Feedback control of dimensions in nanopore and nanofluidic devices

What is claimed is: 1 . A method comprising: providing a substrate comprising a nanofluidic passage bounded by an electrical conductor; filling the nanofluidic passage with an electrolyte; causing the nanofluidic passage to at least partially close by electrochemically forming an oxide layer on the conductor; and setting a target dimension for the nanofluidic passage, monitoring the size of the nanofluidic passage, and discontinuing causing the nanofluidic passage to at least partially close when the target dimension is reached; and wherein the nanofluidic passage is a surface channel in the substrate. 2 . A method comprising: forming a nanofluidic passage having larger than targeted dimensions in a substrate; forming a conductive layer on the substrate, thereby reducing the dimensions of the nanofluidic passage, filling the nanofluidic passage with an electrolyte; and electrochemically oxidizing the conductive layer until the fluidic passage has the targeted dimensions; wherein the nanofluidic passage is a channel. 3 . The method of claim 2 wherein the channel is formed with an opening in a surface of the substrate, further including the step of closing the opening when forming the conductive layer on the substrate. 4 . A computer program product for controlling the fabrication of a nanofluidic device including a nanofluidic passage in a substrate, the nanofluidic passage comprising an electrically conductive surface and containing an electrolyte: a computer readable storage medium having computer readable program code embodied therewith, said computer readable program code comprising: computer readable program code configured to facilitate applying an electric potential between the electrolyte and the electrically conductive surface sufficient to cause oxidation of the electrically conductive surface; computer readable program code configured to monitor ionic current through the nanofluidic passage. 5 . The computer program product of claim 4 , further comprising computer readable program code configured to continuously monitor ionic current as the conductive surface is oxidized. 6 . The computer program product of claim 4 , further comprising computer readable program code configured to alternatively monitor the ionic current and apply the electric potential between the electrolyte and the conductive surface until a desired nanofluidic passage size is reached. 7 . A method comprising: providing a nanofluidic device including a nanofluidic passage having an electrically conductive surface and an electrolyte within the nanofluidic passage; applying a voltage to the electrically conductive surface to electrochemically change the dimensions of the nanofluidic passage; and reducing the dimensions of the nanofluidic passage by oxidizing the electrically conductive surface.