Spatially Resolved Doping Concentration and Nonradiative Lifetime Profiles in Single Si-Doped InP Nanowires Using Photoluminescence Mapping

Abstract: We report an analysis method that combines microphotoluminescence mapping and lifetime mapping data of single semiconductor nanowires to extract the doping concentration, nonradiative lifetime, and internal quantum efficiency along the length of the nanowires. Using this method, the doping concentration of single Si-doped wurtzite InP nanowires are mapped out and confirmed by the electrical measurements of single nanowire devices. Our method has important implication for single nanowire detectors and LEDs and … Show more

“…It is well known that due to background impurity doping, the unintentionally doped InP grown by MOVPE is normally n‐type . We also found that the InP NWs grown by the SAE technique exhibit a relatively high background doping density of ~10 17 cm −3 , which has to be taken into consideration when designing p‐n junction for solar cell applications. In this work, three different InP NWSC structures grown on p‐doped InP substrate by SA‐MOPE, namely i(n − )‐n, p‐i(n − )‐n, and p‐p − ‐n, were designed and characterized using EBIC technique.…”

“…Sample III (p‐p − ‐n + ) was grown with a p‐doped section (1.5 minutes) on the p + substrate followed by a lightly p‐doped section (5 minutes) and a heavily n‐doped section (1.5 minutes). The doping concentrations of both n‐doped and undoped sections were calibrated based on our previous doping study . However, despite a high doping concentration aimed for the bottom p‐region for samples II and III, we find it difficult to determine the p‐type doping concentration using both the photoluminescence (PL) and electrical measurements which were previously used to determine the n‐type doping concentration with great success, implying that the p‐region of our NWs may be only lightly doped (<1 × 10 17 cm −3 ) despite that a high diethylzinc (DEZn) flow rate was used.…”

“…C, The IQE as a function of excitation power from samples I, II, and III. The curves are calculated from fitting the carrier rate equation using the method described by Fan et al [Colour figure can be viewed at wileyonlinelibrary.com]…”

“…However, due to the complex nature of NW growth, background doping, growth rate, and dopant diffusion may vary greatly during the growth of different NWSC structures with different p, i, n‐segment designs. As a result, the junction position and size may significantly deviate from the original design and moreover, the material quality (both optical and electrical) of the NWSC structures may also vary significantly, making it challenging to understand and optimize the NWSC performance. Therefore, it is highly desirable to employ a technique which is able to directly visualize the width and position of the p‐n junction for device optimization.…”

Axial p‐n junction design and characterization for InP nanowire array solar cells

“…It is well known that due to background impurity doping, the unintentionally doped InP grown by MOVPE is normally n‐type . We also found that the InP NWs grown by the SAE technique exhibit a relatively high background doping density of ~10 17 cm −3 , which has to be taken into consideration when designing p‐n junction for solar cell applications. In this work, three different InP NWSC structures grown on p‐doped InP substrate by SA‐MOPE, namely i(n − )‐n, p‐i(n − )‐n, and p‐p − ‐n, were designed and characterized using EBIC technique.…”

“…Sample III (p‐p − ‐n + ) was grown with a p‐doped section (1.5 minutes) on the p + substrate followed by a lightly p‐doped section (5 minutes) and a heavily n‐doped section (1.5 minutes). The doping concentrations of both n‐doped and undoped sections were calibrated based on our previous doping study . However, despite a high doping concentration aimed for the bottom p‐region for samples II and III, we find it difficult to determine the p‐type doping concentration using both the photoluminescence (PL) and electrical measurements which were previously used to determine the n‐type doping concentration with great success, implying that the p‐region of our NWs may be only lightly doped (<1 × 10 17 cm −3 ) despite that a high diethylzinc (DEZn) flow rate was used.…”

“…C, The IQE as a function of excitation power from samples I, II, and III. The curves are calculated from fitting the carrier rate equation using the method described by Fan et al [Colour figure can be viewed at wileyonlinelibrary.com]…”

“…However, due to the complex nature of NW growth, background doping, growth rate, and dopant diffusion may vary greatly during the growth of different NWSC structures with different p, i, n‐segment designs. As a result, the junction position and size may significantly deviate from the original design and moreover, the material quality (both optical and electrical) of the NWSC structures may also vary significantly, making it challenging to understand and optimize the NWSC performance. Therefore, it is highly desirable to employ a technique which is able to directly visualize the width and position of the p‐n junction for device optimization.…”

Axial p‐n junction design and characterization for InP nanowire array solar cells

“…38,49 Another relevant study under a pulsed excitation condition was also conducted and would be of interest here as well. 50 Figure 3a lays out the experimental setup used to implement this method. It consists of the aforementioned μ-PL setup (blue background), in conjunction with time-correlated singlephoton counting (TCSPC) facility (pink background) for TRPL measurement (see ref 35 for details).…”

Wurtzite-Phased InP Micropillars Grown on Silicon with Low Surface Recombination Velocity

III – V Compound Semiconductor Nanowire Solar Cells