A self-referenced single-electron quantized-current source

With the anticipated redefinition of the international system of units (SI) the base units will be linked to fundamental constants of nature [1]. As for the electrical base unit "Ampere", it will be linked to the elementary charge e, requiring a corresponding quantum standard [2, 3]. Many concepts for such a standard have been investigated [4-14] relying on controlling the time-dependent tunnelling of electrons. However, the stochastic nature of quantum mechanical tunnelling intrinsically evokes uncontrolled deviations from the nominally quantized current. Alternatively, the counting of electrons [15, 16] has been explored but is severely limited in current amplitude and uncertainty by the low detector bandwidth. The late M. Wulf proposed [17] that this fundamental problem of electrical quantum metrology could be overcome by combining serial single-electron pumps with charge detectors allowing the generation of a quantized current and the in-situ detection of its stochastic deviations. Here, we experimentally demonstrate such quantized-current generation with in-situ detection of tunnelling errors at low frequencies and a reduction of the total current uncertainty by more than one order of magnitude. After frequency scaling this should enable a validated primary standard for the redefined SI base unit Ampere.