![]() ![]() Therefore the depletion region formed between the junction Base and Collector BC, will be significantly larger than the depletion region formed between the junction of Base and Emitter BE. ![]() However Collector being the region with least doping level after losing electrons due to diffusion, the depletion region formed will be large compared to Base and Emitter. Similarly Base will have a depletion region which is bigger than Emitter. Since the doping level of Emitter is higher than Base even after diffusion more number of electrons will remain in Emitter which leads to a small depletion region in which charge carriers will be non existent. We already knew when N-type and P-type regions are combined diffusion occurs, this leads to exchange of charge carriers between two regions. This is because of the different doping levels in the Emitter, Base and Collector region of a BJT transistor. The depletion region in BC junction is larger than depletion region of BE junction. There is another depletion region that is formed in the junction BC due to the process of diffusion. This means a voltage more than 0.7v should be applied to get the charge carriers move through BE depletion region. This leads to development of a voltage potential of 0.7v across the depletion region. Since this depletion region lacks charge carriers, it serves as a barrier to movement of charges between regions. The diffusion process leaves the area close to the junction with no electrons or holes (charge carriers ) forming a region which is referred as depletion region. This process of diffusion occurs until diffused electrons and holes oppose further movement of charge carriers to other sides as shown in the above figure. When electrons move from emitter this leaves an empty place, this will be occupied by movement of holes from Base region. In base electrons from Emitter will combine with holes in Base to form electron hole pairs. When combined the electrons from Emitter ( N-type material ) will diffuse into Base ( P-type material ) since concentration of charge carries in Emitter is higher than Base. Working of transistor can be understood by understanding how charge carries behave within its three regions. The process of making a BJT transistor that is combining N-type, P-type and N-type material together will form two transistor junctions – Emitter and Base ( BE ) & Base and Collector ( BC ). However in a BJT transistor there is three regions involved but working principle remains same. Diode has two (N-type and P-type semiconductor ) material combined together. Working of transistor is very much similar to diode since there is a significant resemblance in construction of diode to transistor. This leaves more number of free electrons to move from Emitter to Base and to Collector of the BJT transistor.Ĭircuits Library - 220+ practical circuits Size of the regions in a BJT follows this: Base Base >Collector. Collector forms the largest region in a BJT. Area of Emitter is bigger than Base but smaller than Collector. Base region will be smaller comparing to Emitter and Collector. The important thing to note in the above diagram is that Area of Emitter, Base and Collector are not equal in size. ![]() These terminals need to be used by the user to operate the transistor. The terminals attached to NPN or PNP transistors are Collector, Base, Emitter. This is quite similar to the construction of a diode where two semiconductor materials such as P type and N-type joined together whereas in transistor these materials are either two P-type with one N-type in the middle or two N-type with one P-type in the middle. First one is NPN transistor where the device is put together in N-type, P-type and N-type configuration whereas in PNP transistor the device is combined in the following fashion: P-type, N-type and P-type materials as shown in the figure above. This construction of N-type, P-type, N-type semiconductor materials creates two possible transistor configurations. Must read: Resources to self learn Electronics Construction of BJT transistor:īipolar Junction Transistor is a three terminal semiconductor device constructed by joining three semiconductor materials together. Modern electronics we use today made possible because of transistors since it played a huge role in reducing the size of boards drastically. Transistor is a popular three terminal semiconductor device used in Switching and Amplification applications. ![]()
0 Comments
Leave a Reply. |
AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |