Ezequiel Tosi scite author profile

MXenes are a young family of two-dimensional transition metals carbides, nitrides, and carbonitrides with highly controllable structure, composition, and surface chemistry to adjust for target applications. Here, we demonstrate the modifications of two-dimensional MXenes by low-energy ion implantation, leading to the incorporation of Mn ions in Ti3C2Tx thin films.Damages and structural defects caused by the implantation process are characterized at different depths by XPS on Ti2p core-level spectra, ToF-SIMS and with electron energy loss spectroscopy analyses. Results show that the ion-induced alteration of the damage tolerant Ti3C2Tx layer is due to defects formation in both Ti and C sites, thereby promoting the functionalization of these sites with oxygen groups. This work contributes to the inspiring approach of tailoring 2D MXenes structure and properties through doping and defects formation by low-energy ion implantation to expand their practical applications.

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Compositional Phase Change of Early Transition Metal Diselenide (VSe₂ and TiSe₂) Ultrathin Films by Postgrowth Annealing

Bonilla

Kolekar

et al. 2020

Adv Materials Inter

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The transition metal selenides M 1+y Se 2 (M=V, Ti) have intriguing quantum properties, which make them target materials for controlling properties by thinning them to the ultrathin limit. An appropriate approach for the synthesis of such ultrathin films is by molecular beam epitaxy. Here we show that such synthesized V-and Ti-Se 2 films can undergo a compositional change by vacuum annealing. Combined scanning tunneling and photoemission spectroscopy was used to determine compositional and structural changes of ultrathin films as a function of annealing temperature. Loss of selenium from the film is accompanied by a morphology change of monolayer height islands to predominantly bi-layer height. In addition, crystal periodicity and atomic structure changes are observed. These changes are consistent with a transition from a layered transition metal dichalcogenide (TMDC) to ordered intercalation compounds with V or Ti intercalated in between two layers of their respective TMDCs. These observations may clear up misconception of the nature of previously reported high temperature grown transition metal selenides. More significantly, the demonstrated control of the formation of intercalation compounds is a key step towards modifying properties in van der Waals systems and towards expanding materials systems for van der Waals heterostructures.

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The shell effect on the room temperature photoluminescence from ZnO/MgO core/shell nanowires: exciton–phonon coupling and strain

et al. 2017

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The room temperature photoluminescence from ZnO/MgO core/shell nanowires (NWs) grown by a simple two-step vapor transport method was studied for various MgO shell widths (w). Two distinct effects induced by the MgO shell were clearly identified. The first one, related to the ZnO/MgO interface formation, is evidenced by strong enhancements of the zero-phonon and first phonon replica of the excitonic emission, which are accompanied by a total suppression of its second phonon replica. This effect can be explained by the reduction of the band bending within the ZnO NW core that follows the removal of atmospheric adsorbates and associated surface traps during the MgO growth process on one hand, and a reduced exciton-phonon coupling as a result of the mechanical stabilization of the outermost ZnO NW monolayers by the MgO shell on the other hand. The second effect is the gradual increase of the excitonic emission and decrease in the defect related emission by up to two and one orders of magnitude, respectively, when w is increased in the ∼3-17 nm range. Uniaxial strain build-up within the ZnO NW core with increasing w, as detected by x-ray diffraction measurements, and photocarrier tunneling escape from the ZnO core through the MgO shell enabled by defect-states are proposed as possible mechanisms involved in this effect. These findings are expected to be of key significance for the efficient design and fabrication of ZnO/MgO NW heterostructures and devices.

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Glucose biosensor based on functionalized ZnO nanowire/graphite films dispersed on a Pt electrode

et al. 2016

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We present a glucose biosensor based on ZnO nanowire self-sustained films grown on compacted graphite flakes by the vapor transport method. Nanowire/graphite films were fragmented in water, filtered to form a colloidal suspension, subsequently functionalized with glucose oxidase and finally transferred to a metal electrode (Pt). The obtained devices were evaluated using scanning electron microscopy, energy-dispersive x-ray spectroscopy, cyclic voltammetry and chronoamperometry. The electrochemical responses of the devices were determined in buffer solutions with successive glucose aggregates using a tripolar electrode system. The nanostructured biosensors showed excellent analytical performance, with linear response to glucose concentrations, high sensitivity of up to ≈17 μA cm(-2) mM(-1) in the 0.03-1.52 mM glucose concentration range, relatively low Michaelis-Menten constant, excellent reproducibility and a fast response. The detection limits are more than an order of magnitude lower than those achievable in commercial biosensors for glucose control, which is promising for the development of glucose monitoring methods that do not require blood extraction from potentially diabetic patients. The strong detection enhancements provided by the functionalized nanostructures are much larger than the electrode surface-area increase and are discussed in terms of the physical and chemical mechanisms involved in the detection and transduction processes.

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Ezequiel Tosi

Ion Implantation as an Approach for Structural Modifications and Functionalization of Ti₃C₂T_x MXenes

Compositional Phase Change of Early Transition Metal Diselenide (VSe₂ and TiSe₂) Ultrathin Films by Postgrowth Annealing

The shell effect on the room temperature photoluminescence from ZnO/MgO core/shell nanowires: exciton–phonon coupling and strain

Glucose biosensor based on functionalized ZnO nanowire/graphite films dispersed on a Pt electrode

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About

Ezequiel Tosi

Ion Implantation as an Approach for Structural Modifications and Functionalization of Ti3C2Tx MXenes

Compositional Phase Change of Early Transition Metal Diselenide (VSe2 and TiSe2) Ultrathin Films by Postgrowth Annealing

The shell effect on the room temperature photoluminescence from ZnO/MgO core/shell nanowires: exciton–phonon coupling and strain

Glucose biosensor based on functionalized ZnO nanowire/graphite films dispersed on a Pt electrode

Contact Info

Product

Resources

About

Ion Implantation as an Approach for Structural Modifications and Functionalization of Ti₃C₂T_x MXenes

Compositional Phase Change of Early Transition Metal Diselenide (VSe₂ and TiSe₂) Ultrathin Films by Postgrowth Annealing