Article Synopsis
- Researchers have successfully doped PbSe nanowire arrays to create pn junctions for use in electronic and optoelectronic devices, using oxygen for p-type and excess lead for n-type doping.
- They utilized a patternable blocking layer to define these junctions along the length of the nanowires, leading to the creation of functional inverters with significant amplification.
- The flexibility and compatibility of the doping process with plastic substrates suggest a cost-effective method for producing high-performance nanowire devices.
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Article Abstract
We report the controlled and selective doping of colloidal PbSe nanowire arrays to define pn junctions for electronic and optoelectronic applications. The nanowires are remotely doped through their surface, p-type by exposure to oxygen and n-type by introducing a stoichiometric imbalance in favor of excess lead. By employing a patternable poly(methyl)methacrylate blocking layer, we define pn junctions in the nanowires along their length. We demonstrate integrated complementary metal-oxide semiconductor inverters in axially doped nanowires that have gains of 15 and a near full signal swing. We also show that these pn junction PbSe nanowire arrays form fast switching photodiodes with photocurrents that can be optimized in a gated-diode structure. Doping of the colloidal nanowires is compatible with device fabrication on flexible plastic substrates, promising a low-cost, solution-based route to high-performance nanowire devices.
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