No, that's not the reason for the limited bandwidth of real amplifiers.
But keep on asking good questions as you study -- asking good questions is one of the keys to learning well.
There are a couple of reasons for the limited BW. The first is easy to understand, and the second one requires a bit more explanation. The first reason is that in any real circuit, there will be some finite resistance and at least parasitic capacitance. This forms a lowpass filter that limits how the amplifier can respond as the input frequencies get higher and higher. You can try to minimize the parasitic capacitance and use low impedances (which increases power dissipation of the amp), but you can only get so far with that strategy.
http://hyperphysics.phy-astr.gsu.edu/hbase/electric/imgele/rclo.gif
The second reason is that in amplifiers that are used in closed-loop feedback circuits, it is important to ensure that the amplifier does not go unstable and oscillate under any conditions (unless you want it to, like in an oscillator circuit). This is often done with internal components that limit the bandwidth of the amplifier (especially with opamps). The goal of this bandwidth limiting is to ensure that the overall gain of the amp falls to <1.0 as the phase shift through the amplifier gets close to -180 degrees. If the phase shift through the amplifier and external negative feedback circuit reaches -180 degrees and the opamp still has gain >1.0 at that frequency, you will get oscillations and the circuit will not work as intended.
The keyword phrases for reading more about this on-purpose limiting of amplifier gain are: Dominant Pole Compensation of Opamps, and Phase Margin of Opamps.
http://cktse.eie.polyu.edu.hk/eie403/solution1-bode.jpg
[PLAIN]http://cktse.eie.polyu.edu.hk/eie403/solution1-bode.jpg[/QUOTE]
Ah thank you very much. That cleared up a lot.
