The negative capacitance FET (NCFET) proposed by Supriyo
        Datta  et.  al    is  an  alternative  steep  slope  device  to

        overcome  the  classical  limit  of  60mV/dec.  The  switching

        energy  of  the  device  can  be  reduced  by  replacing  the
        insulator  with  ferroelectric  (FE)  materials.  The  basic

        structure  of  NCFET  with  ferroelectric  material  as  gate
        oxide  .  The  underlying  mechanism  for  sub-60  mV/decade

        operation  of  an  NCFET  is  the  passive  amplification  of  the

        gate voltage at the interface between the ferroelectric gate
        oxide  and  the  semiconductor  channel.  The  voltage  drop

        across the ferroelectric gate oxide is a negative quantity as

        ferroelectric capacitance is negative (CF<0) which increases
        the  charge  density  in  the  channel.  Thus  it  acts  as  an

        external  amplifier  to  MOSFETs  and  also  achieves

        subthreshold  slope  of  less  than  60mV/decade.  This
        principle  reduces  the  gate  voltage  required  to  turn  the

        transistor ON the NCFET.  Von,D is the turn-ON voltage for

        a conventional MOSFET and Von,F for an NCFET.



        One  of  the  key  challenges  of  NCFET  technology  is  to
        achieve steep sub-threshold swing due to the variations in

        substrate  capacitance,  CS.  To  achieve  steep  SS,  the

        capacitance CF and CS shown in Fig. 1 should be closer ,
        however the variation of CS is large compared with CF in

        the  sub-threshold  regime.  The  scaling  will  necessitate

        thinner FE layer and resulting FE capacitance is too large
        and hence there will barely be any NC effects . To improve

        SS,  it  is  required  to  use  thicker  FE  which  is  difficult  to

        realize in the scaled FETs .