Let's consider npn transistor, when emitter-base is forward with

In summary: There is no (significant) injection of holes from base to collector. As I explained above, saturation doesn't go that far under normal forward (current entering the collector for an npn device) operation.
  • #1
Outrageous
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Let's consider npn transistor, when emitter-base is forward with voltage supplied to it, then the majority charge carrier(electron) will diffuse to base(p-type) ,
Then (in base-emitter) the minority charge carrier in p-type (electron) will that move close to the depletion layer of base-collector will drift to the collector(the flow of minority charge is spontaneous) so there will be current flow even without voltage supplied to base-collector circuit, right?
But why book say when no voltage supplied to the base-collector then there will not be current? Or this is because the current caused by minority charge in base is too small to be detected?
 
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  • #2


I was correct because that is why a transistor can act as a switch?
 
  • #3


First of all the majority carriers are injected over the barrier from n-emitter to p-base.

If you do not provide any base-collector bias, there won't be any collector current and the transistor will act similar to a diode.
 
  • #4


Outrageous said:
Let's consider npn transistor, when emitter-base is forward biased with voltage supplied to it, then the majority charge carriers(electron) will [strike]diffuse[/strike] be injected into the base (where they become minority cariers).

Then in the base [strike]-emitter[/strike] these minority carriers will diffuse toward the [strike]in p-type (electron) will that move close to the[/strike] depletion layer of base-collector junction, where they will be swept by the internal junction potential and drift to the collector.

Yes this time outragous is basically correct (though I did have to edit it a bit before I could really make that claim :tongue:).

Certainly on the important point that collector current can continue to flow even when Vbc=0 you are correct. In fact, it (a positive collector current) can continue to flow even when the bc junction is lightly forward biased (collector voltage lower than the base voltage for an npn device). This operating mode is called saturation.
 
  • #5


Thanks.
uart said:
In fact, it (a positive collector current) can continue to flow even when the bc junction is lightly forward biased

Do you mean that when it is heavily forward biased the minority charge carriers (hole) will not drift due to the decrease in depletion region of base-collector.

uart said:
(collector voltage lower than the base voltage for an npn device). This operating mode is called saturation.

Saturation mode is two forward biased diode . For npn, n-p is forward, and p-n is also forward?
 
  • #6


Outrageous said:
Thanks.
Do you mean that when it is heavily forward biased the minority charge carriers (hole) will not drift due to the decrease in depletion region of base-collector.
We were talking about npn right? The minority carriers in the base are electrons.

If the base-collector junction is too heavily forward biased then you'll start to get significant injection of holes from base to collector, a component of current flow opposite to what you desire. (current exiting the collector of npn rather then entering).

If however the base collector junction is only lightly forward biased then little BC injection will occur, but the electrons injected at the BE junction will continue to diffuse across the base and to the collector.

Taking for convenience the emitter voltage as ground, for an npn that's lightly saturated the base voltage will be approx 0.7 volts and the collector voltage about 0.5 volts. This makes the collector (n) about 0.2 volts lower than the base (p) and hence the BC junction forward biased.

For an npn in heavy saturation the collector voltage could be a low as 0.3 volts (or less) and the BC junction forward biased by around 0.5 volts. At this point the transistor current gain is falling fast (with increasing saturation) preventing it getting much more deeply saturated.

Saturation mode is two forward biased diode . For npn, n-p is forward, and p-n is also forward?
BE is forward biased, and BC is also forward biased, but not as strongly as BE.
 
  • #7


uart said:
If the base-collector junction is too heavily forward biased then you'll start to get significant injection of holes from base to collector, a component of current flow opposite to what you desire.E.

Then since there will be an injection of holes from base to collector ,then why do we need to forward biased BC with voltage supplied?
 
  • #8


Outrageous said:
Then since there will be an injection of holes from base to collector ,then why do we need to forward biased BC with voltage supplied?

- There is no (significant) injection of holes from base to collector. As I explained above, saturation doesn't go that far under normal forward (current entering the collector for an npn device) operation.

-In general we don't forward bias the BC junction with a supplied voltage. We normally reverse bias the BC junction.
 
  • #9


I am sorry, ask wrong thing.
uart said:
If however the base collector junction is only lightly forward biased then little BC injection will occur, but the electrons injected at the BE junction will continue to diffuse across the base and to the collector.

I mean if we don't forward the BC , there will still be an injection of minority charge carriers (electron) into the collector. Then why do we need to forward?
And if we don't put any voltage supplied to BC ,then there will be more current flow into the collector compare with forward biased BC , is this statement correct?
 
  • #10


Firstly, we don't normally forward bias the BC junction with the external supply, we in fact reverse bias it (eg collector more positive than base for an npn).

Now I'm not sure where this is leading, but it looks like you're thinking the you can achieve active mode operation without any external supply to bias it - you can't.

Yes saturation mode is extremely interesting, in the sense that we can maintain a current gain despite the external voltage between base and collector reversing slightly (so that this voltage actually opposes the direction of collector current flow). This is something that does confuse many students, and to understand it you need to realize that it is totally dependent upon base-emitter injection maintaining highly non thermal-equilibrium minority carrier levels in the base.

You can't look at what's happening at the BC junction in isolation. Looking at the device overall as a three terminal device you need a positive CE voltage (npn) to get a positive collector current. The transistor is NOT an energy source.

Anyway all of this is getting away from what I thought your initial question was about. It started out looking like an interesting question regarding some apparent contradictions of saturation mode, but has kind of gone off course since then. At this point I'm not entirely sure what you're asking or where your confusion is.
 
  • #11


You can operate a bipolar with zero base-collector voltage. It works almost normally, including the current gain.

In saturation mode, the base injects carriers in the epitaxial zone of the collector. This is where charge are stored in saturation and makes desaturation slow.

Beware some older books state wrongly that saturation injects carriers in the base. This was once with allied transistors, back in the germanium era, before epitaxy.
 
  • #12


Outrageous

Then (in base-emitter) the minority charge carrier in p-type (electron) will that move close to the depletion layer of base-collector will drift to the collector(the flow of minority charge is spontaneous) so there will be current flow even without voltage supplied to base-collector circuit, right?

This is nonsense.

If the base and emitter are connected to a circuit so that the base-emitter voltage is defined then the base-collector and emitter-collector voltages are also defined if the collector is also connected to some part of the same circuit.

If the collector is not connected then the collector voltage is undefined.

You cannot connect the collector without supplying some specified voltage (even zero).


Enthapy

Beware some older books state wrongly that saturation injects carriers in the base. This was once with allied transistors, back in the germanium era, before epitaxy.

Did you mean alloy transistor?
 
  • #13


If the transistor operates at or near zero collector-to-base voltage, about all emitter current is still swallowed in the collector, available for the external circuit.

That's because the depleted collector-base zone attracts the minority carriers injected in the base by the emitter.

It is the same process as in photovoltaic cells, except that the carriers are injected by the emitter, instead of being created by photons.

Just as in a photovoltaic cell, the current is available until the (collector-base) junction is directly polarized to a value where the corresponding direct current compensates the "photo"-current.

Correspondingly, a saturated bipolar transistor can have a collector current with Vce smaller than Vbe - can and does, if ohmic losses don't overshadow that.
 
  • #14


Thanks for so many replies. Still have something uncertain.


uart said:
For an npn in heavy saturation the collector voltage could be a low as 0.3 volts (or less) and the BC junction forward biased by around 0.5 volts. At this point the transistor current gain is falling fast (with increasing saturation) preventing it getting much more deeply saturated.
V of emitter is 0V, V of base is 0.7V, V of collector is 0.3 V.
What is heavy saturation ? Is that mean current gain will be very small? What do you mean bu deeply saturated?

uart said:
( so that this voltage actually opposes the direction of collector current flow).This is something that does confuse many students, and to understand it you need to realize that it is totally dependent upon base-emitter injection maintaining highly non thermal-equilibrium minority carrier levels in the base.
"Dependent upon base-emitter injection here mean that the
V of base minus V of emitter must be 0.7V, let's say V of emitter -0.7V, V of base is 0 , as long as V of collector is more positive than (-0.7V) then the electrons will definitely flow towards the collector?
What is highly non thermal equilibrium minority carrier levels in the base used for?

Enthalpy said:
You can operate a bipolar with zero base-collector voltage. It works almost normally, including the current gain..
If V of base is -1V , V of collector is -1V , but V of emitter is-0.8V. Do you mean that I can still operate it? But why not when V of base and emitter are 0V ?
Is that because all the electrons in base will flow out from base instead of flowing into collector? Or
Is that because there won't be any change in the base-collector junction?

Enthalpy said:
In saturation mode, the base injects carriers in the epitaxial zone of the collector. This is where charge are stored in saturation and makes desaturation slow..
Charged are stored in saturation mean there are a lot of charge in the collector? What is desaturation?



Studiot said:
If the base and emitter are connected to a circuit so that the base-emitter voltage is defined then the base-collector and emitter-collector voltages are also defined if the collector is also connected to some part of the same
In order to operate any mode of transistor, the collector terminal must be supplied with voltage, correct?

Enthalpy said:
If the transistor operates at or near zero collector-to-base voltage, about all emitter current is still swallowed in the collector, available for the external circuit.

That's because the depleted collector-base zone attracts the minority carriers injected in the base by the emitter.

Correspondingly, a saturated bipolar transistor can have a collector current with Vce smaller than Vbe - can and does, if ohmic losses don't overshadow that.

What do you mean by "swallowed" ? Disappear ? Or flow out from base?
Vce smaller than Vbe ?

Thank you .
 

1. What is an npn transistor?

An npn transistor is a type of bipolar junction transistor (BJT) that consists of three semiconductor layers: a thin layer of p-type material sandwiched between two layers of n-type material. This arrangement allows for the amplification of electrical signals by controlling the flow of electrons from the emitter to the collector through the base.

2. What happens when the emitter-base is forward biased?

When the emitter-base junction of an npn transistor is forward biased, it allows for a flow of electrons from the emitter to the base. This results in a large number of minority carriers (electrons) being injected into the base region, which then diffuse across the base and into the collector region. This amplifies the signal and allows for current to flow from the collector to the emitter.

3. What is the purpose of the emitter-base junction in an npn transistor?

The emitter-base junction serves as the control element in an npn transistor. By varying the forward bias voltage on this junction, the amount of current flowing from the collector to the emitter can be controlled. This allows for the amplification of electrical signals and the use of the transistor in various electronic applications.

4. How does the forward bias affect the characteristics of an npn transistor?

Forward biasing the emitter-base junction of an npn transistor results in a decrease in the width of the depletion region between the p and n layers. This allows for a larger number of minority carriers to be injected into the base, which increases the amplification and current flow through the transistor. Additionally, the forward bias also decreases the resistance of the junction, resulting in a higher current gain.

5. What is the difference between forward and reverse biasing in an npn transistor?

Forward biasing refers to the application of a voltage in the direction of the arrow on the emitter-base junction, which allows for current to flow through the transistor. Reverse biasing, on the other hand, refers to the application of a voltage in the opposite direction, which blocks the flow of current through the transistor. In an npn transistor, forward biasing allows for amplification and current flow, while reverse biasing prevents this from happening.

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