We investigate the effect of LaTiO3 insertion at the interface between LaAlO3 and TiO2 terminated {100} SrTiO3, for a series of LaAlO3 and LaTiO3 thicknesses. A clear increase of the carrier density was observed while the Hall mobility was largely unchanged. In structures with LaAlO3 thickness ∼ 3 unit cells, close to the critical thickness for conductivity, as little as 0.25 unit cells of LaTiO3 drives an insulator-to-metal transition. These samples show a strong dependence of the conductivity on voltage with electrostatic back-gating, which can be understood in a two-carrier picture, and dominated by the change in carrier density at the interface.The LaAlO 3 /SrTiO 3 (LAO/STO) conducting interface is generating intense interest because of the highly mobile electrons present within a nanoscale thickness in the STO.[1] At the interface twodimensional (2D) superconductivity,[2] 2D Shubnikov-de Haas oscillations, [3,4] and magnetism, [5][6][7] have all been observed. Although the relative contributions of oxygen vacancies, [8][9][10] interdiffused dopants, [11] and the polar discontinuity (PD), [1,[12][13][14][15]] to these properties are still being debated, an intriguing aspect of the PD model is the possibility of modulation doping the STO, leading to relatively high Hall mobility due to the absence of scattering from ionized dopants.This system is particularly interesting since close to the critical thickness of LAO required for conductivity [∼ 3 unit cells (uc)], a back gate voltage applied on the STO can induce conductivity in an as-grown insulating sample at room temperature.[13] Back gating strategies have been used to tune the 2D superconductivity at low temperatures. [16] A disadvantage of gating is that the sheet carrier density n 2D is not modulated independently of the Hall mobility µ. [17] In order to fully explore the phase diagram of the LAO/STO system, other techniques to control n 2D are needed. Chemically doped STO layers, inserted between the LAO and undoped STO substrate, have been utilized to achieve this aim. [18][19][20] In the context of these open questions, the LAO/LaTiO 3 (LTO)/STO heterostructure is notable for several reasons. Given the stacking structure of ABO 3 in the {100} planes, two independent interfaces can be defined, corresponding to the positions at which the chemical make-up of the AO and BO 2 planes switch, as sketched in Fig. 1(a). The inserted LTO layer(s) spatially separates these A-site and B-site interfaces in a structurally clean manner, exploiting the close lattice match to STO. Simultaneously LTO can provide carrier modulation without placing dopant ions at the interface, since it contains a high density of electrons: for each layer of LTO, there exists a potential sheet carrier density of 6.5 × 10 14 cm −2 per lateral unit cell (uc). Usually these electrons are localized in a Mott insulating state, [21] however it has been shown that high µ conduction can be generated if these electrons are released into a STO host. [22][23][24][25] Here we investigate the use of...
