Over the decades since ferroelectricity
was revealed, ferroelectric
materials have emerged as a cornerstone for a wide spectrum of semiconductor
technology and electronic device applications, particularly in state-of-the-art
complementary metal oxide semiconductor (CMOS) logic circuits and
digital information storage media. Recent unprecedented advancements
and future perspectives on integrating ferroelectric materials, particularly
with high-κ dielectrics for electronic devices, are weighed.
The emphasis is on (i) application (logic and memory); (ii) ferroelectric
materials (organic, inorganic, and two-dimensional (2D)); (iii) device
structures (metal/ferroelectric/metal (MFM), metal/ferroelectric/semiconductor
(MFS), metal/ferroelectric/insulator/semiconductor (MFIS), and metal/ferroelectric/metal/insulator/semiconductor
(MFMIS)); and (iv) next-generation electronic devices (negative capacitance
field effect transistors (NC-FETs), ferroelectric RAM (FeRAM), ferroelectric
field effect transistors (FeFETs), and ferroelectric tunnel junctions
(FTJs)). In NCFETs, the ferroelectric layer serves as a negative capacitor
so that the channel surface potential can be amplified more than the
gate voltage. Hence, devices can overcome the “Boltzmann tyranny”
and operate with a steep subthreshold swing < 60 mV/dec and supply
voltage < 0.5 V. Thus, NC-FETs would be more suitable for high-speed
logic operations, scalability, low-power, and cost-effectiveness,
targeting applications such as 14T-type CPU registers and 6T-type
cache static random access memory (SRAM). Ferroelectrics also opens
a path to solving the problems associated with technology scaling
due to the unique structural and electronic properties. Ferroelectric
memories are anticipated to be in different flavors based on optimum
performance, cost, and end-user requirements. Herein, we deliberate
on the exciting possibilities for the development of device structures
such as one-transistor one-capacitor (1T-1C)-type FeRAM with fast
access time (<10 ns), high endurance (∼>1014 cycles),
and moderate data retention being considered as a strong contender
for volatile dynamic random access memory (DRAM), while, for nonvolatile
memory applications, 1T-type ferroelectric gated transistors, called
FeFETs with nondestructive readout, fast access time (∼<100
ns), moderate endurance (>109 cycles), and high retention
time (>10 years) have the potential to compete with embedded solid-state
drives (SSDs). Finally, the FTJs with three-dimensional cross-point
architecture are strong contenders for high-density niche storage
applications to interchange with low-cost per bit external hard disk
drives. We conclude with a brief survey of recent ferroelectrics advances
and potential futuristic comparisons for next-generation computing
and storage device applications so the field may expand and pave the
way for high-volume manufacturing of semiconductor technology down
to the sub-5 nm node over the coming years.