STM observation of surface phases of Sn/Cu(001)

Nara, Yoshitaka; Yaji, Koichiro; Iimori, Takushi; Nakatsuji, Kan; Komori, Fumio

doi:10.1016/j.susc.2007.04.171

Cited by 14 publications

(26 citation statements)

References 6 publications

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“…25 The unit cells have been imaged using scanning tunneling microscopy. 26 We summarize here the most important results and refer the reader to Ref. 25 for a more detailed account.…”

Section: Introductionmentioning

confidence: 99%

Electronic structure and Fermi surface ofSn∕Cu(100)−(32×2)R
Martínez-Blanco
¹
,
Joco
²
,
Fujii
³

et al. 2008
Phys. Rev. B
11
5
20
1
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The surface phase Sn/ Cu͑100͒-͑3 ͱ 2 ϫ ͱ 2͒R45°exhibits a temperature induced phase transition to a ͑ ͱ 2 ϫ ͱ 2͒R45°phase above 360 K. We report an angle-resolved photoemission study of the two-dimensional Fermi surface of the low-temperature phase. The Fermi surface is formed by folding of a quasi-twodimensional surface band and presents three contours. It is characterized by gaps appearing in optimally nested regions of one of the contours, whereas other sections remain ungapped. We address the origin of the folding and of the surface phase transition, which is attributed to the formation of a surface charge density wave.

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“…25 The unit cells have been imaged using scanning tunneling microscopy. 26 We summarize here the most important results and refer the reader to Ref. 25 for a more detailed account.…”

Section: Introductionmentioning

confidence: 99%

Electronic structure and Fermi surface ofSn∕Cu(100)−(32×2)R
Martínez-Blanco
¹
,
Joco
²
,
Fujii
³

et al. 2008
Phys. Rev. B
11
5
20
1
View full text Add to dashboard Cite

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“…Thenceforth, the Sn/Cu͑001͒ surfaces have been studied by several methods, such as scanning tunneling microscopy ͑STM͒, LEED, and surface x-ray diffraction ͑SXRD͒ for each phase. 8,[18][19][20][21][22] These studies clarified that the surface structures of the 1/5-ML and 1/3-ML Sn/Cu͑001͒ are stable below ϳ450 K. 20 Whereas, the surface of the 1/2-ML Sn/ Cu͑001͒ shows a temperature induced reversible phase transition as described above. 8,13,14 Recently, a new phase has been reported between the 1/3-ML and 1/2-ML Sn/Cu͑001͒ surfaces by means of LEED, SXRD, and STM.…”

Section: Introductionmentioning

confidence: 53%

“…8,13,14 Recently, a new phase has been reported between the 1/3-ML and 1/2-ML Sn/Cu͑001͒ surfaces by means of LEED, SXRD, and STM. [20][21][22] J. M. Blanco et al 20 showed in their LEED observation that the surface of the new phase has ͑ −4 2 0 4 ͒ periodicity at 300 K. They also claimed that the LEED pattern showed a p͑2 ϫ 2͒ structure at 440 K. Nara et al 21 reported its atomic image at room temperature ͑RT͒ using STM and proposed a simple model of the Sn arrangement at the surface with Sn coverage of 3/8 ML. 21,22 However, the nature of the structural transition above RT has been unclear.…”

Section: Introductionmentioning

confidence: 99%

Phase transition for a38-monolayer Sn-adsorbed Cu(001) bimetallic surface alloy

et al. 2009

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Structural transition of 3/8 monolayer Sn-adsorbed Cu͑001͒ surface alloy and the changes in the Sn-induced surface resonance band have been studied by low-energy electron diffraction and angle-resolved photoemission spectroscopy. The surface structure reversibly changes between ͑ −4 2 0 4 ͒ periodicity at low temperature and ͑1 ϫ 1͒ periodicity at high temperature. This transition is interpreted as an order-disorder transition from the structure model while the resonance band of the 3/8-ML Sn/Cu͑001͒ surface significantly changes with the transition. The band folds back with an energy gap with decreasing temperature through the transition temperature. The backfolding point of the band is close to the Fermi wave number in reciprocal space in the angle range between 0°and 11°from the ⌫ M line, and is independent of surface Brillouin-zone boundary.

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“…Diffraction patterns of the p(2 Â 6) structure have missing spots, that is, glide planes are present [11]. The subsequently observed phase is a c(4 Â 8) structure, that was discovered recently by scanning tunneling microscopy (STM) studies [10,11]. The coverage of a proposed model is 0.375 ML.…”

Section: Introductionmentioning

confidence: 87%

“…Among such adsorption systems, Sn-adsorbed Cu(0 0 1) surfaces have been extensively studied [4][5][6][7][8][9][10][11][12][13][14]. The Cu(0 0 1)-Sn system showed five ordered phases at room temperature in a submonolayer coverage [9,12].…”

Section: Introductionmentioning

confidence: 99%

Structure determination of the Cu(001)–c(4×4)-Sn surface by low-energy electron diffraction

et al. 2010

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STM observation of surface phases of Sn/Cu(001)

Cited by 14 publications

References 6 publications

Electronic structure and Fermi surface ofSn∕Cu(100)−(32×2)R
Martínez-Blanco
¹
,
Joco
²
,
Fujii
³

et al. 2008
Phys. Rev. B
11
5
20
1
View full text Add to dashboard Cite

Electronic structure and Fermi surface ofSn∕Cu(100)−(32×2)R
Martínez-Blanco
¹
,
Joco
²
,
Fujii
³

et al. 2008
Phys. Rev. B
11
5
20
1
View full text Add to dashboard Cite

Phase transition for a38-monolayer Sn-adsorbed Cu(001) bimetallic surface alloy

Structure determination of the Cu(001)–c(4×4)-Sn surface by low-energy electron diffraction

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STM observation of surface phases of Sn/Cu(001)

Cited by 14 publications

References 6 publications

Electronic structure and Fermi surface ofSn∕Cu(100)−(32×2)RMartínez-Blanco1, Joco2, Fujii3 et al. 2008Phys. Rev. B115201View full textAdd to dashboardCite

Electronic structure and Fermi surface ofSn∕Cu(100)−(32×2)RMartínez-Blanco1, Joco2, Fujii3 et al. 2008Phys. Rev. B115201View full textAdd to dashboardCite

Phase transition for a38-monolayer Sn-adsorbed Cu(001) bimetallic surface alloy

Structure determination of the Cu(001)–c(4×4)-Sn surface by low-energy electron diffraction

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Electronic structure and Fermi surface ofSn∕Cu(100)−(32×2)R
Martínez-Blanco
¹
,
Joco
²
,
Fujii
³

et al. 2008
Phys. Rev. B
11
5
20
1
View full text Add to dashboard Cite

Electronic structure and Fermi surface ofSn∕Cu(100)−(32×2)R
Martínez-Blanco
¹
,
Joco
²
,
Fujii
³

et al. 2008
Phys. Rev. B
11
5
20
1
View full text Add to dashboard Cite