A two-dimensional
(2D) nonvolatile memory device architecture to
improve the long-term charge retention with the minimum charge loss
without compromising storage capacity and the extinction ratio for
practical applications has been an imminent demand. To address the
current issue, we adopted a novel type-II band-aligned heterobilayer
channel comprising vertically stacked monolayer WSe2 nanodots
on monolayer WS2. The band offset modulation leads to electron
doping from WSe2 nanodots into the WS2 channel
without any external driving electric field. As a result, the tested
device outperformed with a memory window as high as 34 V and a negligible
charge loss of 7% in a retention period of 10 years while maintaining
a high extinction ratio of 106. The doping technique presented
in this work provides a feasible route to modulate the electrical
properties of 2D channel materials without hampering charge transport,
paving the way for high-performance 2D memory devices.