties or magnetic behavior of a compound 2 more minutes may be 1 minute will be good enough ok you read this ok. There is some material for example, over here if you are if you are increasing the temperature or decreasing the temperature you can understand how you can give low spin to high spin you know that if you heat it up for example, you can go from low spin to high spin spin will increase right. So, if that is happening you are going to increase the magnetic moment right. So, you are increasing the temperature temperature and at certain temperature high spin complex will be forming from there low spin to high spin complex is formed. Now, if that high spin species upon cooling down or bringing it to room temperature does not come back to the previous orientation that mean low spin orientation quickly those are the one are called hard magnet. They you can heat it or you can change the external condition you can keep it in a high spin state and it can hold on to that magnetic behavior for some time. Those are hard magnet usual magnets are hard magnet. There are soft magnet you heat it little bit it goes up you know magnetic values goes up high low spin to high spin configuration occur, but then again cooling down it comes back very quickly these are called soft magnet. So, you can read about hard magnet and soft magnet once again from any book ok almost done I think this is done this is one or two last slide it is the same thing. So, we have learned so far hard magnet soft magnet anti ferromagnetic ferromagnetic paramagnetic. Now, if you have a cluster if you have a cluster for example, manganese oxo cluster manganese can have spin oxo can also have spin manganese 2 plus let us say oxide oxide 2 minus has unpaired electron. Overall you have lot of spin up lot of spin down theoretically then you have to do almost a calculation in computer to figure out the net magnetic moment of the species alright. I think that is all for today.