Active rectification

It is frequently used for arrays of photovoltaic panels to avoid reverse current flow that can cause overheating with partial shading while giving minimum power loss.

However, even Schottky rectifiers can be significantly more lossy than the synchronous type, notably at high currents and low voltages.

The voltage drop across the transistor is then much lower, causing a reduction in power loss and a gain in efficiency.

Active rectifiers also clearly still need the smoothing capacitors present in passive examples to provide smoother power than rectification does alone.

Using active rectification to implement AC/DC conversion allows a design to undergo further improvements (with more complexity) to achieve an active power factor correction, which forces the current waveform of the AC source to follow the voltage waveform, eliminating reactive currents and allowing the total system to achieve greater efficiency.

Voltage drop across a diode and a MOSFET. The low on-resistance property of a MOSFET reduces ohmic losses compared to the diode rectifier (below 32 A in this case), which exhibits a significant voltage drop even at very low current levels. Paralleling two MOSFETs (pink curve) reduces the losses further, whereas paralleling several diodes won't significantly reduce the forward-voltage drop.
Plot of power dissipated vs. current in four devices.
Active full-wave rectification with two MOSFETs and a center tap transformer.