posted on 2021-05-26, 06:44authored byFengyuan Zhang, Hua Fan, Bing Han, Yudong Zhu, Xiong Deng, David Edwards, Amit Kumar, Deyang Chen, Xingsen Gao, Zhen Fan, Brian J. Rodriguez
When scaling the
lateral size of a ferroelectric random access
memory (FeRAM) device down to the nanometer range, the polarization
switching-induced displacement current becomes small and challenging
to detect, which greatly limits the storage density of FeRAM. Here,
we report the observation of significantly enhanced injection currents,
much larger than typical switching currents, induced by polarization
switching in BiFeO3 thin films via conductive atomic force
microscopy. Interestingly, this injected current can be effectively
modulated by applying mechanical force. As the loading force increases
from ∼50 to ∼750 nN, the magnitude of the injected current
increases and the critical voltage to trigger the current injection
decreases. Notably, changing the loading force by an order of magnitude
increases the peak current by 2–3 orders of magnitude. The
mechanically boosted injected current could be useful for the development
of high-density FeRAM devices. The mechanical modulation of the injected
current may be attributed to the mechanical force-induced changes
in the barrier height and interfacial layer width.