56 results on '"Biji Pullithadathil"'
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2. Integrated co-axial electrospinning for a single-step production of 1D aligned bimetallic carbon fibers@AuNPs–PtNPs/NiNPs–PtNPs towards H2 detection
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Keerthi G. Nair, Ramakrishnan Vishnuraj, and Biji Pullithadathil
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Nanostructure ,Materials science ,Hydrogen ,Carbon nanofiber ,Nanoparticle ,chemistry.chemical_element ,Electrospinning ,Adsorption ,chemistry ,Chemical engineering ,Chemistry (miscellaneous) ,Nanofiber ,General Materials Science ,Bimetallic strip - Abstract
One dimensional (1D) nanostructure like nanorods, nanowires, nanotubes and nanofibers have aroused great attention owing to their exceptional properties like high surface-to-volume ratio, excellent electron and thermal transport and also plays as interconnects during fabricating nanoscale devices. In this work, one dimensionally aligned Carbon nanofibers(CFs)@AuNPs-PtNPs/NiNPs-PtNPs have been developed via a single step co-axial electrospinning integrated with in-situ photo-reduction. The carbon nanofibers with in-situ functionalized bimetallic nanoparticles possessed well-defined core-shell structure with carbon nanofibers (CFs) as the core and AuNPs-PtNPs/NiNPs-PtNPs as the surface anchored heterojunctions. Homogeneously distributed AuNPs-PtNPs/Ni NPs-Pt NPs, which are identified as chemical sensitizers, triggers the dissociation of H2 through the spill-over effect, by successive diffusion of these H+ on carbon nanofiber surface, thereby altering the entire surface of the CFs into reaction sites for H2. Aligned core-shell CFs@Ni NPs-PtNPs possessed high sensitivity of 124% (v/v) at room temperature as compared with aligned core-shell CFs@PtNPs NPs (52%) and aligned core-shell CFs@AuNPs-PtNPs (65%), which may be due to the high catalytic adsorption and desorption properties of Ni and Pt towards hydrogen gas. Moreover, co-axially aligned CFs@NiNPs-PtNPs based sensor also demonstrates outstanding selectivity towards hydrogen compared to other gases like ammonia, ethanol, hydrogen sulphide, and acetone with excellent long-term stability. In addition, hydrogen adsorption kinetics of co-axially aligned CFs@NiNPs-PtNPs based sensor was verified theoretically the adsorption rate constant of (0.42) which showed a comparable experimental value (0.38) of adsorption rate constant. The potential suitability of co-axially aligned CFs@NiNPs-PtNPs based sensor towards H2 at room temperature leading towards real time applications also have been demonstrated
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- 2022
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3. Realization of Micropatterned, Narrow Line-Width Ni–Cu–Sn Front Contact Grid Pattern Using Maskless Direct-Write Lithography for Industrial Silicon Solar Cells
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Ramakirshnan Vishnuraj, Mahaboobbatcha Aleem, Balachander Krishnan, and Biji Pullithadathil
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Materials science ,Silicon ,business.industry ,Energy Engineering and Power Technology ,chemistry.chemical_element ,Line width ,Grid pattern ,chemistry ,Materials Chemistry ,Electrochemistry ,Chemical Engineering (miscellaneous) ,Optoelectronics ,Electrical and Electronic Engineering ,business ,Realization (systems) ,Lithography ,Front (military) - Published
- 2021
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4. Bimetallic AuNi nanoparticles supported on mesoporous MgO as catalyst for Sonogashira-Hagihara cross-coupling reaction
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Mohammad Gholinejad, Faezeh Khosravi, José, M. Sansano, Ramakrishnan Vishnuraj, Biji Pullithadathil, Universidad de Alicante. Departamento de Química Orgánica, Universidad de Alicante. Instituto Universitario de Síntesis Orgánica, and Síntesis Asimétrica (SINTAS)
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Inorganic Chemistry ,MgO nanoflakes ,Nanocatalyst ,Sonogashira-Hagihara reaction ,Organic Chemistry ,Materials Chemistry ,Physical and Theoretical Chemistry ,Bimetallic AuNi ,Biochemistry - Abstract
Gold catalysts have been reported to be applied only for the Sonogashira-Hagihara reaction of iodobenzene and phenylacetylene under harsh reaction conditions, while the scope of the reaction has not been expanded for coupling reaction of other aryl halides and alkynes. In this investigation, a cost-effective, Pd-free catalyst based on mesoporous magnesium oxide supported bimetallic AuNi nanoparticles (m-MgO@AuNi) have been synthesized by hydrothermal method and its efficiency has been demonstrated in Sonogashira-Hagihara cross-coupling reaction. The m-MgO@AuNi nanocatalyst was structurally and morphologically characterized using X-ray Diffraction (XRD), Scanning Electron Microscopy (SEM), Transmission Electron Microscopy (TEM), X-ray Photoelectron Spectroscopy (XPS) and the mesoporous structure of MgO has been confirmed through BET analysis. Using this palladium-free catalyst, Sonogashira-Hagihara coupling reaction of aryl iodides and aryl bromides with alkynes have been successfully performed and catalyst was recycled for several times. The results demonstrate that the synergistic effect between Au, Ni and mesoporous MgO support plays key role in enhancement of m-MgO@AuNi catalytic activity in Sonogashira-Hagihara reaction. Iran National Science Foundation (INSF-Grant number of 99023403), Ministerio de Ciencia, Innovación y Universidades (RED2018-102387-T, PID2019-107268GB-100), FEDER, the Generalitat Valenciana (IDIFEDER/2021/013), and the University of Alicante.
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- 2023
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5. Highly Sensitive, Flexible H2 Gas Sensors Based on Less Platinum Bimetallic Ni–Pt Nanocatalyst-Functionalized Carbon Nanofibers
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Biji Pullithadathil, Keerthi G. Nair, and Ramakrishnan Vishnuraj
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Materials science ,chemistry ,Carbon nanofiber ,Materials Chemistry ,Electrochemistry ,chemistry.chemical_element ,Nanotechnology ,Platinum ,Bimetallic strip ,Hydrogen sensor ,Electrospinning ,Electronic, Optical and Magnetic Materials ,Highly sensitive - Abstract
Flexible electronic gas sensors working at room temperature have acquired enormous attention in recent years due to their suitability to be integrated into various wearable electronic products. In ...
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- 2021
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6. MEMS-compatible, gold nanoisland anchored 1D aligned ZnO heterojunction nanofibers: unveiling the NO2 sensing mechanism with operando photoluminescence studies
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Biji Pullithadathil, Mahaboobbatcha Aleem, Keerthi G. Nair, Ramakrishnan Vishnuraj, and Jayaseelan Dhakshinamoorthy
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Microelectromechanical systems ,Materials science ,Photoluminescence ,Fabrication ,Heterojunction ,Nanotechnology ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,Nanomaterials ,Chemistry (miscellaneous) ,Nanofiber ,General Materials Science ,Electrical measurements ,0210 nano-technology ,Plasmon - Abstract
Production and alignment of heterojunction metal oxide semiconductor nanomaterial-based sensing elements for microsensor devices have always posed fabrication challenges since they involve multi-step synthesis processes. Herein, we demonstrate a coaxial electrospinning with an in situ photoreduction process for the fabrication of MEMS-compatible, 1D aligned gold nanoisland (GNI) anchored ZnO-based Heterojunction Nanofibers (HNFs) and their complex plasmon-mediated NO2 gas sensing mechanism has been investigated using operando photoluminescence studies. Evaluation of the gas sensing properties of aligned ZnO-GNI HNFs has exhibited excellent sensor response (196%) with rapid response time towards 500 ppb NO2 gas at reduced operating temperature (200 °C). Operando studies using photoluminescence and electrical measurements ascertained the existence of supplementary active sites in the multicrystalline nanofibers owing to the existence of Au nanograins over aligned ZnO nanofibers (NFs), thereby inducing a spill-over zone and aiding the charge transfer phenomenon. The operando PL studies also revealed the plasmonic effect of metallic Au and the role of zinc interstitial (Zni) defects and oxygen vacancies (V+o), which influence the charge transfer between ZnO and surface anchored Au nanoislands. This study revealed atomistic insights into the structural defects and charge transport properties of metal oxide semiconductor heterojunction materials, and the coaxial integration method of 1D aligned ZnO-GNI HNFs paves the way for unique strategies and the development of suitable MEMS based gas sensors for real-time applications.
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- 2021
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7. Unidirectional Langmuir–Blodgett-Mediated Alignment of Polyaniline-Functionalized Multiwalled Carbon Nanotubes for NH3 Gas Sensor Applications
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Sukhananazerin Abdulla and Biji Pullithadathil
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chemistry.chemical_compound ,Materials science ,Chemical engineering ,chemistry ,Polyaniline ,Electrochemistry ,General Materials Science ,Surfaces and Interfaces ,Condensed Matter Physics ,Multiwalled carbon ,Langmuir–Blodgett film ,Spectroscopy - Abstract
Herein, we report the formation of well-aligned ultrathin films of polyaniline-functionalized multiwalled carbon nanotubes (PANI@MWCNTs) with a high orientational order over a macroscopic area by L...
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- 2020
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8. Geometrically Controlled Au-Decorated ZnO Heterojunction Nanostructures for NO2 Detection
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Dinesh Veeran Ponnuvelu, Biji Pullithadathil, Mohammed Kamruddin, Jayaseelan Dhakshinamoorthy, Sandip Dhara, and Arun K. Prasad
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Materials science ,Nanostructure ,In situ raman spectroscopy ,Nanofiber ,General Materials Science ,Heterojunction ,Nanorod ,Nanotechnology - Abstract
A comparative analysis of NO2 gas sensing performances of geometry-controlled Au decorated ZnO heterojunction nanostructures (nanospheres, nanorods, ultra-long nanorods and nanofibers) has been dem...
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- 2020
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9. Evolution of Temperature-Driven Interfacial Wettability and Surface Energy Properties on Hierarchically Structured Porous Superhydrophobic Pseudoboehmite Thin Films
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Nimmi Singh, Shalini Halan Joghee, Ravi Kottan Renganayagalu, Biji Pullithadathil, Kamachi Mudali Uthandi, Peeyush Kumar, and Sanjeev Katti
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Nanostructure ,Materials science ,Pseudoboehmite ,Nanotechnology ,02 engineering and technology ,Surfaces and Interfaces ,010402 general chemistry ,021001 nanoscience & nanotechnology ,Condensed Matter Physics ,01 natural sciences ,Surface energy ,0104 chemical sciences ,chemistry.chemical_compound ,chemistry ,Electrochemistry ,General Materials Science ,Wetting ,Thin film ,0210 nano-technology ,Porosity ,Spectroscopy - Abstract
Interaction of water on heterogeneous nonwetting interfaces has fascinated researchers' attention for wider applications. Herein, we report the evolution of hierarchical micro-/nanostructures on superhydrophobic pseudoboehmite surfaces created from amorphous Al
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- 2020
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10. Unraveling Hydrogen Adsorption Kinetics of Bimetallic Au–Pt Nanoisland-Functionalized Carbon Nanofibers for Room-Temperature Gas Sensor Applications
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Karthikeyan K. Karuppanan, Vishnuraj Ramakrishnan, Biji Pullithadathil, Rajesh Unnathpadi, and Keerthi G. Nair
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Materials science ,Hydrogen ,Carbon nanofiber ,Kinetics ,chemistry.chemical_element ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,Electrospinning ,Hydrogen adsorption ,0104 chemical sciences ,Surfaces, Coatings and Films ,Electronic, Optical and Magnetic Materials ,General Energy ,chemistry ,Chemical engineering ,Transmission electron microscopy ,Chemical reduction ,Physical and Theoretical Chemistry ,0210 nano-technology ,Bimetallic strip - Abstract
Electrospun carbon nanofibers (CNF) with surface-anchored bimetallic gold–platinum nanoislands (CNFs@Au–Pt NIs) have been effectively developed by electrospinning and chemical reduction methods, an...
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- 2020
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11. Boosting the performance of NO2 gas sensors based on n–n type mesoporous ZnO@In2O3 heterojunction nanowires: in situ conducting probe atomic force microscopic elucidation of room temperature local electron transport
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Biji Pullithadathil, Mahaboobbatcha Aleem, Karthikeyan K. Karuppanan, and Ramakrishnan Vishnuraj
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Kelvin probe force microscope ,Materials science ,Spreading resistance profiling ,business.industry ,General Engineering ,Nanowire ,Dangling bond ,Bioengineering ,Heterojunction ,02 engineering and technology ,General Chemistry ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,Atomic and Molecular Physics, and Optics ,0104 chemical sciences ,Microscopy ,Optoelectronics ,General Materials Science ,Charge carrier ,0210 nano-technology ,business ,Electronic band structure - Abstract
Herein, n–n type one dimensional ZnO@In2O3 heterojunction nanowires have been developed and their local electron transport properties during trace-level NO2 gas sensing process have been probed at room-temperature using conducting probe atomic microscopy. Solvothermally synthesized 1D ZnO@In2O3 heterojunction nanowires have been characterized by various spectroscopic and microscopic techniques, which revealed the mesoporous structure indicating their enhanced sensing properties. The dangling bonds and fraction of metal ions to oxygen ions existing on the exposed crystal facets of the heterojunction nanowires have been visualized by employing crystallographic simulations with TEM analysis, which aided in forecasting the nature of surface adsorption of NO2 gas species. In situ electrical characteristics and Scanning Spreading Resistance Microscopic (SSRM) imaging of single ZnO@In2O3 heterojunction nanowires revealed the local charge transport properties in n–n type ZnO@In2O3 heterojunction nanowires. Moreover, the ZnO@In2O3 heterojunction nanowires based sensor exhibited excellent sensitivity (S = 274%), a fast response (4–6 s) and high selectivity towards trace-level concentration (500 ppb) of NO2 gas under ambient conditions with low power consumption. Spatially resolved surface potential (SP) variations in ZnO@In2O3 heterojunction nanowires have been visualized using in situ Scanning Kelvin Probe Force Microscopy (SKPM) under NO2 gas environment at room temperature, which was further correlated with its energy band structure. The work functions of the material evaluated by SKPM reveal considerable changes in the energy band structure owing to the local electron transport between ZnO and In2O3 at the heterojunctions upon exposure to NO2 gas indicating the charge carrier recombination. A plausible mechanism has been proposed based on the experimental evidences. The results suggest that new insights into complex sensing mechanisms deduced from the present investigation on n–n type MOS based heterojunction nanowires under ambient conditions can pave the way for the novel design and development of affordable and superior real-time gas sensors.
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- 2020
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12. Porous, n–p type ultra-long, ZnO@Bi2O3 heterojunction nanorods - based NO2 gas sensor: new insights towards charge transport characteristics
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Biji Pullithadathil, Vishnuraj Ramakrishnan, Jayaseelan Dhakshinamoorthy, Keerthi G. Nair, and K. R. Ravi
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Materials science ,Dangling bond ,Oxide ,General Physics and Astronomy ,Heterojunction ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,Crystal ,chemistry.chemical_compound ,Band bending ,Chemical engineering ,chemistry ,Transmission electron microscopy ,Charge carrier ,Nanorod ,Physical and Theoretical Chemistry ,0210 nano-technology - Abstract
Herein, porous 1D n–p type ultra-long ZnO@Bi2O3 heterojunction nanorods have been synthesized by a solvothermal method and their complex charge transport characteristics pertaining to NO2 gas sensing properties have been investigated. The porous structure of the ZnO@Bi2O3 heterojunction nanorods assisted in achieving superior sensing properties compared to pristine ZnO nanorods. Temperature-dependent in situ electrical studies of the porous heterojunction nanorods explored the unique electron transport properties under different environments, which revealed the accumulation/depletion of electrons and charge carrier recombination leading to band bending at the metal oxide heterojunctions. The formation of electron depletion layers at n-ZnO/p-Bi2O3 interfaces is believed to increase the adsorption of oxidizing gas, resulting in a fast response time (10–12 s) and 10 times higher sensitivity than that of the ZnO nanorod-based sensor towards 500 ppb NO2. To study the structure–property correlation of the ultra-long ZnO@Bi2O3 heterojunction nanorods-based sensor, a crystallographic model supported by transmission electron microscopy analysis was adopted to understand the NO2 gas adsorption properties on the surface. The crystallographic model helps to visualize the dangling bonds and the ratio of metal to oxygen ions present at the exposed crystal planes. The results suggest that porous, ultralong n–p type ZnO@Bi2O3 heterojunction nanorods could be a promising candidate for a high performance NO2 sensor for real time applications.
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- 2020
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13. Noninvasive biomarker sensors using surface-enhanced Raman spectroscopy
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Navami Sunil and Biji Pullithadathil
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- 2022
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14. Contributors
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M. Alonso Cotta, R. Anjana, K.S. Anju, A.S. Asha, P.A. Aswathy, Maneesh Chandran, A. Irzhak, M.K. Jayaraj, V. Koledov, T.K. Krishnapriya, P. Lega, P.S. Midhun, A.M.V. Mohan, P. Mymoona, Subha P.P., M.J. Priya, Biji Pullithadathil, K.K. Rajeev, J.V. Rival, K.J. Saji, V. Sampath, Manu Shaji, E.S. Shibu, Z. Song, A.M. Starvin, P.S. Subin, Navami Sunil, Shibi Thomas, and S. von Gratowski
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- 2022
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15. Bio-Inspired Multifunctional Superhydrophobic Coatings for Corrosion Resistance
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Shalini Halan Joghee, Navami Sunil, Gokul Selvaraj, Kamachi Mudali Uthandi, and Biji Pullithadathil
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- 2022
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16. List of contributors
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Ebrahim Afshari, Samuel Simon Araya, Seyed Ali Atyabi, Abha Bharti, P. Bujlo, J.C. Calderón Gómez, H. Chhina, Mojtaba Aghajani Delavar, Sangeetha Dharmalingam, K.L. Duncan, N. Dyantyi, Vijayakumar Elumalai, Byron D. Gates, Sakshi Gautam, Hadi Heidary, Patrick Hong, Nabi Jahantigh, Kui Jiao, Gurbinder Kaur, Vaidhegi Kugarajah, Na Li, Vincenzo Liso, L. Mekuto, Rameez Ahmad Mir, Mahbod Moein Jahromi, Rajalakshmi Natarajan, Reza Omrani, O.P. Pandey, Manoj Kumar Panthalingal, G. Pattrick, Pavithra Ponnusamy, Biji Pullithadathil, Natarajan Rajalakshmi, Sundararajan Ramakrishnan, Krishnan Ramya, Merissa Schneider-Coppolino, Piyush Sharma, A.K. Taylor, Junye Wang, Yun Wang, Lizhen Wu, Tanzila Younas, and Guobin Zhang
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- 2022
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17. Multidimensional nanoarchitectures of TiO2/Au nanofibers with O-doped C3N4 nanosheets for electrochemical detection of nitrofurazone
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Thangavelu Kokulnathan, Ramakrishnan Vishnuraj, Tzyy-Jiann Wang, and Biji Pullithadathil
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General Physics and Astronomy ,Surfaces and Interfaces ,General Chemistry ,Condensed Matter Physics ,Surfaces, Coatings and Films - Published
- 2022
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18. Tailored construction of one-dimensional TiO
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Thangavelu, Kokulnathan, Ramakrishnan, Vishnuraj, Shen-Ming, Chen, Biji, Pullithadathil, Faheem, Ahmed, P M Z, Hasan, Anwar L, Bilgrami, and Shalendra, Kumar
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Titanium ,Diphenylamine ,Nanofibers ,Metal Nanoparticles ,Electrochemical Techniques ,Gold ,Electrodes - Abstract
We report a one-dimensional titanium dioxide encapsulated with gold heterojunction nanofibers (TiO
- Published
- 2021
19. Highly Surface Active Phosphorus-Doped Onion-Like Carbon Nanostructures: Ultrasensitive, Fully Reversible, and Portable NH3 Gas Sensors
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Biji Pullithadathil, Appu Vengattoor Raghu, and Karthikeyan K. Karuppanan
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Carbon nanostructures ,Nanostructure ,Materials science ,Doping ,chemistry.chemical_element ,Phosphonate ,Oxygen ,Electronic, Optical and Magnetic Materials ,chemistry.chemical_compound ,Phosphorus doped ,Adsorption ,chemistry ,Chemical engineering ,Adsorption kinetics ,Materials Chemistry ,Electrochemistry - Abstract
Unique phosphorous doped onion-like carbon nanostructures (P-OLCs) with superior surface properties have been synthesized through a temperature and pressure controlled thermal decomposition method. The substitutional doping of phosphorous in OLCs nanostructures could facilitate the charge transfer during ammonia gas sensing. Presence of polar metaphosphates/phosphonate species in the active sites of highly crystalline P-OLCs due to interstitial doping of oxygen incorporated with substitutionally doped phosphorous atoms significantly enhanced the sensitivity with fast response and recovery characteristics (2.8 s and 4.5 s) towards NH3 at room temperature. Further, ammonia gas adsorption kinetics in OLCs and P-OLCs have been meticulously investigated which revealed the faster adsorption rate in P-OLCs (2.17 x 10-7 Ω-1s-1) compared to pristine OLCs (8.599 x 10-8 Ω-1s-1). This method can widely open up the feasibility to induce enhanced surface activity (phosphorus-containing groups allows the access of oxyge...
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- 2019
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20. Tailored Hollow Core/Mesoporous Shell Carbon Nanofibers as Highly Efficient and Durable Cathode Catalyst Supports for Polymer Electrolyte Fuel Cells
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Karthikeyan K. Karuppanan, Biji Pullithadathil, Manoj Kumar Panthalingal, and Appu Vengattoor Raghu
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Hollow core ,Materials science ,Chemical engineering ,Carbon nanofiber ,Electrochemistry ,Shell (structure) ,Fuel cells ,Polymer electrolyte fuel cells ,Mesoporous material ,Catalysis ,Oxygen reduction ,Cathode catalyst - Published
- 2019
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21. Wearable, Flexible Ethanol Gas Sensor Based on TiO2 Nanoparticles-Grafted 2D-Titanium Carbide Nanosheets
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Appu Vengattoor Raghu, Jayakrishnan Nampoothiri, Karthikeyan K. Karuppanan, and Biji Pullithadathil
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chemistry.chemical_compound ,Titanium carbide ,Materials science ,chemistry ,Surface reactivity ,Tio2 nanoparticles ,Titanium dioxide ,Wearable computer ,General Materials Science ,Nanotechnology ,Ethanol fuel ,Microstructure ,Homogeneous distribution - Abstract
Herein, we demonstrate a novel approach for development of TiO2 grafted 2D-TiC nanosheets (TiO2@2D-TiC) based room temperature operable, flexible ethanol gas sensor. The homogeneous distribution, unique composition, and crystalline microstructure of TiO2 nanoparticles grafted 2D-TiC nanosheets have been found to enhance the surface reactivity and efficiency of its transducer–receptor functions. The electron–hole recombination at the TiO2/2D-TiC interfaces offered superior sensor performance with fast response and recovery times. Moreover, TiO2@2D-TiC nanosheets based flexible sensor exhibited high selectivity toward trace-level ethanol gas (10 ppb–60 ppm) with extremely low noise-to-signal ratio and excellent stability. The results suggest that the development of low-cost flexible sensors based on TiO2@2D-TiC nanosheets could be applied for potential applications, such as printed/wearable electronics, biomedical sector and environmental monitoring.
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- 2019
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22. 3D-porous electrocatalytic foam based on Pt@N-doped graphene for high performance and durable polymer electrolyte membrane fuel cells
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Manoj Kumar Panthalingal, Appu Vengattoor Raghu, Vijayaraghavan Thiruvenkatam, Karthikeyan K. Karuppanan, P. Karthikeyan, and Biji Pullithadathil
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Materials science ,Renewable Energy, Sustainability and the Environment ,Membrane electrode assembly ,Graphene foam ,Limiting current ,Energy Engineering and Power Technology ,Proton exchange membrane fuel cell ,02 engineering and technology ,Electrolyte ,010402 general chemistry ,021001 nanoscience & nanotechnology ,Electrocatalyst ,01 natural sciences ,0104 chemical sciences ,Fuel Technology ,Chemical engineering ,Specific surface area ,0210 nano-technology ,Triple phase boundary - Abstract
A 3D porous nitrogen-doped graphene foam with a uniformly grafted platinum electrocatalyst (2–3 nm) (3D-Pt@N-graphene foam) has been developed using a simple hydrothermal synthesis for high performance proton exchange membrane (PEM) fuel cells. Excellent electrocatalytic activity towards the ORR in acidic medium has been exhibited by Pt@N-graphene foam with a favorable 4-electron transfer pathway resulting in the augmentation of active triple phase boundary sites. The positive shift of onset potential (989 mV) and half wave potential (895 mV) with a high limiting current density of 4.675 mA cm−2 exhibited by the 3D-Pt@N-graphene foam was found to be comparatively greater than that of the Pt/C catalyst with high durability. The presence of pyridinic-N and pyrrolic-N species in the highly compressible 3D-Pt@N-graphene foam contributed to the enhancement of the electrocatalytic activity, while graphitic-N improved the electrical conductivity of the material facilitating the electron transport during the ORR process. Compared to the commercial Pt/C electrocatalyst, the 3D-Pt@N-graphene foam based on a membrane electrode assembly exhibited four times higher power density (394 mW cm−2) and current density (1036 mA cm−2) owing to the favorable mass transport due to the hierarchical porous network, high specific surface area, nitrogen doping, uniform distribution of Pt nanoparticles and abundant active sites on the support material. The material demonstrates a new rational design for the fabrication of a highly efficient electrocatalyst assembly for flexible PEMFCs.
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- 2019
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23. Gold nanoparticles supported on NiO and CuO: The synergistic effect toward enhanced reduction of nitroarenes and A3-coupling reaction
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Mohammad Gholinejad, Rahimeh Khezri, Sara Nayeri, Ramakrishnan Vishnuraj, and Biji Pullithadathil
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Process Chemistry and Technology ,Physical and Theoretical Chemistry ,Catalysis - Published
- 2022
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24. Double-Sided, Omnidirectional γ-AlOOH Hierarchical Nanostructures: Imparting Enhanced Antireflective Properties with Self-Cleaning Capacity for Optical Devices
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Kamachi Mudali Uthandi, Nimmi Singh, Peeyush Kumar, Maninder Pal Kaur, Shalini Halan Joghee, Biji Pullithadathil, and Sanjeev Katti
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Nanostructure ,Materials science ,02 engineering and technology ,engineering.material ,010402 general chemistry ,01 natural sciences ,law.invention ,Contact angle ,Coating ,law ,Electrochemistry ,General Materials Science ,Specular reflection ,Spectroscopy ,business.industry ,Surfaces and Interfaces ,021001 nanoscience & nanotechnology ,Condensed Matter Physics ,Ray ,0104 chemical sciences ,Anti-reflective coating ,engineering ,Optoelectronics ,Photonics ,0210 nano-technology ,business ,Refractive index - Abstract
Herein, we have successfully developed an integrated strategy to develop antireflective coatings with self-cleaning capabilities based on periodic double-sided photonic γ-AlOOH nanostructures to transmit maximum incident light photons. Interfacial reflections are instinctive and one of the fundamental phenomena occurring at interfaces owing to refractive index mismatch. The eradication of such undesirable light reflection is of significant consideration in many optical devices. A systematic approach was carried out to eradicate surface reflection and enhance optical transmission by tailored γ-AlOOH nanostructures. The γ-AlOOH photonic nanostructures with subwavelength features exhibited a gradient index, which almost eliminated the refractive index mismatch at the interface. Optical transmittance of 97% was achieved in the range of 350-800 nm at normal incidence compared to uncoated glass (89%). A multilayer model approach was adopted to extract the effective refractive index of the coating, which showed a graded index from the top to the bottom surface. Further, to fully comprehend the optics of these nanostructures, the omnidirectional (20-70°) antireflective property has been explored using variable-angle specular reflectance spectroscopy. The hierarchical γ-AlOOH nanostructures exhibited only ∼1.3% reflectance at the lower incident angle in the visible spectra and an average reflectance of ∼7.6% up to an incident angle of 70°. Moreover, the hierarchical nanostructures manifested contact angle (CA) >172° and roll-off angle (RA)
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- 2021
25. Tailored construction of one-dimensional TiO2/Au nanofibers: Validation of an analytical assay for detection of diphenylamine in food samples
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Thangavelu Kokulnathan, Ramakrishnan Vishnuraj, Shen-Ming Chen, Biji Pullithadathil, Faheem Ahmed, P.M.Z. Hasan, Anwar L. Bilgrami, and Shalendra Kumar
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General Medicine ,Food Science ,Analytical Chemistry - Published
- 2022
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26. Unveiling the interplay between induced native defects and room temperature magnetic ordering in titanium deficient disordered-TiO
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Jayaseelan, Dhakshinamoorthy, Sachin Kumar, Srivastava, Durgamadhab, Mishra, and Biji, Pullithadathil
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Understanding the origin of magnetic ordering in an undoped semiconductor with native defects is an open question, which is being explored actively in research. In this investigation, the interplay between magnetic ordering and excess induced native defects in undoped anatase TiO
- Published
- 2020
27. Unidirectional Langmuir-Blodgett-Mediated Alignment of Polyaniline-Functionalized Multiwalled Carbon Nanotubes for NH
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Sukhananazerin, Abdulla and Biji, Pullithadathil
- Abstract
Herein, we report the formation of well-aligned ultrathin films of polyaniline-functionalized multiwalled carbon nanotubes (PANI@MWCNTs) with a high orientational order over a macroscopic area by Langmuir-Blodgett (LB) technique and its enhanced ammonia gas sensing properties. During the interfacial assembly process, the PANI@MWCNTs gradually align to form small ordered blocks at the air-water interface, which further organize as a well-defined oriented monolayer. The orientation and alignment of PANI@MWCNTs in Langmuir films at the air-water interface were systematically studied as a function of interface temperature using transmission electron microscopic analysis. Surface functionalization of MWCNTs with polyaniline was found to overcome the 3D aggregation of CNTs leading to an oriented assembly of PANI@MWCNTs. The formation and stability of the compact monolayer/multilayer structures of PANI@MWCNTs-based LB films have been extensively studied using a π
- Published
- 2020
28. Boosting the performance of NO
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Ramakrishnan, Vishnuraj, Karthikeyan K, Karuppanan, Mahaboobbatcha, Aleem, and Biji, Pullithadathil
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Herein, n-n type one dimensional ZnO@In
- Published
- 2020
29. Porous, n-p type ultra-long, ZnO@Bi
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Vishnuraj, Ramakrishnan, Keerthi G, Nair, Jayaseelan, Dhakshinamoorthy, K R, Ravi, and Biji, Pullithadathil
- Abstract
Herein, porous 1D n-p type ultra-long ZnO@Bi2O3 heterojunction nanorods have been synthesized by a solvothermal method and their complex charge transport characteristics pertaining to NO2 gas sensing properties have been investigated. The porous structure of the ZnO@Bi2O3 heterojunction nanorods assisted in achieving superior sensing properties compared to pristine ZnO nanorods. Temperature-dependent in situ electrical studies of the porous heterojunction nanorods explored the unique electron transport properties under different environments, which revealed the accumulation/depletion of electrons and charge carrier recombination leading to band bending at the metal oxide heterojunctions. The formation of electron depletion layers at n-ZnO/p-Bi2O3 interfaces is believed to increase the adsorption of oxidizing gas, resulting in a fast response time (10-12 s) and 10 times higher sensitivity than that of the ZnO nanorod-based sensor towards 500 ppb NO2. To study the structure-property correlation of the ultra-long ZnO@Bi2O3 heterojunction nanorods-based sensor, a crystallographic model supported by transmission electron microscopy analysis was adopted to understand the NO2 gas adsorption properties on the surface. The crystallographic model helps to visualize the dangling bonds and the ratio of metal to oxygen ions present at the exposed crystal planes. The results suggest that porous, ultralong n-p type ZnO@Bi2O3 heterojunction nanorods could be a promising candidate for a high performance NO2 sensor for real time applications.
- Published
- 2020
30. Anomalous Effects of Lattice Strain and Ti3+ Interstitials on Room-Temperature Magnetic Ordering in Defect-Engineered Nano-TiO2
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Jayaseelan Dhakshinamoorthy, Arun K. Prasad, Biji Pullithadathil, and Sandip Dhara
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Anatase ,Condensed matter physics ,Magnetic moment ,02 engineering and technology ,Electron ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,Surfaces, Coatings and Films ,Electronic, Optical and Magnetic Materials ,Ion ,Metal ,General Energy ,Ferromagnetism ,visual_art ,Lattice (order) ,visual_art.visual_art_medium ,Physical and Theoretical Chemistry ,0210 nano-technology ,Spectroscopy - Abstract
Defect engineering in n-type undoped metal oxides is a great challenge compared to the often-studied surface oxygen vacancies. The present investigation unravels new insights toward defect chemistry and defect engineering in anatase TiO2 nanoparticles. It is demonstrated that using the rapid cooling process, high concentration of Ti3+ interstitials, and lattice oxygen vacancies can be easily introduced in undoped metal oxides. The structural disorders in anatase TiO2 nanoparticles synthesized under two different argon-annealing processes have been comprehensively investigated using spectroscopy and electron microscopic analysis. Though excess of interstitial Ti3+ ions with one unpaired 3d electron in quenched TiO2 introduces local magnetic moments, they could be antiferromagnetically coupled via lattice Ti4+ ions, which limit the overall magnetic moment of the quenched materials. Lattice contraction was also found to enhance the ferromagnetic coupling between the defect complexes (Ti3+–F+ center) which he...
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- 2018
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31. Highly Sensitive, Temperature-Independent Oxygen Gas Sensor Based on Anatase TiO2 Nanoparticle Grafted, 2D Mixed Valent VOx Nanoflakelets
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Appu Vengattoor Raghu, Biji Pullithadathil, and Karthikeyan K. Karuppanan
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Fluid Flow and Transfer Processes ,Anatase ,Materials science ,Process Chemistry and Technology ,Thermal decomposition ,chemistry.chemical_element ,Bioengineering ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,Oxygen ,Vanadium oxide ,0104 chemical sciences ,symbols.namesake ,Chemical engineering ,chemistry ,X-ray photoelectron spectroscopy ,symbols ,0210 nano-technology ,Raman spectroscopy ,Instrumentation ,Temperature coefficient ,Monoclinic crystal system - Abstract
Herein, we report a facile approach for the synthesis of TiO2 nanoparticles tethered on 2D mixed valent vanadium oxide (VOx/TiO2) nanoflakelets using a thermal decomposition assisted hydrothermal method and investigation of its temperature-independent performance enhancement in oxygen-sensing properties. The material was structurally characterized using XRD, TEM, Raman, DSC, and XPS analysis. The presence of mixed valent states, such as V2O5 and VO2 in VOx, and the metastable properties of VO2 have been found to play crucial roles in the temperature-independent electrical conductivity of VOx/TiO2 nanoflakelets. Though pristine VOx exhibited characteristic semiconductor-to-metal transition of monoclinic VO2, pure VOx nanoflakelets exhibited poor sensitivity toward sensing oxygen. VOx/TiO2 nanoflakelets showed a very low temperature coefficient of resistance above 150 °C with improved sensitivity (35 times higher than VOx for 100 ppm) toward oxygen gas. VOx/TiO2 nanoflakelets exhibited much higher response,...
- Published
- 2018
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32. Novel Electro-Spun Nanograined ZnO/Au Heterojunction Nanofibers and Their Ultrasensitive NO2Gas Sensing Properties
- Author
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Biji Pullithadathil, Dinesh Veeran Ponnuvelu, and Sukhananazerin Abdulla
- Subjects
Materials science ,Nanofiber ,Nanotechnology ,Heterojunction ,02 engineering and technology ,General Chemistry ,010402 general chemistry ,021001 nanoscience & nanotechnology ,0210 nano-technology ,01 natural sciences ,0104 chemical sciences - Published
- 2018
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33. Magnesium oxide supported bimetallic Pd/Cu nanoparticles as an efficient catalyst for Sonogashira reaction
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Mohammad Gholinejad, Carmen Nájera, Biji Pullithadathil, Maedeh Bahrami, Universidad de Alicante. Departamento de Química Orgánica, and Síntesis Asimétrica (SINTAS)
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010405 organic chemistry ,Magnesium ,Aryl ,Iodobenzene ,Sonogashira ,chemistry.chemical_element ,Sonogashira coupling ,010402 general chemistry ,01 natural sciences ,Catalysis ,0104 chemical sciences ,chemistry.chemical_compound ,Química Orgánica ,chemistry ,Phenylacetylene ,Supported catalyst ,Physical and Theoretical Chemistry ,Bimetallic strip ,Palladium ,Copper ,Magnesium oxide ,Nuclear chemistry - Abstract
PdCu bimetallic nanoparticles with a diameter of about 3 nm are prepared and supported on a polymeric vinylimidazole ligand modified magnesium oxide. This new material is characterized using different analysis such as XRD, XPS, CHNS, TEM, SEM, and EDX-mapping. PdCu supported on MgO (MgO@PdCu) exhibits high catalytic activity in the Sonogashira coupling reaction of aryl iodides, bromides and chlorides with low Pd loading (0.05–0.2 mol%). This catalyst is recovered and recycled for 11 consecutive runs preserving its catalytic activity in the model reaction of iodobenzene with phenylacetylene for at least 8 cycles. Reused catalyst is characterized with TEM, XPS and EDX showing preservation of the catalyst structure. Using hot filtration and PVP poisoning tests, the catalyst shows a heterogeneous behavior for the model reaction. The authors are grateful to Institute for Advanced Studies in Basic Sciences (IASBS) Research Council and Iran National Science Foundation (INSF-Grant number of 95844587) for support of this work. C. Nájera is also thankful to the Spanish Ministerio de Economía y Competitividad (MINECO) (projects CTQ2013-43446-P and CTQ2014-51912-REDC), the Spanish Ministerio de Economía, Industria y Competitividad, Agencia Estatal de Investigación (AEI) and Fondo Europeo de Desarrollo Regional (FEDER, EU) (projects CTQ2016-76782-P and CTQ2016-81797-REDC), the Generalitat Valenciana (PROMETEOII/2014/017) and the University of Alicante for financial support.
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- 2018
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34. Enlarged interlayer spaced molybdenum disulfide supported on nanocarbon hybrid network for efficient hydrogen evolution reaction
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Aruna Kalasapurayil Kunhiraman, Sivasubramanian Ramanathan, and Biji Pullithadathil
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Tafel equation ,Materials science ,Nanocomposite ,General Chemical Engineering ,Exchange current density ,02 engineering and technology ,Overpotential ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,Catalysis ,chemistry.chemical_compound ,Chemical engineering ,chemistry ,Electrochemistry ,0210 nano-technology ,Porosity ,Current density ,Molybdenum disulfide - Abstract
We report a facile, one pot solvothermal route to prepare ultrathin molybdenum disulfide supported on nanocarbon hybrid (MoS2@NCHy) network with varied mass loading of MoS2 (20 wt%, 40 wt% and 60 wt%) for catalyzing hydrogen evolution reaction (HER). A large current density of −451 mAcm−2 at an overpotential of −480 mV vs. RHE, proves 40 wt% MoS2@NCHy/GCE nanocomposite as a highly HER active catalytic material. This value was found to be 50 times, 6 times and 2.5 times higher compared to MoS2/GCE (−8 mAcm−2), 20 wt% MoS2@NCHy/GCE (−75 mAcm−2) and 60 wt% MoS2@NCHy/GCE (−180 mAcm−2) respectively. Meanwhile, η10 (overpotential required to attain a current density of −10 mAcm−2) is −186 mV for 40 wt% MoS2@NCHy/GCE, which is much lower to MoS2/GCE (−498 mV), NCHy/GCE (−334 mV), 20 wt% MoS2@NCHy/GCE (−264 mV) and 60 wt% MoS2@NCHy/GCE (−204 mV). The overall activity of the catalyst was manifested by the least overpotential, η10 = −186 mV vs. RHE, Tafel slope of 53 mVdec−1 and exchange current density (j0) of 6.3 × 10−2 mAcm−2. The superior performance of 40 wt% MoS2@NCHy should be attributed to the highly conductive and porous support of three dimensional NCHy architecture as well as the enlarged interlayer spacing of MoS2. This study paves a new paradigm to exploit the synergistic effect of MoS2 and NCHy resulting in strong electronic coupling for enhancement in the HER activity.
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- 2018
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35. Highly monodispersed mesoporous, heterojunction ZnO@Au micro-spheres for trace-level detection of NO2 gas
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Dinesh Veeran Ponnuvelu, Sukhananazerin Abdulla, and Biji Pullithadathil
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Materials science ,Photoluminescence ,chemistry.chemical_element ,Nanotechnology ,Heterojunction ,02 engineering and technology ,General Chemistry ,Zinc ,010402 general chemistry ,021001 nanoscience & nanotechnology ,Condensed Matter Physics ,01 natural sciences ,0104 chemical sciences ,Nanoclusters ,Electron transfer ,Physisorption ,Chemical engineering ,chemistry ,Mechanics of Materials ,General Materials Science ,0210 nano-technology ,Selectivity ,Mesoporous material - Abstract
Highly monodispersed, mesoporous ZnO@Au heterojunction micro-spheres have been successfully synthesized using a two-stage facile chemical method and their surface bound NO2 sensing properties were explored. Room temperature Photoluminescence (RTPL) reveal the presence of high degree of oxygen defects and zinc interstitials for the pristine ZnO mesoporous-spheres and a drastic reduction in PL intensity of the ZnO@Au heterojunction mesoporous-spheres pointing towards the utilization of surface defects for the Au cluster growth, facilitating electron transfer process between ZnO and Au. NO2 gas sensor property analysis of the ZnO@Au mesoporous-spheres showed an extraordinary sensitivity and selectivity at a lower operating temperature of 250 °C than pristine ZnO mesoporous-spheres (450 °C). The enhanced sensing behavior of the ZnO@Au heterojunction mesoporous-spheres can be ascribed to the synergetic effect of Au nanoclusters at the heterojunctions which acts as spill-over zone for the physisorption mediated sensing process and the inherent high surface area and surface defects.
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- 2018
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36. Triple phase boundary augmentation in hierarchical, Pt grafted N-doped mesoporous carbon nanofibers for high performance and durable PEM fuel cells
- Author
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Sivasubramanian Ramanathan, Appu Vengattoor Raghu, Karthikeyan K. Karuppanan, Manoj Kumar Panthalingal, Thanarajan Kumaresan, and Biji Pullithadathil
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Materials science ,Renewable Energy, Sustainability and the Environment ,Catalyst support ,Proton exchange membrane fuel cell ,02 engineering and technology ,General Chemistry ,010402 general chemistry ,021001 nanoscience & nanotechnology ,Electrochemistry ,Electrocatalyst ,01 natural sciences ,Nanomaterial-based catalyst ,0104 chemical sciences ,Chemical engineering ,Nanofiber ,General Materials Science ,0210 nano-technology ,Triple phase boundary ,Mesoporous material - Abstract
Pt-grafted, hierarchical mesoporous carbon nanofibers (Pt/MPCNFs) electrocatalysts have been developed using electrospinning for high-performance PEM fuel cells. The morphological analysis of Pt/MPCNFs revealed uniformly dispersed Pt nanoparticles (2–3 nm) strongly grafted onto the hierarchical nanochannels of mesoporous carbon nanofibers (MPCNFs). Pyridinic and pyrrolic nitrogen species formed in the sp2 graphitic structure during the carbonization process of the MPCNFs have been found to play a major role in augmentation of the triple phase boundaries in the catalyst support materials. Pt/MPCNFs exhibited outstanding electrocatalytic performance towards the oxygen reduction reaction (ORR) with a positively shifted onset potential (54 mV), half-wave potential (78 mV) and high limiting current density (4.75 mA cm−2 at 0.4 V) compared to state-of-the-art Pt/C electrocatalysts in acidic medium and they exhibited superior long-term stability (89.8% retention after 30 000 s and less change in activity after 10 000 potential sweeps). Pt/MPCNFs as a cathode catalyst yielded a maximum power density of 428.6 mW cm−2 during single cell testing, which is 2.08 times higher than a commercial Pt/C electrocatalyst. The electrochemical performance evaluation clearly implied that the unique combination of ultrathin nanofibers with a three-dimensional mesoporous structure, high electrical conductivity, enhanced specific surface area, homogeneous dispersion of Pt nanocatalysts and the presence of optimal nitrogen doping offers superior electrocatalytic activity via a favorable four-electron pathway and long-term operating stability during repeated cycles. Performance analysis in a single PEM fuel cell shows twice the power density (428 mW cm−2) with Pt/MPCNFs compared to commercial electrocatalyst membranes due to the effective enhancement in the triple phase boundaries, indicating that Pt/MPCNFs are potential candidates for high-performance, durable PEMFCs.
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- 2018
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37. Rapid, Trace‐Level Ammonia Gas Sensor Based on Surface‐Engineered Ag Nanoclusters@Polyaniline/Multiwalled Carbon Nanotubes and Insights into Their Mechanistic Pathways
- Author
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Sukhananazerin Abdulla, Biji Pullithadathil, and Dinesh Veeran Ponnuvelu
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Nanocomposite ,Materials science ,Composite number ,Nanotechnology ,02 engineering and technology ,General Chemistry ,Carbon nanotube ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,law.invention ,Nanoclusters ,chemistry.chemical_compound ,Adsorption ,chemistry ,law ,Polyaniline ,Surface modification ,0210 nano-technology ,Selectivity - Abstract
An ultrasensitive and selective chemiresistive sensor interface based on Ag nanocluster integrated polyaniline functionalized multi-walled carbon nanotubes (AgNC@PANI/MWCNTs) has been developed for trace-level detection of NH3 gas at room temperature. AgNC@PANI/MWCNTs was synthesized using surfactant-free, one-pot wet-chemical process, by controlled integration of active Ag sites onto MWCNTs. The structure and morphology of AgNC@PANI/MWCNTs nanocomposite have been extensively studied by various characterization techniques. The gas sensing properties of AgNC@PANI/MWCNTs nanocomposite towards trace-level concentrations NH3 (2-10 ppm), an important biomarker in exhaled human breath, was systematically evaluated. The sensor exhibited dramatic enhancement in the sensor response (26 %), fast response (∼5 s) and recovery (∼4 s) characteristics with good reproducibility and selectivity upon exposure to NH3 gas. The excellent performance of the sensor towards NH3 could be attributed to the rapid electronic sensitization of surface engineered active AgNC sites in the composite in which oxidized AgNC were found to play a critical role. Effect of humidity and the kinetics of the NH3 gas adsorption on nanocomposite were analyzed. The possible interactions between NH3 and AgNC@PANI/MWCNTs nanocomposite were discussed. This investigation can pave the way to novel strategies for designing and fabricating low-cost, high performance NH3 gas sensors for clinical breath analyzer application.
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- 2017
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38. Highly sensitive, atmospheric pressure operatable sensor based on Au nanoclusters decorated TiO2@Au heterojunction nanorods for trace level NO2 gas detection
- Author
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Dinesh Veeran Ponnuvelu, Biji Pullithadathil, Baldev Raj, Sandip Dhara, Kamruddin Mohamed, A.K. Tyagi, and Arun K. Prasad
- Subjects
Anatase ,Materials science ,Atmospheric pressure ,Analytical chemistry ,Heterojunction ,02 engineering and technology ,Partial pressure ,010402 general chemistry ,021001 nanoscience & nanotechnology ,Condensed Matter Physics ,01 natural sciences ,Atomic and Molecular Physics, and Optics ,0104 chemical sciences ,Electronic, Optical and Magnetic Materials ,Nanoclusters ,Adsorption ,Phase (matter) ,Nanorod ,Electrical and Electronic Engineering ,0210 nano-technology - Abstract
A controlled synthetic strategy is established for the development of TiO2@Au heterojunction nanorods using a facile wet-chemical method for the detection of NO2 gas under atmospheric pressure conditions. Structural studies reveal the existence of metastable anatase phase along with thermodynamically stable rutile phase with high degree of crystallinity. The structural analysis divulges the uniform surface anchoring of Au nanoclusters onto mono-dispersed TiO2 nanorods introducing interfacial metal–semiconductor heterojunctions. TiO2@Au heterojunction nanorods exhibited excellent sensor performance towards trace level exposure of NO2 gas. Owing to the interfacial electron transfer process at the heterojunction the optimum operating temperature of TiO2@Au heterojunction nanorods determined to be 250 °C, which is much less as compared to pristine TiO2 gas sensors (400 °C). Sensor response was found to be linear for the trace level concentration range of 0.5–5 ppm with lowest detection limit as 500 ppb. The TiO2@Au heterojunction nanorods exhibited higher sensitivity at atmospheric pressure conditions compared to vacuum conditions because of the changes in surface O2 adsorption properties of the heterojunction material at different oxygen partial pressure and existence of mixed phases in TiO2 nanorods. The superior gas sensor performance of the material under atmospheric pressure conditions point towards their potential for real-time applications.
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- 2017
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39. Development of low-cost hybrid multi-walled carbon nanotube-based ammonia gas-sensing strips with an integrated sensor read-out system for clinical breath analyzer applications
- Author
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Venkataraman Krishnan Kallidaikuruchi, Dinesh Veeran Ponnuvelu, Sukhananazerin Abdulla, Vijay Mohan, Jayaseelan Dhakshinamoorthy, Biji Pullithadathil, and Lazar Mathew Thalakkotil
- Subjects
Pulmonary and Respiratory Medicine ,Materials science ,Silver ,STRIPS ,Carbon nanotube ,01 natural sciences ,law.invention ,Nanocomposites ,03 medical and health sciences ,0302 clinical medicine ,law ,Ammonia ,Humans ,Computer Simulation ,Nanocomposite ,Ammonia gas ,Aniline Compounds ,business.industry ,Nanotubes, Carbon ,010401 analytical chemistry ,Reproducibility of Results ,Humidity ,Carbon Dioxide ,0104 chemical sciences ,Microcontroller ,Breath analyzer ,030228 respiratory system ,Breath Tests ,Costs and Cost Analysis ,Optoelectronics ,business - Abstract
This work demonstrates the development of Ag@polyaniline/multi-walled carbon nanotube nanocomposite-based sensor strips and a suitable integrated electronic read-out system for the measurement of trace-level concentrations of ammonia (NH3). The sensor is optimized under various operating conditions and the resulting sensor exhibited an enhanced response (32% for 2 ppm) with excellent selectivity. Stable performance was observed towards NH3 in the presence of high concentrations of CO2 (>40 000 ppm), simulated and real breath samples. A suitable electronic sensor read-out system has also been designed and developed based on multi-scale resistance-to-voltage conversion architecture, processed by a 32-bit microcontroller which is operatable over a wide range of sensor resistance (1 kΩ to 200 MΩ). As a proof of concept, integration of gas-sensing strips with the electronic read-out system was tested with various levels of NH3 ( 2 ppm as critical and 2 ppm as threshold), which is important for clinical breath analyzer applications. The developed prototype device can be readily incorporated into a portable, low-cost and non-invasive point-of-care breath NH3 detection unit for portable pre-diagnostic breath analyzer applications.
- Published
- 2019
40. Ultrahigh specific capacitance of α-Fe2O3 nanorods-incorporated defect-free graphene nanolayers
- Author
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Vijayasree Haridas, Biji Pullithadathil, Binitha N. Narayanan, and A. Sukhananazerin
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Supercapacitor ,Nanocomposite ,Materials science ,Graphene ,020209 energy ,Mechanical Engineering ,02 engineering and technology ,Building and Construction ,Pollution ,Capacitance ,Industrial and Manufacturing Engineering ,Pseudocapacitance ,law.invention ,General Energy ,020401 chemical engineering ,Chemical engineering ,law ,Electrode ,0202 electrical engineering, electronic engineering, information engineering ,Graphite ,0204 chemical engineering ,Electrical and Electronic Engineering ,Hybrid material ,Civil and Structural Engineering - Abstract
The development of hybrid materials with high pseudocapacitance and electrical double layer capacitance is an urge for the fabrication of efficient supercapacitor electrodes. Herein, a highly effective, easily performable, high-yielding, and economical method is demonstrated for the preparation of α -Fe2O3 nanorods incorporated defect-free graphene nanosheets that showed excellent supercapacitor performance. α -Fe2O3/graphene nanocomposite has been synthesized by an interlayer catalytic exfoliation of α -Fe2O3 intercalated graphite which showed high conductivity of 3.1 × 106 S/cm. α -Fe2O3/graphene nanocomposite modified carbon paste electrode exhibited ultrahigh specific capacitance values of 1135 mF/cm2 at a scan rate of 5 mV/s and 815 mF/cm2 at a current density of 0.5 mA/cm2. The fast ionic diffusion with no charge transfer resistance of the electrode material was revealed from the electrochemical impedance spectroscopic analysis. α -Fe2O3/graphene nanocomposite showed 100 folds of increase in the specific capacitance compared to α -Fe2O3 and graphene, suggesting their synergistic effect in the nanocomposite leading to a drastic increase in the specific capacitance. The composite displayed good cyclic stability of 79.9% retention of the initial capacitance after 1500 cycles and 54.9% after 10,000 repeated cycles.
- Published
- 2021
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41. Heterostructured bismuth oxide/hexagonal-boron nitride nanocomposite: A disposable electrochemical sensor for detection of flutamide
- Author
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Tzyy-Jiann Wang, Ramakrishnan Vishnuraj, Thangavelu Kokulnathan, Biji Pullithadathil, and Elumalai Ashok Kumar
- Subjects
Boron Compounds ,Materials science ,Health, Toxicology and Mutagenesis ,0211 other engineering and technologies ,Oxide ,chemistry.chemical_element ,02 engineering and technology ,010501 environmental sciences ,Two-dimensional materials ,Electrochemistry ,01 natural sciences ,Catalysis ,Environmental pollution ,Nanocomposites ,Bismuth ,chemistry.chemical_compound ,GE1-350 ,Electrodes ,Prostate anti-cancer ,0105 earth and related environmental sciences ,Detection limit ,021110 strategic, defence & security studies ,Nanocomposite ,Public Health, Environmental and Occupational Health ,Electrochemical Techniques ,General Medicine ,Pollution ,Carbon ,Flutamide ,Electrochemical gas sensor ,Environmental sciences ,Electrochemical sensor ,TD172-193.5 ,chemistry ,Chemical engineering ,Anti-testosterone ,Boron nitride ,Electrode ,Metal oxides - Abstract
Aquatic contamination from the accumulation of pharmaceuticals has induced severe toxicological impact to the ecological environment, especially from non-steroidal anti-inflammatory drugs (NSAIDs). Real-time monitoring of flutamide, which is a class of NSAIDs, is very significant in environmental protection. In this work, we have synthesized the hexagonal-h boron nitride decorated on bismuth oxide (Bi2O3/h-BN) based nanocomposite for the effective electrochemical detection of flutamide (FTM). The structural and morphological information of the heterostructured Bi2O3/h-BN nanocomposite was analyzed by using a sequence of characterization methods. Voltammetric techniques were used to evaluate the analytical performance of the Bi2O3/h-BN modified screen-printed carbon electrode (SPCE) for the FTM detection. The Bi2O3/h-BN modified SPCE displays a synergetic catalytic effect for the reduction of FTM due to large surface area, numerous active sites, fast charge transfer and abundant defects. The proposed electrochemical sensing platform demonstrates high selectivity, low detection limit (9.0 nM), good linear ranges (0.04–87 μM) and short response time for the detection of FTM. The feasibility of the electrochemical sensor has been proved by the successful application to determine FTM in environmental samples.
- Published
- 2021
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42. Agarose functionalized phosphorus ligand for stabilization of small-sized palladium and copper nanoparticles: efficient heterogeneous catalyst for Sonogashira reaction
- Author
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Mohammad Gholinejad, Biji Pullithadathil, and Neda Jeddi
- Subjects
Phosphinite ,010405 organic chemistry ,Aryl ,Organic Chemistry ,Inorganic chemistry ,chemistry.chemical_element ,Sonogashira coupling ,010402 general chemistry ,Heterogeneous catalysis ,01 natural sciences ,Biochemistry ,Copper ,0104 chemical sciences ,chemistry.chemical_compound ,chemistry ,Drug Discovery ,Agarose ,Bimetallic strip ,Palladium ,Nuclear chemistry - Abstract
Mono-dispersed and small-sized bimetallic copper and palladium nanoparticles were successfully supported on phosphinite functionalized agarose biopolymer. The new material was characterized using various techniques such as solid state UV–vis and FT-IR spectroscopies, SEM, EDX, TGA, HRTEM, SAED, EDX-Map, and nitrogen adsorption–desorption analysis. The heterogeneous and recyclable catalyst has been used in Sonogashira coupling reaction of aryl iodides at room temperature and aryl bromides at 50 °C under low palladium loading conditions (0.05 mol %).
- Published
- 2016
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43. New Insights Towards Electron Transport Mechanism of Highly Efficient p-Type CuO (111) Nanocuboids-Based H2S Gas Sensor
- Author
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Jayaseelan Dhakshinamoorthy and Biji Pullithadathil
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Chemistry ,Inorganic chemistry ,chemistry.chemical_element ,02 engineering and technology ,Electron ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,Electron transport chain ,Oxygen ,Dissociation (chemistry) ,0104 chemical sciences ,Surfaces, Coatings and Films ,Electronic, Optical and Magnetic Materials ,Catalysis ,Surface conductivity ,General Energy ,Adsorption ,Chemical engineering ,Molecule ,Physical and Theoretical Chemistry ,0210 nano-technology - Abstract
Charge transport and adsorption kinetics of wet-chemically synthesized CuO nanocuboids have been explored. The growth direction of CuO nanocuboids was found to be (111) plane, which exhibited predominant surface catalytic activity toward the dissociation of H2S and O2. Temperature-dependent adsorption studies revealed the adsorption kinetics of (111) grown p-type CuO nanocuboids toward H2S gas. Adsorption of oxygen (O2) on the CuO (111) surface resulted in the formation of ionosorbed O2¯ species, which increased the hole density and enhanced the surface conductivity of CuO nanocuboids. H2S molecules were found to interact well with CuO (111) surface, donating electrons to the material and reducing the hole-accumulation layer width. Investigation of electrical characteristics of p-type CuO nanocuboids revealed absence of any structural phase transitions under H2S environment. The H2S sensing mechanism was found to be associated with local suppression/expansion of the hole-accumulation layer of p-CuO nanocu...
- Published
- 2016
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44. Copper nanoparticles supported on starch micro particles as a degradable heterogeneous catalyst for three-component coupling synthesis of propargylamines
- Author
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Biji Pullithadathil, Fariba Saadati, Shahram Shaybanizadeh, and Mohammad Gholinejad
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Materials science ,010405 organic chemistry ,Starch ,General Chemical Engineering ,Nanoparticle ,chemistry.chemical_element ,General Chemistry ,010402 general chemistry ,Heterogeneous catalysis ,01 natural sciences ,Copper ,0104 chemical sciences ,Catalysis ,chemistry.chemical_compound ,chemistry ,X-ray photoelectron spectroscopy ,Chemical engineering ,Organic chemistry ,Coupling (piping) ,Selected area diffraction - Abstract
Novel copper nanoparticles supported on starch micro particles (CuNPs@MS) were prepared successfully and characterized by SEM, EDX, TEM, SAED, TGA, XPS, and XRD analyses. The easily synthesized and thermally stable CuNPs@MS have been applied as a green, degradable, and eco-friendly catalyst in a three component reaction of amines, aldehydes and alkynes for the preparation of diverse propargylamines. The reactions were performed under heterogeneous conditions and the catalyst was successfully recycled for five consecutive runs with a small decrease in activity.
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- 2016
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45. Unveiling the interplay between induced native defects and room temperature magnetic ordering in titanium deficient disordered-TiO2 nanoparticles
- Author
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Jayaseelan Dhakshinamoorthy, Sachin Kumar Srivastava, D. Mishra, and Biji Pullithadathil
- Subjects
Quenching ,Anatase ,Materials science ,Magnetic moment ,Intrinsic semiconductor ,Mechanical Engineering ,Nanoparticle ,chemistry.chemical_element ,Bioengineering ,02 engineering and technology ,General Chemistry ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,Oxygen ,0104 chemical sciences ,Ion ,Crystallography ,chemistry ,Mechanics of Materials ,General Materials Science ,Electrical and Electronic Engineering ,0210 nano-technology ,Titanium - Abstract
Understanding the origin of magnetic ordering in an undoped semiconductor with native defects is an open question, which is being explored actively in research. In this investigation, the interplay between magnetic ordering and excess induced native defects in undoped anatase TiO2 nanoparticles is explained using an experimental and theoretical approach. It is demonstrated that structurally disordered TiO2 nanoparticles with a high concentration of native defects such as titanium interstitials and oxygen vacancies are synthesized using controlled atmospheric rapid cooling (i.e. quenching) process. The structural disorders in the lattice have been examined using various spectroscopic and microscopic analyses revealed the existence of Ti deficiency in both pristine and quenched TiO2 nanoparticles. A possible origin of magnetic ordering in titanium deficient anatase TiO2 system is elucidated based on first-principle calculations. It was found that the overall magnetic moment of Ti deficient TiO2 system is determined by the distance between Ti interstitials and its neighboring vacancies (i.e. either V Ti or V Os). However, quenched TiO2 nanoparticles possess excess Ti interstitials, Ti and O vacancies and therefore the net magnetic moment of the system is reduced due to anti-ferromagnetically coupled neighboring Tilattice ions.
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- 2020
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46. α-Fe2O3 loaded less-defective graphene sheets as chemiresistive gas sensor for selective sensing of NH3
- Author
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J. Mary Sneha, Biji Pullithadathil, Vijayasree Haridas, Binitha N. Narayanan, and A. Sukhananazerin
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Chemiresistor ,Nanocomposite ,Materials science ,Graphene ,Sonication ,General Physics and Astronomy ,02 engineering and technology ,Surfaces and Interfaces ,General Chemistry ,010402 general chemistry ,021001 nanoscience & nanotechnology ,Condensed Matter Physics ,01 natural sciences ,Hydrothermal circulation ,0104 chemical sciences ,Surfaces, Coatings and Films ,law.invention ,symbols.namesake ,X-ray photoelectron spectroscopy ,Chemical engineering ,law ,symbols ,0210 nano-technology ,Selectivity ,Raman spectroscopy - Abstract
α-Fe2O3 functionalized, less-defective graphene sheets have been synthesized by a cost effective green solvent-assisted ultrasonication induced graphite exfoliation followed by hydrothermal method and its chemiresistive ammonia gas sensing properties have been investigated. The less-defective nature of graphene and the strong interaction of aromatic graphene network with α-Fe2O3 have been revealed from Raman spectroscopic and XPS and Raman spectroscopic analyses. The α-Fe2O3/graphene nanocomposite exhibited outstanding chemiresistive sensing properties towards NH3 gas, which is a toxic industrial pollutant. High sensor response, selectivity and repeatability are offered by the α-Fe2O3/graphene nanohybrid towards NH3 gas at 250 °C. The sensor response was linear in the range of 10–50 ppm with a regression coefficient of 0.95. A plausible sensing mechanism is suggested, indicating the role of both α-Fe2O3 and graphene leading to a synergistic response towards NH3.
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- 2020
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47. Pt Nanoislands Functionalized Mesoporous Carbon Nanofibers Based Chemical Sensor for Trace-Level Detection of Hydrogen Gas
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Keerthi G. Nair and Biji Pullithadathil
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Trace (semiology) ,Materials science ,Mesoporous carbon ,Chemical engineering ,Hydrogen ,chemistry ,Nanofiber ,chemistry.chemical_element ,Chemical sensor - Abstract
Introduction: Hydrogen is one of the most promising sources of energy for next generation power and transportation sectors.Owing to the inflammable properties of H2 gas, it is highly essential to develop technologies for its rapid detection to ensure safety and leakage detection in various application domains. In this regard, researchers have focused their attention on development of new chemical sensors based on solid electrolytes, metal oxides, polymers and carbon-based gas sensors [1-2]. Among these materials, carbon-based gas sensors have received immense attention owing to their exceptional structural properties, including high electrical conductivity, chemical and thermal stability and high surface area. Especially, carbon nanofibers (CNFs) have earned significant attention due to their notable electrical conductivity and stability with tailor-made one-dimensional structures. But, the sensors made of CNFs are less explored due to selectivity issues. Integration of catalytically active metal nanoparticles onto 1-D carbon nanostructures have been attempted by many groups [3-4]. For sensing hydrogen, expensive Pt catalysts have shown excellent performance. In order to improve the sensitivity at affordable cost, it is proposed that Pt can be used on mesoporous carbon nanofibers (pCNF). Herein, we report development of a novel room-temperature hydrogen sensor based on Pt@pCNF nanohybrids fabricated by electrospinning. Gas sensing properties were systematically investigated towards trace level detection of hydrogen gas which showed enhanced hydrogen sensing properties at room temperature with fast response/recovery time. Synthesis of Pt@pCNF nanohybrids: Carbon nanofibers were fabricated using electrospinning technique. The electrospun PAN fibers collected on copper sheet were subjected to a two-step thermal process to convert into carbon nanofibers by a stabilization (280°C) step followed by carbonization (800°C) in air and N2 atmosphere with a ramping rate of 2°C/min and 3°C/min by holding time of 1hr. Platinum nanoparticles were chemically deposited on functionalized carbon nanofibers via urea assisted ethylene glycol synthesis method. For fabrication of mesoporous carbon nanofibers (pCNF), NaHCO3 nanoparticles were used as pore forming agent during electrospinning process which was thermally decomposed for introduction of mesopores in carbon nanofibers. Results and Discussion: XRD patterns of Pt@CNF and Pt@pCNF confirms the fcc structure, which corresponds to (111), (200), (220) and (222) planes of Platinum (JCPDS card 04-0802). A broad diffraction peak was appeared at 24.7° in CNF@Pt nanohybrids, which is ascribed to the amorphous phase of carbon ((002) plane) in the carbon nanofibers assigned to hexagonal graphite (JCPDS card 41-1487). The Pt formed over the surface of CNFs exhibited evident diffraction peaks, signifying the formation and favorable crystallization of Pt@CNF and Pt@pCNF nanohybrids. Further structural characterization of the monometallic nanoislands was performed using HRTEM analysis. The lattice d-spacing of 0.227 nm corresponds to the (111) crystalline plane of face centered cubic crystal structure of Pt on the surface of Pt@CNF. Porous structure of carbon nanofibers where studied using HRTEM and SEM analysis. These results indicate that homogenous distribution of Pt nanoparticles over CNF and pCNF. Evaluation of Hydrogen gas sensor properties: H2 gas sensing properties of Pt@CNF and Pt@pCNF nanohybrids were evaluated using in-house gas sensor test station at room temperature. The dynamic gas sensing response of Pt@pCNF nanohybrids towards trace level detection of hydrogen from 0.1% to 4% exhibited sensitivity in the range of 6% to 47% at room temperature. Gas sensing response of CNFs with surface anchored platinum nanoparticles is due to high adsorption property of H2 on monometallic active sites. Upon exposure to H2 gas, H2 molecules initially physisorbed on the sensor and later chemisorbed. Due to this process, work function of the platinum is lowered and hence electron transfer occurs from platinum to supporting materials. Hence, the resistance decreases due to the accumulation of electrons which is evident from the gas sensing response of Pt@pCNF upon exposure to reducing gas, like H2. References: Korotcenkov, S. D. Han, and J. R. Stetter, Review of Electrochemical Hydrogen Sensors, Chem. Rev. (2009) 109, 1402–1433,doi: 10.1021/cr800339k. Hübert, L. Boon-Brett, G. Black, U. Banach, Hydrogen sensors – A review, Sensors and Actuators B 157 (2011) 329– 352, doi: 10.1016/j.snb.2011.04.070. Wang, S. Rathi, B. Singh, I. Lee, H. Joh and G. Kim, Alternating Current Dielectrophoresis Optimization of Pt-Decorated Graphene Oxide Nanostructures for Proficient Hydrogen Gas Sensor, ACS Appl. Mater. Interfaces 2015, 7, 13768-13775, doi: 10.1021/acsami.5b01329. Jung, M. Han, and G. S. Lee , Fast-response room temperature hydrogen gas sensors using Pt-coated spin-capable carbon nanotubes, ACS Appl. Mater. Interfaces,2015, doi: 10.1021/am506578j.
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- 2020
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48. High Performance N-N Type WO3@in2O3 core-Shell Heterojunction Nanowires Based NO2 Gas Sensor for Environmental Monitoring
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Vishnuraj Ramakrishnan and Biji Pullithadathil
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Core shell ,Materials science ,business.industry ,Environmental monitoring ,Nanowire ,Optoelectronics ,Heterojunction ,business - Abstract
Introduction: Harmful and toxic gases such as nitrogen dioxide (NO2), carbon-monoxide (CO) and VOCs are largely released into environment due to increased industrial revolution. NO2 is considered as one of the most dangerous air pollutants, which plays a vital role in the formation of ozone (O3) to produce acid rains and therefore, it is essential to monitor trace level NO2 gas in environment for human safety. One-dimensional (1D) nanostructures have become an attractive candidate for sensors owing to their superior spatial resolution and rapid response due to the high surface-to-volume ratio compared to thin film gas sensors [1–4]. Metal oxide based tungsten oxide (WO3) is an important n-type semiconductor material with a bandgap of 2.7 eV, suitable for gas sensor applications [5]. Though, WO3 is widely used gas sensor material, poor selectivity, high operating temperature and reliability hinders their practical application. Similarly, indium oxide (In2O3) has demonstrated as another promising gas sensor material specifically to detect NO2 gas at room-temperature. In this investigation, development of n-n type WO3@ In2O3 heterojunction nanorods has been implemented to form core-shell architecture which exhibited distinguished sensing properties at reduced temperature towards trace level NO2 gas with excellent sensitivity, high selectivity and fast response/recovery characteristics and a plausible mechanism is deduced. Synthesis of WO3@In2O3 core-shell heterojunction nanorods: 1D WO3 nanorods were synthesized using hydrothermal method as per previous report [6]. In this work, WO3@In2O3 core-shell heterojunction nanorods were subsequently prepared by solvothermal method. Briefly, In(CH3COO)3. xH2O (0.5 mmol) was dissolved in a binary solvent mixture (1:2) with ethylene glycol (17 mL) and ethanol (34 mL), followed by vigorous stirring for 40 min. Meanwhile, the surface treatment of 200 mg of WO3 nanorods were carried out under UV-irradiation (254 nm) for 2 min. The above mixture was subjected to ultrasonication for 30 min. The solution was further transferred into a Teflon-lined stainless-steel autoclave (100 mL capacity) and maintained at 160oC for 5 h. The product was separated, washed and centrifuged several times with ultrapure water followed by ethanol in order to eliminate the organic and redundant In2O3 impurities. The precipitate was dried in a vacuum oven at 80oC for 24 h. Finally, the resultant product was annealed at 500oC in air for 2 h at a heating rate of 2oC/min. The color of the precipitate was changed to pale yellow, implying the functionalization of In2O3 nanoparticles on the surface of WO3 nanorods. Results and Discussion: XRD patterns and the Raman spectral analysis of WO3 nanorods and WO3@In2O3 core-shell heterojunction nanorods confirmed the structural purity and formation of heterojunction materials. The peaks in XRD pattern of the WO3 nanorods could be well-indexed to the hexagonal phase of WO3 (JCPDS 85-2460). No additional peaks were observed, which confirmed the phase purity of synthesized WO3 nanorods. Further, core shell structure of the WO3@In2O3 nanorods was analyzed using HRTEM and SEM. The results indicated the homogenous distribution of In2O3 nanoparticles over WO3 nanorods. Evaluation of NO2 gas sensor properties: NO2 gas sensing properties of WO3 nanorods and WO3@In2O3 core-shell heterojunction nanorods were evaluated using in-house gas sensor test station at reduced temperature. The dynamic gas sensing response of WO3@In2O3 core-shell heterojunction nanorods towards trace level detection of NO2 in the range of 500 ppb to 3 ppm exhibited sensitivity upto to S = 280% at 150oC. The enhanced gas sensing response of WO3 nanorods with surface anchored In2O3 nanoparticles is attributed to high adsorption property of NO2 on active sites and also due to directed electron transport mechanism. Upon exposure to NO2, the gas molecules initially physisorbed at the heterojunctions and trap electrons from the heterojunction interfaces of WO3@In2O3 nanorods. Since electron transport between WO3 and In2O3 is based on work function difference, the electrons can accumulate at the heterojunction interfaces leading to increased space-charge depletion region. Hence, the resistance increases due to the depletion of electrons which is evident from the enhanced gas sensing behaviour of WO3@In2O3 heterojunction nanorods upon exposure to NO2. References: Kolmakov, Y. Zhang, G. Cheng, M. Moskovits, “Detection of CO and O2 Using Tin Oxide Nanowire Sensors”Adv. Mater.15, 997 (2003) doi:10.1002/adma.200304889 Liu, E. Koep, M. Liu, “A Highly Sensitive and Fast-Responding SnO2 Sensor Fabricated by Combustion Chemical Vapor Deposition”, Chem. Mater.17, 3997 (2005)doi:10.1021/cm050451o H. Lin, M.W. Huang, C.K. Liu, J.R. Chen, J.M. Wu, H.C. Shih, “The Preparation and High Photon-Sensing Properties of Fluorinated Tin Dioxide Nanowires”J. Electrochem. Soc.156, K196 (2009)doi:10.1149/1.3223984 S. Ramgir, I.S. Mulla, K.P. Vijayamohanan, “A room temperature nitric oxide sensor actualized from Ru-doped SnO2 nanowires”,Sens. Actuators B 107, 708 (2005) doi:10.1016/j.snb.2004.12.073 T. Sun, C. Cantalini, “Microstructural effect on NO2 sensitivity of WO3 thin film gas sensors Part 1. Thin film devices, sensors and actuators”, Thin Solid Films 287, 258 (1996).doi:10.1016/S0040-6090(96)08745-7 Jinmin Wang et, al., “Controlled Synthesis of WO3 Nanorods and Their Electrochromic Properties in H2SO4 Electrolyte”, J. Phys. Chem. C 2009,113,9655–9658.doi:10.1021/jp901650v
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- 2020
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49. Highly Sensitive, Temperature-Independent Oxygen Gas Sensor Based on Anatase TiO
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Appu Vengattoor, Raghu, Karthikeyan K, Karuppanan, and Biji, Pullithadathil
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Oxygen ,Titanium ,Vanadium Compounds ,Temperature ,Metal Nanoparticles ,Reproducibility of Results ,Adsorption ,Electrochemical Techniques ,Gases ,Phase Transition ,Nanocomposites - Abstract
Herein, we report a facile approach for the synthesis of TiO
- Published
- 2018
50. Highly sensitive, room temperature gas sensor based on polyaniline-multiwalled carbon nanotubes (PANI/MWCNTs) nanocomposite for trace-level ammonia detection
- Author
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Biji Pullithadathil, Sukhananazerin Abdulla, and Thalakkotur Lazar Mathew
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Materials science ,Nanocomposite ,Metals and Alloys ,Nanotechnology ,Carbon nanotube ,Condensed Matter Physics ,Surfaces, Coatings and Films ,Electronic, Optical and Magnetic Materials ,law.invention ,chemistry.chemical_compound ,symbols.namesake ,X-ray photoelectron spectroscopy ,chemistry ,Polymerization ,Chemical engineering ,law ,Polyaniline ,Materials Chemistry ,symbols ,Electrical and Electronic Engineering ,High-resolution transmission electron microscopy ,Spectroscopy ,Raman spectroscopy ,Instrumentation - Abstract
Herein we report excellent gas sensor properties of Polyaniline functionalized multiwalled carbon nanotubes (PANI/MWCNTs) based nanocomposite for trace level detection of ammonia (NH3) gas. PANI/MWCNTs nanocomposite was synthesized by in-situ chemical oxidative polymerization of aniline monomer with carboxylated multiwalled carbon nanotubes (C-MWCNTs). The material was structurally characterized by UV–vis Spectroscopy, FT-IR Spectroscopy, Raman Spectroscopy, X-ray Photoelectron Spectroscopy (XPS) and High Resolution Transmission Electron Microscopy (HRTEM). Uniform PANI layer with ∼7 nm thickness was formed on the external walls of the MWCNTs. The gas sensor properties of C-MWCNT and PANI/MWCNTs nanocomposite towards NH3 gas exposure at trace level concentrations (2–10 ppm) under ambient conditions were analyzed and their performances were compared. PANI/MWCNT nanocomposite based sensor exhibited excellent enhancement in sensor response and response/recovery characteristics with good reproducibility towards NH3 gas in comparison with C-MWCNT. The response and recovery time of the PANI/MWCNTs nanocomposite based sensor were found to be significantly improved in the order of a few seconds (6 s) towards NH3 gas. The results reveal the potential application of this sensor in monitoring trace level NH3 gas for varied applications.
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- 2015
- Full Text
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