Now showing 1 - 10 of 24
  • Publication
    Strategic Review of Organic–Inorganic Perovskite Photodetectors
    (2024)
    Neeraj Goel
    ;
    Aditya Kushwaha
    ;
    Monika Kwoka
    ;
    Metal halide perovskites have aroused worldwide efforts for developing optoelectronic devices due to their unique optical properties and low-cost simple fabrication process. In recent years, various perovskites-based miniaturized optical devices have been actively investigated due to their record-breaking efficiency in different fields, including environmental monitoring, remote sensing, biomedical imaging, and optical communications. In this review, a succinct and critical survey of recently discovered organic–inorganic perovskite photodetectors providing insights into their structural properties and key performance parameters is staged. First, key features of perovskites-based photodetectors emphasizing their optoelectronic and electrical properties are introduced. Then, the polarization-sensitive detection of metal halide perovskites using polarization-selective optical structures is discussed. The bandgap engineering for tailoring the properties of perovskite photodetectors by changing the chemical composition and material structures is also highlighted in this report. Finally, a perspective on future opportunities and current challenges for designing perovskite-based optoelectronic devices is presented.
  • Publication
    High performance Pt-anchored MoS2 based chemiresistive ascorbic acid sensor
    (2024)
    Arpita Biswas
    ;
    Ashok Kumar
    ;
    ;
    Monika Kwoka
    ;
    Gaurav Bassi
    ;
    Mukesh Kumar
    ;
    Ascorbic acid (AA), known as vitamin C, is a vital bioactive compound that plays a crucial role in several metabolic processes, including the synthesis of collagen and neurotransmitters, the removal of harmful free radicals, and the uptake of iron by cells in the human intestines. As a result, there is an absolute need for a highly selective, sensitive, and economically viable sensing platform for AA detection. Herein, we demonstrate a Pt-decorated MoS2 for efficient detection of an AA biosensor. MoS2 hollow rectangular structures were synthesized using an easy and inexpensive chemical vapor deposition approach to meet the increasing need for a reliable detection platform. The synthesized MoS2 hollow rectangular structures are characterized through field effect scanning electron microscopy (FESEM), energy-dispersive spectroscopy elemental mapping, Raman spectroscopy, and x-ray photoelectron spectroscopy. We fabricate a chemiresistive biosensor based on Pt-decorated MoS2 that measures AA with great precision and high sensitivity. The experiments were designed to evaluate the response of the Pt-decorated MoS2 biosensor in the presence and absence of AA, and selectivity was evaluated for a variety of biomolecules, and it was observed to be very selective towards AA. The Pt-MoS2 device had a higher response of 125% against 1 mM concentration of AA biomolecules, when compared to that of all other devices and 2.2 times higher than that of the pristine MoS2 device. The outcomes of this study demonstrate the efficacy of Pt-decorated MoS2 as a promising material for AA detection. This research contributes to the ongoing efforts to enhance our capabilities in monitoring and detecting AA, fostering advancements in environmental, biomedical, and industrial applications.
  • Publication
    High-Performance Photodetector from p-n Junction of Vertically Aligned SnS2 and Reduced Graphene Oxide
    (2024)
    Chayan Das
    ;
    Suresh Kumar
    ;
    Neha V. Dambhare
    ;
    ;
    Arup K. Rath
    ;
    Semiconducting 2D transition metal dichalcogenides (TMDC) became very popular in photodetection due to their high mobility and high rate of generating electron and hole pairs. Over the past decade, MoS2 and WS2 became the most popular TMDC for several applications. On the other hand, due to the complex synthesis process compared to MoS2 and WS2, SnS2 became a less popular 2D material for photodetection. We synthesized vertically aligned SnS2 flakes by a chemical vapor deposition (CVD) process with three temperature zones with controlled argon (Ar) gas flow. Pristine SnS2-based devices are not very suitable for photodetection applications because of their low photo-to-dark current ratio (Iph/Idark), high response time, and low stability. So, they need to be decorated with oppositely doped materials. We decorated pristine SnS2-based devices with rGO nanoparticles, which significantly increased the device’s performance. We found a high responsivity (R) of 1.33 A/W, detectivity (D) of 6.95 × 1011 Jones, Iph/Idark of 102, and a rise time of 0.241 ms (fall time of 1.318 ms) with the rGO decorated SnS2-based device.
  • Publication
    High-Performance Photodetector from p-n Junction of Vertically Aligned SnS2 and Reduced Graphene Oxide
    (2024)
    Chayan Das
    ;
    Suresh Kumar
    ;
    Neha V. Dambhare
    ;
    ;
    Arup K. Rath
    ;
    Semiconducting 2D transition metal dichalcogenides (TMDC) became very popular in photodetection due to their high mobility and high rate of generating electron and hole pairs. Over the past decade, MoS2 and WS2 became the most popular TMDC for several applications. On the other hand, due to the complex synthesis process compared to MoS2 and WS2, SnS2 became a less popular 2D material for photodetection. We synthesized vertically aligned SnS2 flakes by a chemical vapor deposition (CVD) process with three temperature zones with controlled argon (Ar) gas flow. Pristine SnS2-based devices are not very suitable for photodetection applications because of their low photo-to-dark current ratio (Iph/Idark), high response time, and low stability. So, they need to be decorated with oppositely doped materials. We decorated pristine SnS2-based devices with rGO nanoparticles, which significantly increased the device’s performance. We found a high responsivity (R) of 1.33 A/W, detectivity (D) of 6.95 × 1011 Jones, Iph/Idark of 102, and a rise time of 0.241 ms (fall time of 1.318 ms) with the rGO decorated SnS2-based device.
  • Publication
    Bioinspired AlFeO3 Memristor with Sensing, Storage, and Synaptic Functionalities
    (2024)
    Mubashir Mushtaq Ganaie
    ;
    ;
    Amit K. Shringi
    ;
    ;
    Michael Saliba
    ;
    In conventional designs, sensory systems are segregated from memory and computing units. The conversion and transmission of data from analog sensing domains to digital storage result in inefficient power utilization and increased latency. Here, a multifunctional memristor capable of detecting gamma radiation while also serving as a data storage device and an artificial synapse is reported. Large-scale integration of oxide-based memristors for artificial neural networks faces major challenges due to the sneak-path current issue in crossbar arrays. Consequently, material combinations and fabrication variables significantly shape nanoscale processes, which are essential in determining resistive switching properties and functionalities. Resistive switching in AlFeO3 is studied using different electrode materials (silver (Ag), gold (Au), chromium (Cr), fluorine-doped tin oxide, and silicon), embedding metal (Ag, Au) nanocrystals to engineer a class of tunable memories capable of functioning as selector, memory, artificial synapse, and dosimeter. Techniques like electrode engineering, nanocrystal seeding, and temperature-dependent thin film deposition are employed to tune resistive and threshold switching functionalities. Accessing different functionalities requires changing the electrode materials or changing the synthesis conditions of the AlFeO3 resistive switching layer and are not interconvertible in the same device simultaneously. The devices emulate critical neural functions and demonstrate interconversion dynamics between short-term and long-term plasticity.
  • Publication
    Boosting acetone response of p-type Co3O4 sensor via Sn and Ni co-doping for diabetes diagnosis
    (2024)
    Xiaohua Ji
    ;
    Junqing Chang
    ;
    Zanhong Deng
    ;
    Chengyin Shen
    ;
    Meng Li
    ;
    Shimao Wang
    ;
    Libing You
    ;
    ;
    Xiaodong Fang
    ;
    Gang Meng
    The hole accumulation layer (HAL) configuration of p-type oxides (including Co3O4) in ambient air causes intrinsically low gas response and hinders their promising applications in exhaled gas analysis. Herein, Sn and Ni co-doping has been proposed to trigger the response of chemiresistive Co3O4 sensor toward acetone (biomarker of diabetes). Via incorporating 1 at% Sn and 0.5 at% Ni doping (Co2.95Sn0.03Ni0.02O4), the response to 100 ppm acetone has been boosted ∼2 orders (from 1.24 to 125.6) at 70 °C, the limit of detection (LoD) has been reduced ∼4 times (from 47.9 to 12.4 ppb), the optimal operation temperature has been decreased from 130 °C to ∼70 °C. Various characterizations suggest that co-doping induced abundant surface asymmetric oxygen vacancy defects (Co-□-Ni, Sn-□-Ni), which facilitate the catalytic oxidation of acetone molecules at relatively low operation temperature. In addition to excellent reproducibility and long-term stability, Co2.95Sn0.03Ni0.02O4 sensor could also operate under highly humid air background and reliably detect acetone concentration in exhaled breath at 150 °C, opening the opportunity for the practical application of p-type oxide sensors for diabetes diagnosis.
  • Publication
    Design of a Humidity Sensor for a PPE Kit Using a Flexible Paper Substrate
    (2024)
    Priyanka Chaudhary
    ;
    Arpit Verma
    ;
    Sandeep Chaudhary
    ;
    ;
    Meng-Fang Lin
    ;
    Yu-Ching Huang
    ;
    Kuen-Lin Chen
    ;
    B.C. Yadav
    The present work reports the rapid sweat detection inside a PPE kit using a flexible humidity sensor based on hydrothermally synthesized ZnO (zinc oxide) nanoflowers (ZNFs). Physical characterization of ZNFs was done using scanning electron microscopy (SEM), X-ray diffraction (XRD), Fourier transmission infrared spectroscopy (FTIR), UV-visible, particle size analysis, Raman analysis, and X-ray photoelectron spectroscopy (XPS) analysis, and the hydrophilicity was investigated by using contact angle measurement. Fabrication of a flexible sensor was done by deposition on the paper substrate using the spin coating technique. It exhibited high sensitivity and low response and recovery times in the humidity range 10-95%RH. The sensor demonstrated the highest sensitivity of 296.70 nF/%RH within the humidity range 55-95%RH, and the rapid response and recovery times were also calculated and found as 5.10/1.70 s, respectively. The selectivity of the proposed sensor was also analyzed, and it is highly sensitive to humidity. The humidity sensing characteristics were theoretically witnessed in terms of the highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO) and electronic properties of sensing materials in ambient and humid conditions. These theoretical results are evidence of the interaction of ZnO with humidity. Overall, the present study provides a scope of architecture-enabled paper-based humidity sensors for the detection of sweat levels inside PPE kits for health workers.
  • Publication
    Effect of Noble Metal on CuO/SnO2 Heterostructures Thin Films for H2S Gas
    (2024)
    Kumar, Amit
    ;
    Suraj Barala
    ;
    Hydrogen sulfide (H2S) is recognized as a toxic gas, renowned for its capacity to inflict significant harm upon the respiratory and nervous systems. Consequently, the development of high-performance H2S sensors holds significant importance. However, traditional fabrication methods such as brush painting and drop casting often yield sensors with inconsistent batch responses due to the unpredictable film formation process, hindering their mass industrial production. Here, we have devised a novel approach to fabricate highly sensitive and selective H2S sensors utilizing Pd-anchored CuO/SnO2 heterostructures thin films. An investigation was conducted to analyze the impact of different noble metals (Pt, Au, Ag, and Pd) on CuO/SnO2 heterostructure thin films concerning their response to H2S. These films were synthesized through RF sputtering and subsequently decorated with varying durations of CuO (15, 30, 45, 60, and 75 s) and Pd nanoparticles (Nps) (3, 6, 9, and 12 s) using a sputtering process. Notably, a sputtering time of 60 s for CuO and 9 s for Pd significantly enhanced the H2S sensing performance and selectivity over other gases. The Pd-anchored CuO/SnO2 thin films revealed an exceptional result of 75.45% to 100 ppm H2S, demonstrating a detection capability down to 0.5 ppm. These noteworthy outcomes were attained under optimal operating conditions at a temperature of 150 °C. This innovative fabrication technique holds promise for the advancement of gas sensor technology, enabling the creation of portable sensor prototypes suitable for real-time sensing applications.
  • Publication
    High energy density picoliter-scale zinc-air microbatteries for colloidal robotics
    (2024)
    Ge Zhang
    ;
    Sungyun Yang
    ;
    Jing Fan Yang
    ;
    David Gonzalez-Medrano
    ;
    Marc Z. Miskin
    ;
    Volodymyr B. Koman
    ;
    Yuwen Zeng
    ;
    Sylvia Xin Li
    ;
    Matthias Kuehne
    ;
    Albert Tianxiang Liu
    ;
    Allan M. Brooks
    ;
    ;
    Michael S. Strano
    The recent interest in microscopic autonomous systems, including microrobots, colloidal state machines, and smart dust, has created a need for microscale energy storage and harvesting. However, macroscopic materials for energy storage have noted incompatibilities with microfabrication techniques, creating substantial challenges to realizing microscale energy systems. Here, we photolithographically patterned a microscale zinc/platinum/SU-8 system to generate the highest energy density microbattery at the picoliter (10−12 liter) scale. The device scavenges ambient or solution-dissolved oxygen for a zinc oxidation reaction, achieving an energy density ranging from 760 to 1070 watt-hours per liter at scales below 100 micrometers lateral and 2 micrometers thickness in size. The parallel nature of photolithography processes allows 10,000 devices per wafer to be released into solution as colloids with energy stored on board. Within a volume of only 2 picoliters each, these primary microbatteries can deliver open circuit voltages of 1.05 ± 0.12 volts, with total energies ranging from 5.5 ± 0.3 to 7.7 ± 1.0 micro-joules and a maximum power near 2.7 nanowatts. We demonstrated that such systems can reliably power a micrometer-sized memristor circuit, providing access to nonvolatile memory. We also cycled power to drive the reversible bending of microscale bimorph actuators at 0.05 hertz for mechanical functions of colloidal robots. Additional capabilities, such as powering two distinct nanosensor types and a clock circuit, were also demonstrated. The high energy density, low volume, and simple configuration promise the mass fabrication and adoption of such picoliter zinc-air batteries for micrometer-scale, colloidal robotics with autonomous functions.
  • Publication
    Resistance-driven low power H2S sensors based on MWCNT@CuO heterojunction
    (2024)
    Sumit Kumar
    ;
    Rahul Mitra
    ;
    Suraj Barala
    ;
    Ashok Kumar
    ;
    Monika Kwoka
    ;
    Krishnau Biswas
    ;
    Low power, high sensitivity, and selectivity chemiresistive gas sensors are in urgent demand for hydrogen sulfide (H2S) detection to protect human health and the world's ecosystem. In this study, multiwalled carbon nanotubes (MWCNTs) and copper oxide (CuO) submicrometer size particles’ compositions were utilized to fabricate low-temperature H2S gas sensors, which were prepared using a screen-printing technique on inter-digited patterned SiO2/Si substrates. The heterostructure of MWCNT@CuO was confirmed through high-resolution transmission electron microscopy analysis and x-ray diffraction patterns. The x-ray photoelectron spectroscopy analysis reveals the chemical states, binding energies, and oxygen vacancy (Ov). Brunauer-Emmett-Teller analysis of nitrogen physisorption analysis was conducted on the samples to analyze sensor surface areas and pore size distribution. The as-fabricated MWCNT@CuO sensor shows a relative response (ΔR/R%) of 73% toward 10 ppm H2S at 50 °C temperature in a selective manner, which is 1.6 times higher than that of devices based on bare CuO. The MWCNT@CuO interface modifies the morphology and also constructs a p-p heterojunction. This leads to the reforming of the band structure and results in a low resistance of the matrix, as well as a high chemisorbed oxygen content. The use of metal oxide semiconductors with MWCNTs offers a promising approach for the development of high-performance gas sensors that are energy-efficient.