Bent Polytypic ZnSe and CdSe Nanowires Probed by Photoluminescence

Kim, Yejin; Im, Hyung Soon; Park, Kidong; Kim, Jundong; Ahn, Jae‐Pyoung; Yoo, Seung Jo; Kim, Jin-Gyu; Park, Jeunghee

doi:10.1002/smll.201603695

Cited by 16 publications

(17 citation statements)

References 47 publications

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“…It has been observed that the emission of bent (or buckled) NWs red shifts due to a piezoelectric field. 9−13 We predict that the band gap of the bent GaP and GaAs NWs would decrease owing to the dominant tensile strain. Furthermore, the larger excessive tensile strain of GaAs NWs suggests the larger band gap decrease as compared to that of GaP NWs.…”

Section: Results and Discussionmentioning

confidence: 99%

“…2−8 For bent (or buckled) NWs, a red-shifted emission has been observed, which has been explained by the piezotronic effect, in which under a piezoelectric field, the number of photons emitted from the outer surface of the NW is much larger than that from the inner surface. 9−13 The outstanding piezoelectric properties of ZnO and CdS NWs have facilitated the development of various piezotronic and piezo-phototronic devices such as nanogenerators, field-effect transistors, and light-emitting diodes, which rely on the piezoelectric potential created along the strained NWs. 3,14−16 Moreover, the enhanced carrier mobility or photocurrent of strained NWs has attracted widespread research interest owing to their great potential in a rich variety of applications.…”

Section: Introductionmentioning

confidence: 99%

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Strain Mapping and Raman Spectroscopy of Bent GaP and GaAs Nanowires

Park

Kim

et al. 2018

ACS Omega

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Strain engineering of nanowires (NWs) has been recognized as a powerful strategy for tuning the optical and electronic properties of nanoscale semiconductors. Therefore, the characterization of the strains with nanometer-scale spatial resolution is of great importance for various promising applications. In the present work, we synthesized single-crystalline zinc blende phase GaP and GaAs NWs using the chemical vapor transport method and visualized their bending strains (up to 3%) with high precision using the nanobeam electron diffraction technique. The strain mapping at all crystallographic axes revealed that (i) maximum strain exists along the growth direction ([111]) with the tensile and compressive strains at the outer and inner parts, respectively; (ii) the opposite strains appeared along the perpendicular direction ([2̅11]); and (iii) the tensile strain was larger than the coexisting compressive strain at all axes. The Raman spectrum collected for individual bent NWs showed the peak broadening and red shift of the transverse optical modes that were well-correlated with the strain maps. These results are consistent with the larger mechanical modulus of GaP than that of GaAs. Our work provides new insight into the bending strain of III–V semiconductors, which is of paramount importance in the performance of flexible or bendable electronics.

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Section: Results and Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Strain Mapping and Raman Spectroscopy of Bent GaP and GaAs Nanowires

Park

Kim

et al. 2018

ACS Omega

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“…Different materials in the II‐VI compound have different bandgaps, such as 1.5 eV for CdTe, 3.7 eV for ZnS, and the like. This makes them ideal for optoelectronic devices at different wavelengths . ZnO is one of the most widely studied materials in oxide semiconductors (II‐VI) .…”

Section: Low‐dimensional Semiconductor Nanomaterialsmentioning

confidence: 99%

“…This makes them ideal for optoelectronic devices at different wavelengths. 101,102 ZnO is one of the most widely studied materials in oxide semiconductors (II-VI). 66,92,103-107 ZnO has very good semiconductor properties with wide direct bandgap and unique piezoelectric and mechanical properties, which make ZnO have many applications, such as PDs, solar photovoltaics, flexible electronics, and so on.…”

Section: D Materialsmentioning

confidence: 99%

Recent advances in low‐dimensional semiconductor nanomaterials and their applications in high‐performance photodetectors

Fang

Zhou

Xiao

et al. 2019

InfoMat

106

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Low‐dimensional (including two‐dimensional [2D], one‐dimensional [1D], and zero‐dimensional [0D]) semiconductor materials have great potential in electronic/optoelectronic applications due to their unique structure and characteristics. Many 2D (such as transition metal dichalcogenides and black phosphorus) and 1D (such as NWs) materials have demonstrated superior performance in field effect transistors, photodetectors (PDs), and some flexible devices. And in some hybrid structures of 0D materials and 1D or 2D materials, the modification of 1D and 2D devices by 0D materials is embodied. This type of hybrid heterostructure has a larger performance optimization compared with the original. In the application of PDs, the variety of low‐dimensional materials and properties enable wide‐spectrum detection from ultraviolet UV to infrared, which provide a potential option for PDs under various conditions. For flexible electronic devices, high performance and mechanical stability are two important features. Low‐dimensional materials offer unparalleled advantages in flexible devices. In this review, we will focus on the various low‐dimensional materials that have been extensively studied and their applications in the electronics/optoelectronic and flexible electronics. From the composition and lattice structure of materials (including alloys) to the construction of various devices and heterostructures, we will introduce their application and recent development under various conditions. These works can provide valuable guidance for the construction and application of more high‐performance and multifunctional devices.

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“…Zinc selenide (ZnSe) is an important II-VI semiconductor material with a direct band-gap of ~2.7 eV at room temperature, which is widely regarded as a very good candidate for blue-violet light emitting devices [1] [2] [3] [4]. With the miniaturization of devices, many research groups have begun to study the nanostructures of ZnSe materials and have done a lot of work in this area.…”

Section: Introductionmentioning

confidence: 99%

One-Step Synthesis of Enhanced Band-Edge Emission ZnSe Nanowires Assisted by SnO<SUB>2</SUB>

Hou¹,

Guo²,

Zhang³

2020

AMPC

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Bent Polytypic ZnSe and CdSe Nanowires Probed by Photoluminescence

Cited by 16 publications

References 47 publications

Strain Mapping and Raman Spectroscopy of Bent GaP and GaAs Nanowires

Strain Mapping and Raman Spectroscopy of Bent GaP and GaAs Nanowires

Recent advances in low‐dimensional semiconductor nanomaterials and their applications in high‐performance photodetectors

One-Step Synthesis of Enhanced Band-Edge Emission ZnSe Nanowires Assisted by SnO<SUB>2</SUB>

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Bent Polytypic ZnSe and CdSe Nanowires Probed by Photoluminescence

Cited by 16 publications

References 47 publications

Strain Mapping and Raman Spectroscopy of Bent GaP and GaAs Nanowires

Strain Mapping and Raman Spectroscopy of Bent GaP and GaAs Nanowires

Recent advances in low‐dimensional semiconductor nanomaterials and their applications in high‐performance photodetectors

One-Step Synthesis of Enhanced Band-Edge Emission ZnSe Nanowires Assisted by SnO&lt;SUB&gt;2&lt;/SUB&gt;

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One-Step Synthesis of Enhanced Band-Edge Emission ZnSe Nanowires Assisted by SnO<SUB>2</SUB>