ABSTRACT
Semiconductor nanowires are commonly described as being defect-free due to their ability to expel mobile defects with long-range strain fields. Here, we describe previously undiscovered topologically protected line defects with null Burgers vector that, unlike dislocations, are stable in nanoscale crystals. We analyze the defects present in semiconductor nanowires in regions of imperfect crystal growth, i.e., at the nanowire tip formed during consumption of the droplet in self-catalyzed vapor-liquid-solid growth and subsequent vapor-solid shell growth. We use a form of the Burgers circuit method that can be applied to multiply twinned material without difficulty. Our observations show that the nanowire microstructure is very different from bulk material, with line defects either (a) trapped by locks or other defects, (b) arranged as dipoles or groups with a zero total Burgers vector, or (c) have a zero Burgers vector. We find two new line defects with a null Burgers vector, formed from the combination of partial dislocations in twinned material. The most common defect is the three-monolayer high twin facet with a zero Burgers vector. Studies of individual nanowires using cathodoluminescence show that optical emission is quenched in defective regions, showing that they act as strong nonradiative recombination centers.
ABSTRACT
Cocultivation of a clonal factor-dependent hematopoietic cell line (FDC-P1JL26) with an irradiated bone marrow stromal cell line (D2XRII) significantly increased the frequency of isolation of factor-independent subclones. Eight out of nine factor-independent subclonal lines showed expression of IL-3, GM-CSF or both cytokine mRNAs by reverse-transcription polymerase chain reaction (RT-PCR) and seven of these expressed biologically active GM-CSF or IL-3. In three cell lines that synthesized biologically active IL-3 (FIJ1, FIJ4D and FIJ10D) insertion of an IAP sequence into the IL-3 gene was detected by PCR analysis and the insertions were confirmed by DNA sequence analysis of PCR or RT-PCR fragments. In the four cell lines in which no IL-3 expression was detected no IAP insertions were detected. Rearrangements of the GM-CSF gene were detected in three factor-independent cell lines and an insertion of an IAP into the GM-CSF gene was confirmed by DNA sequence analysis of PCR fragments. In contrast to results with IL-3, insertion of an IAP into the GM-CSF gene did not correlate with GM-CSF expression. In one cell line that contained an IAP insertion into the GM-CSF gene, no GM-CSF was detected by biological assay nor by RT-PCR. Retrotransposition of IAPs may be responsible for the emergence of factor-independent cells in our cocultivation system and other IAP insertions may prove to be responsible for the factor-independent phenotype seen in the non-autocrine factor-independent cell line, FI7CL2.
