The spin field effect transistor envisioned by Datta and Das[1] opens a gateway to spin information processing [2,3]. Although the coherent manipulation of electron spins in semiconductors is now possible [4][5][6][7], the realization of a functional spin field effect transistor for information processing has yet to be achieved, owing to several fundamental challenges such as the low spin-injection efficiency due to resistance mismatch [9], spin relaxation, and the spread of spin precession angles. Alternative spin transistor designs have therefore been proposed [10,11], but these differ from the field effect transistor concept and require the use of optical or magnetic elements, which pose difficulties for the incorporation into integrated circuits. Here, we present an all-electric and all-semiconductor spin field effect transistor, in which these obstacles are overcome by employing two quantum point contacts as spin injectors and detectors. Distinct engineering architectures of spin-orbit coupling are exploited for the quantum point contacts and the central semiconductor channel to achieve complete control of the electron spins-spin injection, manipulation, and detection-in a purely electrical manner. Such a device is compatible with large-scale integration and hold promise for future spintronic devices for information processing.Spin-orbit (SO) coupling-the interaction between a particle's spin and its motion-can be appreciated in the framework of an effective magnetic field B SO , which acts on charged particles when they move in an electric field E and is described by, where is Planck's constant divided by 2π, c is the speed of light, k is the particle's wavevector, and m is its mass. In semiconductor heterostructures, the electric field which gives rise to B SO can be created by breaking the structural inversion symmetry in the material, namely, the Rashba SO coupling [12,13]. Moreover, this electric field can easily be varied using metallic gates [14,15], thus controlling B SO . Such an effective magnetic field creates a link between the magnetic moment of the particle (spin) and the electric field acting upon it, offering a route for fast and coherent electrical control of spin states. While the SO coupling has been utilized for spin manipulation, approaches to spin injection and detection still rely on ferromagnetic and/or optical components, and the demonstration of an all-electric spin transistor device has remained elusive.Figure 1 illustrates our proposed spin field effect transistor (FET) and its operating principle. An InGaAs heterostructure (see Methods Summary), one of the strong contenders to replace Si in future generations of largescale integrated circuits (see International Technology Roadmap for Semiconductors; http://public.itrs.net), is used to provide a two-dimensional electron gas (2DEG) channel for ballistic electron transport under a metallic middle gate and between two gate-defined quantum point contacts (QPCs). The QPCs are narrow and short onedimensional (1D) constrictions, usually...
