Irradiation-induced shrinkage and expansion mechanisms of SiO₂circle membrane nanopores

Abstract: 20 nm diameter SiO(2) nanopore arrays on gradient-thickness membranes were formed by a focused electron beam with in situ transmission electron microscopy (TEM). Nanopore shrinkage was seen in nanopores on thicker membranes, with the rate of diameter change remaining constant during the shrinkage process. In contrast, pore expansion was observed in thinner membranes, with the expansion rate being constant at the initial stage but with a slight increase at the later stage. The geometry model of shrinkage and ex… Show more

“…4a–4c) (see Supplementary Movies S1–S2 online). Such nonlinear shrinking behavior is in contrast with knowledge revealed during the shrinkage of nanopores in SiO 2 , where the shrinking rate remained constant1017.…”

“…Noticeable expansion of the nanopore was not observed, which may be attributed to oxidation. Such size effects suggest that the surface-tension effect17 should be considered in the healing mechanism in Mg. However, the detailed relationship between the critical size and sample thickness is beyond the scope of the present study and will be studied in future research.…”

“…Without the e-beam, the nanopore would remain frozen and retain its original size. The healing process has been attributed to the surface tension effect of fluidized atoms1017. Using transmission electron microscope (TEM) images, which provide real-time feedback during the healing process, allow for the precise control of pores with sub-nanometer sizes.…”

Electron beam-assisted healing of nanopores in magnesium alloys

“…4a–4c) (see Supplementary Movies S1–S2 online). Such nonlinear shrinking behavior is in contrast with knowledge revealed during the shrinkage of nanopores in SiO 2 , where the shrinking rate remained constant1017.…”

“…Noticeable expansion of the nanopore was not observed, which may be attributed to oxidation. Such size effects suggest that the surface-tension effect17 should be considered in the healing mechanism in Mg. However, the detailed relationship between the critical size and sample thickness is beyond the scope of the present study and will be studied in future research.…”

“…Without the e-beam, the nanopore would remain frozen and retain its original size. The healing process has been attributed to the surface tension effect of fluidized atoms1017. Using transmission electron microscope (TEM) images, which provide real-time feedback during the healing process, allow for the precise control of pores with sub-nanometer sizes.…”

Electron beam-assisted healing of nanopores in magnesium alloys

“…Solid-state nanopores have been extensively investigated due to many biological engineering and scientific applications, such as for rapid electrical detection and analysis of biopolymers, 1-5 powerful DNA detection, and genome sequencing technology. 6,7 To date, nanopores were fabricated and studied in various materials including SiO 2 , 8,9 Si 3 N 4 , 10 Al 2 O 3 , 11 and graphene, 12 etc., via electron beam (e-beam) drilling 10,12 and ion beam sculpting. 13 It is interesting to note that most of the nanopores reported previously are circular with no obvious facets, as a result of the isotropic property in amorphous materials.…”

“…13 It is interesting to note that most of the nanopores reported previously are circular with no obvious facets, as a result of the isotropic property in amorphous materials. [8][9][10][11] While faceted nanopores can be potentially employed in rapid electrical detection and analysis of biomacromolecule with various shapes, the relevant investigation has been rarely reported. 14 In addition, Venta et al recently showed the synthesis of electrically controlled gold nanoparticles inside nanopores, 15 indicating that an individual nanopore can serve as a "nano-mold" regarding the synthesis of nanomaterials.…”

Fabrication of faceted nanopores in magnesium

Resizing Metal‐Coated Nanopores Using a Scanning Electron Microscope