Silicon Wafers with Facet‐Dependent Electrical Conductivity Properties

Tan, Chih Shan; Hsieh, Pei‐Lun; Chen, Lih‐Juann; Huang, Michael H.

doi:10.1002/anie.201709020

Cited by 47 publications

(66 citation statements)

References 23 publications

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“…[7,11,[16][17][18] To verify that the facet-dependent electrical-conductivity phenomenon is broadly observable in semiconductors, electrical-conductivity measurementsh ave been made on four different faces of Si wafers, which revealed that the (111)a nd (112) surfaces are highly conductive. [19] The results are consistent with previous DFT calculations showing metal-like band structuresf or these two Si surfaces. [20] Because germanium is also an important wafer material, knowing the presence of facet-dependent electrical properties of germanium should be quite useful for novel integrated circuit fabrication.…”

Section: Introductionsupporting

confidence: 92%

“…Figure offers band structures of one to three layers of Ge(211) planes, the corresponding DOS plots, and side‐ and top‐view models of the Ge(211) planes. Since germanium and silicon have the same crystal structure, the previous assignment of the Si(112) plane could have been changed to Si(211) planes according to the presence of the (422) peak in the X‐ray diffraction pattern of silicon . The Supporting Information provides band structures of four to six layers of Ge(211) planes, the corresponding DOS plots, and models of the Ge(211) planes.…”

Section: Resultsmentioning

confidence: 99%

“…Since germanium and silicon have the same crystal structure, the previous assignment of the Si(112) plane could have been changed to Si(211) planes according to the presence of the (422) peak in the X-ray diffraction pattern of silicon. [19,20] The Supporting Information provides band structures of four to six layers of Ge(211) planes, the corresponding DOS plots, and modelso ft he Ge(211) planes. Again, valence-band and conduction-band energies cross each other for one and two layers of Ge(211) planes, thereby yieldingm etal-like band structures.…”

Section: Resultsmentioning

confidence: 99%

“…As the ultrathin layer has dissimilar band structures for different crystal faces it means that light of somewhat different wavelengths is absorbed by particles of various shapes, accounting for the observed facet‐dependent optical properties of Cu 2 O and other semiconductor crystals . To verify that the facet‐dependent electrical‐conductivity phenomenon is broadly observable in semiconductors, electrical‐conductivity measurements have been made on four different faces of Si wafers, which revealed that the (111) and (112) surfaces are highly conductive . The results are consistent with previous DFT calculations showing metal‐like band structures for these two Si surfaces .…”

Section: Introductionmentioning

confidence: 99%

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Density Functional Theory Calculations Revealing Metal‐like Band Structures for Ultrathin Germanium (111) and (211) Surface Layers

Tan

Huang

2018

Chemistry An Asian Journal

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To find out if germanium possesses facet-dependent electrical-conductivity properties, surface-state density functional theory (DFT) calculations were performed on one to six layers of germanium (100), (110), (111), and (211) planes. Tunable Ge(100) and Ge(110) planes always present the same semiconducting band structure with a band gap of 0.67 eV expected of bulk germanium. In contrast, one, two, four, and five layers of Ge(111) and Ge(211) plane models show metal-like band structures with continuous density of states (DOS) throughout the entire band. For three and six layers of Ge(111) and Ge(211) plane models, the normal semiconducting band structure was obtained. The plane layers with metal-like band structures also show Ge-Ge bond-length deviations and bond distortions, as well as significantly different 4s and 4p frontier-orbital electron counts and relative percentages integrated over the valence and conduction bands from those of the semiconducting state. These differences should contribute to strikingly dissimilar band structures. The calculation results suggest the observation of facet-dependent electrical-conductivity properties of germanium materials; when making transistors from germanium, the facet effects with shrinking dimensions approaching 3 nm may also need to be considered.

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Section: Introductionsupporting

confidence: 92%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Density Functional Theory Calculations Revealing Metal‐like Band Structures for Ultrathin Germanium (111) and (211) Surface Layers

Tan

Huang

2018

Chemistry An Asian Journal

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“…For example, a Cu 2 O octahedron is highly conductive, but a single Cu 2 O rhombic dodecahedron is insulating. More recently, intrinsic Si and Ge wafers have also revealed facet‐dependent electronic properties . All these semiconductors, including Ag 3 PO 4 crystals, display current‐rectifying effects when electrical contacts are made on two different crystal faces .…”

Section: Introductionmentioning

confidence: 99%

Density Functional Theory Calculations Revealing Metal‐like Band Structures and Work Function Variation for Ultrathin Gallium Arsenide (111) Surface Layers

Tan

Huang

2019

Chemistry An Asian Journal

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Density functional theory (DFT) calculations have been performed on tunable numbers of gallium arsenide (100), (110), and (111) planes for their electron density of states (DOS) plots and the corresponding band diagrams. The GaAs (100) and (110) planes show the same semiconducting band structure with tunable plane layers and a band gap of 1.35 eV around the Fermi level. In contrast, metal‐like band structures are obtained with a continuous band structure around the Fermi level for 1, 2, 4, 5, 7, and 8 layers of GaAs (111) planes. For 3, 6, and 9 GaAs (111) planes, the same semiconducting band structure as seen in the (100) and (110) planes returns. The results suggest the GaAs {111} face should be more electrically conductive than its {100} and {110} faces, due to the merged conduction band and valence band. GaAs (100) and (110) planes give a fixed work function, but the (111) planes have variable work function values that are smaller than that obtained for the (100) and (110) planes. Furthermore, bond length, bond geometry, and frontier orbital electron number and energy distribution show notable differences between the metal‐like and semiconducting plane cases, so the emergence of plane‐dependent electronic properties have quantum mechanical origin at the orbital level. GaAs should possess similar facet‐dependent electronic properties to those of Si and Ge.

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Nanocrystal Inks: Photoelectrochemical Printing of Cu₂O Nanocrystals on Silicon with 2D Control on Polyhedral Shapes

Vogel

Gonçales

Al‐Obaidi

et al. 2018

Adv Funct Materials

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text. Here is reported a printing technology that enables the functionalization of photoconducting materials with an arbitrary user-defined pattern of nanocrystals. Two sets of information can be encoded into the same unit area; control over the polyhedral shape of individual nanocrystals and high lateral resolution (micrometre scale) for large 2D patterns (millimetre scale) of Cu2O that were grown over unstructured amorphous silicon. Key to this new technology is a parallel modulation of both the electrode kinetics at the silicon/electrolyte interface as well as the light-assisted control of adsorption of halide ions on the growing Cu2O particles. This is achieved using local pixelation of a visible light stimuli by means of adapting to the field of photoelectrochemistry the instrumental tools for spatial light modulation more often used in super resolution microscopy. Any user-defined pattern (i.e., any arbitrary bitmap image file or a sequence of images) is converted within seconds into an array of nanoparticles. The process does not rely on the use of physical masks Received: ((will be filled in by the editorial staff)) Revised: ((will be filled in by the editorial staff))

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Silicon Wafers with Facet‐Dependent Electrical Conductivity Properties

Cited by 47 publications

References 23 publications

Density Functional Theory Calculations Revealing Metal‐like Band Structures for Ultrathin Germanium (111) and (211) Surface Layers

Density Functional Theory Calculations Revealing Metal‐like Band Structures for Ultrathin Germanium (111) and (211) Surface Layers

Density Functional Theory Calculations Revealing Metal‐like Band Structures and Work Function Variation for Ultrathin Gallium Arsenide (111) Surface Layers

Nanocrystal Inks: Photoelectrochemical Printing of Cu₂O Nanocrystals on Silicon with 2D Control on Polyhedral Shapes

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Silicon Wafers with Facet‐Dependent Electrical Conductivity Properties

Cited by 47 publications

References 23 publications

Density Functional Theory Calculations Revealing Metal‐like Band Structures for Ultrathin Germanium (111) and (211) Surface Layers

Density Functional Theory Calculations Revealing Metal‐like Band Structures for Ultrathin Germanium (111) and (211) Surface Layers

Density Functional Theory Calculations Revealing Metal‐like Band Structures and Work Function Variation for Ultrathin Gallium Arsenide (111) Surface Layers

Nanocrystal Inks: Photoelectrochemical Printing of Cu2O Nanocrystals on Silicon with 2D Control on Polyhedral Shapes

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Product

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Nanocrystal Inks: Photoelectrochemical Printing of Cu₂O Nanocrystals on Silicon with 2D Control on Polyhedral Shapes