Theory of scanning gate microscopy

Abstract: A systematic theory of the conductance measurements of noninvasive (weak probe) scanning gate microscopy is presented that provides an interpretation of what precisely is being measured. A scattering approach is used to derive explicit expressions for the first-and second-order conductance changes due to the perturbation by the tip potential in terms of the scattering states of the unperturbed structure. In the case of a quantum point contact, the first-order correction dominates at the conductance steps and v… Show more

“…For a QPC r m t m = 0 on a conductance plateau [21,22], yielding a vanishing μ. Moreover, away from the edges of the plateau the V and U derivatives of r m t m also vanish, and thus 115414-2 g (1) i = 0.…”

“…On one hand, from various experimental and theoretical works focused on a QPC probed by a strongly charged tip, the conductance change appears to be closely related to the local current density [15,16,23,24]. On the other, it has been shown [22] that only under quite restrictive conditions (a spatially symmetric QPC tuned to a conductance plateau) the tip-induced conductance change is directly related to the current density at the tip position.…”

“…The last equality of Eq. (3) is obtained by a change into the basis of scattering eigenstates (built from the eigenmodes of t † t) [22], where the reflection and transmission submatrices are diagonal with nonzero elements r m (r m ) and t m (t m ) for l = 1,2. N is the number of channels in the leads and U 21 m m is the matrix element of the perturbing potential between the m th left-and the mth right-moving scattering eigenstates.…”

“…Even in the linear regime, the interpretation of the resulting scans is delicate [21,22]. On one hand, from various experimental and theoretical works focused on a QPC probed by a strongly charged tip, the conductance change appears to be closely related to the local current density [15,16,23,24].…”

“…Firstly, what is the local potential of a QPC operating in the nonlinear regime [1,[25][26][27][28][29]? Secondly, what is actually measured in the scanning gate microscopy of a QPC in the linear and nonlinear regimes [13,18,21,22]?…”

Scanning-gate-induced effects in nonlinear transport through nanostructures

“…For a QPC r m t m = 0 on a conductance plateau [21,22], yielding a vanishing μ. Moreover, away from the edges of the plateau the V and U derivatives of r m t m also vanish, and thus 115414-2 g (1) i = 0.…”

“…On one hand, from various experimental and theoretical works focused on a QPC probed by a strongly charged tip, the conductance change appears to be closely related to the local current density [15,16,23,24]. On the other, it has been shown [22] that only under quite restrictive conditions (a spatially symmetric QPC tuned to a conductance plateau) the tip-induced conductance change is directly related to the current density at the tip position.…”

“…The last equality of Eq. (3) is obtained by a change into the basis of scattering eigenstates (built from the eigenmodes of t † t) [22], where the reflection and transmission submatrices are diagonal with nonzero elements r m (r m ) and t m (t m ) for l = 1,2. N is the number of channels in the leads and U 21 m m is the matrix element of the perturbing potential between the m th left-and the mth right-moving scattering eigenstates.…”

“…Even in the linear regime, the interpretation of the resulting scans is delicate [21,22]. On one hand, from various experimental and theoretical works focused on a QPC probed by a strongly charged tip, the conductance change appears to be closely related to the local current density [15,16,23,24].…”

“…Firstly, what is the local potential of a QPC operating in the nonlinear regime [1,[25][26][27][28][29]? Secondly, what is actually measured in the scanning gate microscopy of a QPC in the linear and nonlinear regimes [13,18,21,22]?…”

Scanning-gate-induced effects in nonlinear transport through nanostructures

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