Owing to their unprecedented electronic properties, graphene and two-dimensional (2D) crystals have brought fresh opportunities for advances in planar spintronic devices. Graphene is an ideal medium for spin transport while also being an exceptionally resilient material for flexible electronics. However, these extraordinary traits have never been combined to create flexible graphene spin circuits. Realizing such circuits could lead to bendable strain-based spin sensors, a unique platform to explore pure spin current based operations and low power flexible nanoelectronics. Here, we demonstrate graphene spin circuits on flexible substrates for the first time. These circuits, realized using chemical vapour deposited (CVD) graphene, exhibit large spin diffusion coefficients ~0.19-0.24 m 2 s -1 at room temperature. Compared to conventional devices of graphene on Si/SiO2 substrates, such values are 10-20 times larger and result in a maximum spin diffusion length ~10 µm in graphene achieved on such industry standard substrates, showing one order enhanced room temperature non-local spin signals. These devices exhibit state of the art spin diffusion, arising out of a distinct substrate topography that facilitates efficient spin transport, leading to a scalable , highperformance platform towards flexible 2D spintronics. Our innovation unlocks a new domain for the exploration of strain-dependent spin phenomena, and paves the way for flexible graphene spin memory-logic units and surface mountable sensors.
Establishing
ultimate spin current efficiency in graphene over
industry-standard substrates can facilitate research and development
exploration of spin current functions and spin sensing. At the same
time, it can resolve core issues in spin relaxation physics while
addressing the skepticism of graphene’s practicality for planar
spintronic applications. In this work, we reveal an exceptionally
long spin communication capability of 45 μm and highest to date
spin diffusion length of 13.6 μm in graphene on SiO
2
/Si at room temperature. Employing commercial chemical vapor deposited
(CVD) graphene, we show how contact-induced surface charge transfer
doping and device doping contributions, as well as spin relaxation,
can be quenched in extremely long spin channels and thereby enable
unexpectedly long spin diffusion lengths in polycrystalline CVD graphene.
Extensive experiments show enhanced spin transport and precession
in multiple longest channels (36 and 45 μm) that reveal the
highest spin lifetime of ∼2.5–3.5 ns in graphene over
SiO
2
/Si, even under ambient conditions. Such performance,
made possible due to our devices approaching the intrinsic spin–orbit
coupling of ∼20 μeV in graphene, reveals the role of
the D’yakonov–Perel’ spin relaxation mechanism
in graphene channels as well as contact regions. Our record demonstration,
fresh device engineering, and spin relaxation insights unlock the
ultimate spin current capabilities of graphene on SiO
2
/Si,
while the robust high performance of commercial CVD graphene can proliferate
research and development of innovative spin sensors and spin computing
circuits.
Despite structural and processing-induced imperfections, wafer-scale chemical vapor deposited (CVD) graphene today is commercially available and has emerged as a versatile form that can be readily transferred to desired substrates for various nanoelectronic and spintronic applications. In particular, over the past decade, significant advancements in CVD graphene synthesis methods and experiments realizing high-quality charge and spin transport have been achieved. These include growth of large-grain graphene, new processing methods, high-quality electrical transport with high-carrier mobility, micron-scale ballistic transport, observations of quantum and fractional quantum Hall effect, as well as the spintronic performance of extremely long spin communication over tens of micrometers at room temperature with robust spin diffusion lengths and spin lifetimes. In this short review, we discuss the progress in recent years in the synthesis of high-quality, large-scale CVD graphene and improvement of the electrical and spin transport performance, particularly towards achieving ballistic and long-distance spin transport that show exceptional promise for next-generation graphene electronic and spintronic applications.
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