High-Efficiency Selective Electron Tunnelling in a Heterostructure Photovoltaic Diode

Jia, Chuancheng; Ma, Wei; Gu, Chunhui; Chen, Hongliang; Yu, Haomiao; Li, Xinxi; Zhang, Fan; Gu, Lin; Xia, Andong; Hou, X. Y.; Meng, Sheng; Guo, Xuefeng

doi:10.1021/acs.nanolett.6b00727

Cited by 14 publications

(17 citation statements)

References 31 publications

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“…To solve the first problem, we and some other groups modified the graphene/environment interface with stimuli‐active components to fabricate graphene‐based hybrid chemical sensors or photodetectors with highly sensitive responses to external stimuli. A variety of graphene composites, such as graphene/polymer composites, have also been used as active sensing materials to improve the performances of graphene‐based gas sensors .…”

Section: Ternary Interfaces In Hybrid Devicesmentioning

confidence: 99%

“…To promote the development of this field and enable the development of high‐efficiency low‐cost photovoltaic and optoelectronic device architectures, ingenious and reliable interface designs for highly efficient separation and transmission of photogenerated carriers are required . In this regard, our group has developed a unique heterostructure photovoltaic diode with an all‐solid‐state ternary interface (TiO 2 /SLG/dye), which is composed of a TiO 2 electron‐collecting layer, SLG hole‐transporting layer, and monolayer of dye molecules ( Figure a) . Different from the conventional photovoltaic conversion process, in our photovoltaic device, both the electrons and holes generated by photoexcitation can tunnel into the graphene along the same direction, but only the electrons show a highly efficient ballistic transport to the TiO 2 transport layer (Figure b).…”

Section: Ternary Interfaces In Hybrid Devicesmentioning

confidence: 99%

“…Recently, we and some other groups found that more efficient functional and hybrid devices can be realized by building more complicated ternary interfaces (Figure e) such as semiconductor/recognition receptor/environment interfaces for specific light/chemistry/biosensing (Figure e, left), or a dye/single layer graphene (SLG)/titanium oxide (TiO 2 ) ternary interface, for efficient charge transport and photovoltaic conversion (Figure e, middle and right). The key to this idea is to separate the signal recognition from charge transport, each performing its own functions without interfering with the other.…”

Section: Introductionmentioning

confidence: 99%

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Precise Control of Interfacial Charge Transport for Building Functional Optoelectronic Devices

Zhang

Chen

Guo

2019

Adv Materials Technologies

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studies have not only improved device performance, but have even built novel functions. At present, interface engineering has become a research hotspot and has great potential for further applications in diverse fields, ranging from integrated circuits and energy conversion to catalysis and chemical/biosensors. Scientists with various backgrounds have been devoting great efforts to this area, which has moved from the simple improvement of device performance to branch out in broad directions, indicating its interdisciplinarity.As shown in Figure 1c, an important interface for an FET is the semiconductor/ electrode interface, which typically determines the efficiency of charge carrier injection and extraction. In general, the charge injection of a metal/organic semiconductor (OSC) junction can be described in terms of thermal electron emission or tunneling mechanisms, depending on the concentration of defect states inside the bandgap (Figure 1c, left and middle). [1] By carefully selecting the self-assembled monolayer (SAM) or thin buffer interlayer to modify the metal electrode (Figure 1c, right), the interface charge injection barrier can be fine-tuned, thereby significantly reducing the contact resistance of the device. More interestingly, by using a stimuli-responsive conformational isomer as a functional layer to modify the electrode interface, functionalization of the electrodes can be achieved. This concept laid the foundation for the construction of functional devices such as optical/electrical switches, memory, and photodetectors.The semiconductor/dielectric interface is another important interface in FETs, that governs carrier transport (Figure 1d, left), because generation, transport, and regulation of charge carriers all occur in the first few layers (<10 nm) of semiconductors at the interface (Figure 1d, middle). In addition, the modification of the dielectric surface has been shown to help reduce the defects, improve the roughness, change the polarity, and modulate the surface hydrophilic/hydrophobic properties. These changes further affect the transport of carriers at the semiconductor/dielectric interface (Figure 1d, right) and have a significant impact on the morphology of the semiconductor layer. Furthermore, modification of the interface with SAMs or stimuli-responsive layers offers an important and general methodology to improve device performance and even integrate new molecular functionalities, such as photocontrollable memory, superconductivity, and charge-trap memory, into organic electrical circuits. Optoelectronic devices and interfaces therein have captured great attention in both scientific and industrial communities because of the wide variety of their unique properties. From a materials chemistry point of view, each layer and individual component of an optoelectronic device possesses the possibility of flexible chemical modification, making it feasible to dope, mix, and physically/chemically modify the interface. Exploiting the novel properties in optoelectronic devices with diverse la...

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Section: Ternary Interfaces In Hybrid Devicesmentioning

confidence: 99%

Section: Ternary Interfaces In Hybrid Devicesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Precise Control of Interfacial Charge Transport for Building Functional Optoelectronic Devices

Zhang

Chen

Guo

2019

Adv Materials Technologies

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“…[20,42] With photoexcitation by a 532 nm pulse laser, the transient photovoltage spectrum of the Z907/SLG/TiO 2 photovoltaic device was monitored by an oscilloscope. [43] As shown in Figure 3b …”

Section: Wwwadvelectronicmatdementioning

confidence: 99%

“…[16][17][18][19] Recently, we discovered an ipsilateral selective electron tunneling (ISET) mechanism, which can be used to effectively separate photoinduced electron-hole pair at the heterointerface. [20,21] Specifically, when photoactive materials are assembled on the outside surface of single-layer graphene (SLG)/TiO 2 , Schottky diode, photoexcited electrons, as well as holes produced from the photoactive materials transport along the same direction to SLG, whereas only electron can further inject into the TiO 2 layer, thus realizing photogenerated electron-hole pair separation at the Schottky interface. With acridine orange (AO) dye as a model photoactive material, ≈86.8% photocarriers separation/collection efficiency was realized at the AO/SLG/ TiO 2 interface.…”

mentioning

confidence: 99%

High‐Efficiency Photovoltaic Conversion at Selective Electron Tunneling Heterointerfaces

Jia

Guan

et al. 2017

Adv Elect Materials

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particular, highly efficient photogenerated electron-hole pair separation, transport, and collection at the heterointerface are the key to achieve high photon-to-current conversion efficiency for photovoltaic devices. [12][13][14][15] Therefore, interface engineering was widely applied to control the photoinduced charge transport processes at the heterointerface for improving the performance of photovoltaic devices. [16][17][18][19] Recently, we discovered an ipsilateral selective electron tunneling (ISET) mechanism, which can be used to effectively separate photoinduced electron-hole pair at the heterointerface. [20,21] Specifically, when photoactive materials are assembled on the outside surface of single-layer graphene (SLG)/TiO 2 , Schottky diode, photoexcited electrons, as well as holes produced from the photoactive materials transport along the same direction to SLG, whereas only electron can further inject into the TiO 2 layer, thus realizing photogenerated electron-hole pair separation at the Schottky interface. With acridine orange (AO) dye as a model photoactive material, ≈86.8% photocarriers separation/collection efficiency was realized at the AO/SLG/ TiO 2 interface. Therefore, such an ISET effect at the heterointerface has great potential to be applied for efficient photovoltaic conversion.Due to a highly photoactive and unique amphiphilic structure, Z907 ruthenium molecules were widely used as the dye sensitizer in all-solid-state dye-sensitized solar cells. [22] In this work, Z907 molecules were chosen as the photoactive material to construct a Z907/SLG/TiO 2 ternary interface. As shown in Figure 1a, the photoexcited electrons in Z907 molecules are expected to tunnel across SLG and ballistically inject into the conductance band (CB) of the TiO 2 semiconductor layer, while photoexcited holes in Z907 molecules can only transport to the SLG semimetal layer. After that, the electron and hole are collected by the TiO 2 layer and the SLG layer, respectively, and further transport to the outside circuit for photoelectric conversion. Based on such an ISET mechanism, the electron transparency of the graphene layer is crucial for the high-efficiency photovoltaic conversion in ISET-based photovoltaic devices. Considering the fact that the electron transparency decreases with increasing the thickness of graphene, [23] single-layer graphene was chosen to construct the ISET-based heterointerface. With such an ISET-based heterointerface, we investigated the photoinduced carrier dynamic processes and photoelectric conversion performances at the heterointerface.Effectively controlling photoinduced charge transport at the heterointerface is of crucial importance for improving the performance of photovoltaic devices. On the basis of an ipsilateral selective electron tunneling (ISET) mechanism, here this study investigates photoinduced charge transport and photovoltaic conversion at a simplified dye/single-layer graphene (SLG)/TiO 2 ternary interface. With an amphiphilic Z907 molecule as the model dye, the photoexcit...

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A general analytical method for finding the quantum capacitance of graphene

Selvaggi

2018

J Comput Electron

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High-Efficiency Selective Electron Tunnelling in a Heterostructure Photovoltaic Diode

Cited by 14 publications

References 31 publications

Precise Control of Interfacial Charge Transport for Building Functional Optoelectronic Devices

Precise Control of Interfacial Charge Transport for Building Functional Optoelectronic Devices

High‐Efficiency Photovoltaic Conversion at Selective Electron Tunneling Heterointerfaces

A general analytical method for finding the quantum capacitance of graphene

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