2004
DOI: 10.1103/physrevlett.93.105501
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Nanofilm Allotrope and Phase Transformation of Ultrathin Bi Film on Si(111)-7×7

Abstract: Our scanning tunneling microscopy and electron diffraction experiments revealed that a new twodimensional allotrope of Bi forms on the Si111-7 7 surface. This pseudocubic f012g-oriented allotrope is stable up to four atomic layers at room temperature. Above this critical thickness, the entire volume of the film starts to transform into a bulk single-crystal (001) When the size and shape of the materials are downsized to a nanometer scale, they often reveal anomalous atomic structures as well as exotic functio… Show more

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Cited by 446 publications
(484 citation statements)
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References 19 publications
(16 reference statements)
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“…There, the coexistence of both crystallographic orientations was attributed to the minor difference in surface free energy of ultrathin Bi(110) and Bi(111) films and Bi(111) films were observed to be kinetically limited at low temperatures. Here, we observe solely the growth of Bi (110) at low temperatures, transforming to Bi(111) around about 400 K. Surprisingly, the Bi(110) (domains) can be grown up to thicknesses of 14 nm, well beyond the critical thickness reported by both, Nagao [23,26] and Bobaru [38].…”
Section: (A) and (B) This Means That The Electronic Density Profile Ismentioning
confidence: 77%
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“…There, the coexistence of both crystallographic orientations was attributed to the minor difference in surface free energy of ultrathin Bi(110) and Bi(111) films and Bi(111) films were observed to be kinetically limited at low temperatures. Here, we observe solely the growth of Bi (110) at low temperatures, transforming to Bi(111) around about 400 K. Surprisingly, the Bi(110) (domains) can be grown up to thicknesses of 14 nm, well beyond the critical thickness reported by both, Nagao [23,26] and Bobaru [38].…”
Section: (A) and (B) This Means That The Electronic Density Profile Ismentioning
confidence: 77%
“…According to Nagao et al [23,26], at low film thickness the (puckered-layer) Bi(110) is more stable as a result of surface effects. As the thickness approaches a critical few layers, the surface effects become less dominant, transforming the film to Bi(111), as it becomes energetically more favorable.…”
Section: (A) and (B) This Means That The Electronic Density Profile Ismentioning
confidence: 99%
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“…15 However, the fact that only even numbers of layers are preferred may indicate that another relevant factor is the formation of a bilayer type of structure, as reported for Bi growth on Si ͑111͒. 17,18 An investigation of the structure of the Bi islands was therefore carried out.…”
Section: B Size Distribution Of Bi Islands At Higher Coveragementioning
confidence: 99%
“…16 Although the quantum size effects provide a good explanation of the preference for 4 AL high islands seen for Bi on i-Al 71 Pd 20 Mn 9 and related systems, there is another potential explanation which comes from work carried out on the closely related system of Bi films grown on Si͑111͒. 17,18 In this system, as with growth on quasicrystalline surfaces, a monolayer film of Bi is seen to form, on top of which Bi islands of 4 AL height grow, as demonstrated by STM studies. However, in this case density-functional theory calculations indicated the formation of a puckered "blackphosphorus"-like structure composed of bilayers of Bi atoms.…”
Section: Introductionmentioning
confidence: 99%