Long‐Term, High‐Voltage, and High‐Temperature Stable Dual‐Mode, Low Dark Current Broadband Ultraviolet Photodetector Based on Solution‐Cast r‐GO on MBE‐Grown Highly Resistive GaN

Prakash, Nisha; Kumar, Gaurav; Singh, Manjri; Singh, Surinder P.; Satpati, Biswarup; Khanna, Suraj P.; Pal, Prabir

doi:10.1002/adom.201900340

Cited by 21 publications

(13 citation statements)

References 41 publications

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“…Remarkably, by fitting the photocurrent densities and light intensities, a linear relationship could be obtained, as shown in Figure 3b, suggesting that the device has a great linear response to UV light. To assess the capability of a PD responding to and detecting an optical signal from an atmospheric environment, the responsivity (R λ ) and detectivity (D*) were calculated using the following equations: 42,43…”

Section: Resultsmentioning

confidence: 99%

“…Remarkably, by fitting the photocurrent densities and light intensities, a linear relationship could be obtained, as shown in Figure b, suggesting that the device has a great linear response to UV light. To assess the capability of a PD responding to and detecting an optical signal from an atmospheric environment, the responsivity ( R λ ) and detectivity ( D *) were calculated using the following equations: , where P , S , e , and I dark represent the light intensity, effective illumination area, elementary charge, and dark current density, respectively. The calculated light-intensity-dependent R λ and D * are plotted in Figure c.…”

Section: Resultsmentioning

confidence: 99%

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Ordered GaN Nanorod Arrays for Self-Powered Photoelectrochemical Ultraviolet Photodetectors

Chen

Zhang

Shao

et al. 2022

ACS Appl. Nano Mater.

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Self-powered ultraviolet (UV) photodetectors have great application prospects in the fields of UV astronomy, environmental monitoring, and space communication. In particular, the emerging photoelectrochemical photodetectors (PEC PDs) without external bias, high sensitivity, and environmental sensitivity have attracted extensive attention. Herein, self-powered PEC PDs were designed and constructed by using highly ordered GaN nanorod arrays (NRAs) as photoelectrodes. Without external bias, PEC PDs with NRA structures exhibit a high peak responsivity of 6.04 mA/W and a detectivity of 5.14 × 1010 Jones, which are 12 and 5.1 times higher, respectively, than those of the planar device. The large solid–liquid interface of the nanorod structure will lead to an improved built-in electrical field to promote carrier collection and rapid directional transmission, which can enhance the generation and separation of photogenerated carriers. Moreover, an optimized nanoarray will increase the UV detection effect significantly, which provides instruction for the design and fabrication of high-performance self-powered PEC PDs in the future.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Ordered GaN Nanorod Arrays for Self-Powered Photoelectrochemical Ultraviolet Photodetectors

Chen

Zhang

Shao

et al. 2022

ACS Appl. Nano Mater.

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“…The decrease in the distribution of the interface state density at the In 2 O 3 /InN NRs interface would be beneficial for the enhancement of charge carrier separation and extraction in In 2 O 3 /InN core–shell NRs. Apparently, the I – V results of In 2 O 3 /InN NRs and pristine InN are different, and Termann’s method is widely reported for the interface states density evolution in semiconductor device physics …”

Section: Results and Discussionmentioning

confidence: 99%

Photovoltaic Photodetectors Based on In₂O₃/InN Core–Shell Nanorods

Reddeppa

Park

Nam

et al. 2022

ACS Appl. Nano Mater.

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Indium nitride (InN)-based nanostructures have attracted substantial interest in the development of next-generation nanostructured optoelectronic devices. By expanding the light absorption range, the concept of heterostructures is of paramount significance in optoelectronics. Herein, we report a self-powered photodetector using In2O3/InN core–shell nanorods (NRs). InN NRs were grown using molecular beam epitaxy, and a radial In2O3/InN core–shell NR heterojunction with an In2O3 polycrystalline sheath layer was fabricated using hydrogen plasma treatment. The temperature-dependent current–voltage characteristics exhibit nonideal behavior, and the interface states cause deviation in barrier heights (BHs). The calculated BHs for InN and In2O3/InN core–shell heterostructure are estimated to be 0.47 and 0.62 eV, respectively. The In2O3/InN core–shell heterostructure achieved the highest photosensitivity and detectivity values of 3.22 A/W and 1.07 × 1011 Jones under λ = 465 nm (0.64 mW/cm2), respectively, in the self-power mode. This figure of merit is retained in 382–465 nm spectral regions. The maximum responsivity noticed at 465 nm is believed to be the intermediate oxygen defect energy levels within the forbidden gap of In2O3. The high performance was also attributed to the passivation of the InN NR surfaces by In2O3. The study would be beneficial for the development of solar-blind photodetectors.

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“…The most important criterion in the selection of materials for high-performance photodetector (PD) is the exhibited photocarrier lifetime that should be long enough so the photocarriers can diffuse and drift to the respective electrodes before recombining. This has led to the integration of the suitable mixed dimensional materials to form hybrid heterojunction devices in order to achieve high performance. , The layered 2D material can be integrated with various dimensionalities to form mixed-dimensional heterojunction, such as 0D/2D, , 1D/2D, , 2D/2D, and 2D/3D − reported earlier for high-performance heterojunction devices. Among them, the amalgamation of 2D layered materials and conventional 3D semiconductors is the most exciting scheme because of stronger light matter interaction and easy integration with the established 3D semiconductor materials technology. − For such cases of 2D/3D devices, the top 2D layered material enhances the light-matter interaction through strong light absorption; in addition, the physical separation between the electrons and holes by the interfacial barrier of the heterojunction leads to prompt transportation of carriers.…”

Section: Introductionmentioning

confidence: 99%

“…Although r-GO provides the ease of forming efficient large-area devices using simple solution process techniques as compared to Graphene, little attention has been paid so far. Only few reports exploring the r-GO/GaN junction are available until date. ,− Prakash et al. demonstrated the use of r-GO as transparent electrodes to achieve fast response and recovery speed in GaN UV PD .…”

Section: Introductionmentioning

confidence: 99%

Solution-Processed-2D on 3D Heterojunction UV–Visible Photodetector for Low-Light Applications

Kumar

Prakash

Singh

et al. 2019

ACS Appl. Electron. Mater.

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We have demonstrated a heterojunction photodetector (PD) based on reduced graphene oxide (r-GO) and metal−organic chemical vapor deposition (MOCVD)-grown gallium nitride (GaN) that can sense very low light intensities in the above-band-gap and below-band-gap regimes, showing no and high photoconductive gains, respectively. The current− voltage characteristics of the device transforms from quasi photoconductive to photodiode behavior once the illumination wavelength is in the below-band-gap regime. The device exhibits a very low dark current of 0.85 pA at zero bias. In the selfpowered mode with low-light conditions (∼0.38 μW/cm 2 ) at 360 nm illumination, the light-to-dark current (I Light /I Dark ) ratio, responsivity (R λ ), specific detectivity (D*), and external quantum efficiency (EQE) of the fabricated PD were calculated to be ∼1 × 10 4 , 0.22 A/W, 1.486 × 10 14 Jones (cm Hz 1/2 W −1 ), and 77%, respectively. The response and recovery time of the PD were typically 485 and 886 μs, respectively under 280 Hz light switching frequency at zero bias. The device also shows significant photoconductive response with a typical persistent photoconductivity behavior at an applied bias of 5 V with extremely large I Light /I Dark ratio of ∼10 7 at 360 nm (∼0.15 mW/cm 2 ). The R λ , D*, and EQE were found to be 529 A/W, 4.25 × 10 16 Jones, and ∼2 × 10 5 %, respectively, for 360 nm illumination under low-light conditions (∼0.38 μW/cm 2 ), at 5 V applied bias. The extraordinary performance of the device in both photovoltaic and photoconductive modes makes r-GO/GaN heterojunction scheme suitable for dual-mode low-light UV−visible applications.

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Long‐Term, High‐Voltage, and High‐Temperature Stable Dual‐Mode, Low Dark Current Broadband Ultraviolet Photodetector Based on Solution‐Cast r‐GO on MBE‐Grown Highly Resistive GaN

Cited by 21 publications

References 41 publications

Ordered GaN Nanorod Arrays for Self-Powered Photoelectrochemical Ultraviolet Photodetectors

Ordered GaN Nanorod Arrays for Self-Powered Photoelectrochemical Ultraviolet Photodetectors

Photovoltaic Photodetectors Based on In₂O₃/InN Core–Shell Nanorods

Solution-Processed-2D on 3D Heterojunction UV–Visible Photodetector for Low-Light Applications

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Long‐Term, High‐Voltage, and High‐Temperature Stable Dual‐Mode, Low Dark Current Broadband Ultraviolet Photodetector Based on Solution‐Cast r‐GO on MBE‐Grown Highly Resistive GaN

Cited by 21 publications

References 41 publications

Ordered GaN Nanorod Arrays for Self-Powered Photoelectrochemical Ultraviolet Photodetectors

Ordered GaN Nanorod Arrays for Self-Powered Photoelectrochemical Ultraviolet Photodetectors

Photovoltaic Photodetectors Based on In2O3/InN Core–Shell Nanorods

Solution-Processed-2D on 3D Heterojunction UV–Visible Photodetector for Low-Light Applications

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Photovoltaic Photodetectors Based on In₂O₃/InN Core–Shell Nanorods