Edge-driven nanomembrane-based vertical organic transistors showing a multi-sensing capability

Nawaz, Ali; Merces, Leandro; Andrade, Denise M. de; Camargo, Davi H. S. de; Bufon, Carlos César Bof

doi:10.1038/s41467-020-14661-x

Cited by 39 publications

(72 citation statements)

References 66 publications

(84 reference statements)

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“…[32,33] Such an approach avoids electrical shortcircuits usually caused by top-electrode evaporation, whereas the mechanically soft top-contact preserves the moleculesintegrity and function. [34][35][36] Additionally, nCap monolithic integration spares the use of either liquid metal electrodes or scanning probe tips, allowing reliable fabrication of real-life molecular devices that can be operated in different electromagnetic fields, temperatures, pressures, among other external conditions. [37][38][39] In the literature, one may find exciting examples of using the nanomembrane-origami technology to fabricate various monolithically-integrated devices featuring organic/ inorganic hybrid functions.…”

Section: Introductionmentioning

confidence: 99%

Reorganization Energy upon Controlled Intermolecular Charge‐Transfer Reactions in Monolithically Integrated Nanodevices

Merces

Candiotto

Ferro

et al. 2021

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Intermolecular electron‐transfer reactions are key processes in physics, chemistry, and biology. The electron‐transfer rates depend primarily on the system reorganization energy, that is, the energetic cost to rearrange each reactant and its surrounding environment when a charge is transferred. Despite the evident impact of electron‐transfer reactions on charge‐carrier hopping, well‐controlled electronic transport measurements using monolithically integrated electrochemical devices have not successfully measured the reorganization energies to this date. Here, it is shown that self‐rolling nanomembrane devices with strain‐engineered mechanical properties, on‐a‐chip monolithic integration, and multi‐environment operation features can overcome this challenge. The ongoing advances in nanomembrane‐origami technology allow to manufacture the nCap, a nanocapacitor platform, to perform molecular‐level charge transport characterization. Thereby, employing nCap, the copper‐phthalocyanine (CuPc) reorganization energy is probed, ≈0.93 eV, from temperature‐dependent measurements of CuPc nanometer‐thick films. Supporting the experimental findings, density functional theory calculations provide the atomistic picture of the measured CuPc charge‐transfer reaction. The experimental strategy demonstrated here is a consistent route towards determining the reorganization energy of a system formed by molecules monolithically integrated into electrochemical nanodevices.

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Section: Introductionmentioning

confidence: 99%

Reorganization Energy upon Controlled Intermolecular Charge‐Transfer Reactions in Monolithically Integrated Nanodevices

Merces

Candiotto

Ferro

et al. 2021

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“…traditional inorganic electronic components -or even replace them -comes from the possibility of creating systems that display a high degree of sophistication. [4][5][6] Flexible devices processed by low-temperature routes and reduced production costs are some to mention a few. [7] As organic materials and devices reach the nanoscale, organic/inorganic interfaces become a fundamental counterpart, being responsible for several functionalities.…”

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confidence: 99%

High‐Performance Ultrathin Molecular Rectifying Diodes Based on Organic/Inorganic Interface Engineering

Batista

Merces

Costa

et al. 2021

Adv Funct Materials

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The bottom-up engineering of organic/inorganic hybrids is a crucial step toward advanced nanomaterial technologies. Understanding the energy level alignment at hybrid interfaces provides a valuable comprehension of the systems′ electronic properties -which are decisive for well-designed device applications. Here, active interfaces of ultrathin (≈10 nm) molecular rectifying diodes that are capable of achieving a 4-order-magnitude rectification ratio along with 10 MHz cutoff frequency, both in a single nanodevice, are engineered. Atomic force microscopy and Kelvin-Probe analysis are employed to investigate the surface potential of the hybrid devices′ organic/inorganic interfaces, which comprise a metal (M) electrode in contact with a fewnanometer-thick copper phthalocyanine (CuPc) film. Thereby a nanometerresolved quantification of the CuPc film work functions as well as the M/ CuPc diode's space-charge densities are delivered. By recognizing that the molecular rectifying diode is a functional building block for nanoscale electronics, the findings address crucial advances to the design of high-performance molecular rectifiers based on organic/inorganic interface engineering.

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“…[ 25 ] Such features are severely impacted by the surface–volume ratio displayed by the corresponding analytical environment—a scenario in which self‐curled nanomembranes (NMs) have successfully shown the remarkable capability of improving electrochemical energy conversion and storage within shrunk device components. [ 26,27 ] As nanometer‐thick, freestanding, bendable, and twistable structures, [ 28 ] which can be strain‐engineered to form microcylindrical cavities, [ 29 ] the NMs offer plenty of room for mass‐transport‐driven lab‐on‐a‐chip integration. [ 30 ] The self‐curling can be controlled very well by standard semiconductor processing techniques, whereas the tubular geometry, winding angle, the number of consecutive windings, and coil diameter can be adjusted precisely to provide specific device functionality.…”

Section: Introductionmentioning

confidence: 99%

Ultrahigh‐Gain Organic Electrochemical Transistor Chemosensors Based on Self‐Curled Nanomembranes

et al. 2021

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Organic electrochemical transistors (OECTs) are technologically relevant devices presenting high susceptibility to physical stimulus, chemical functionalization, and shape changes—jointly to versatility and low production costs. The OECT capability of liquid‐gating addresses both electrochemical sensing and signal amplification within a single integrated device unit. However, given the organic semiconductor time‐consuming doping process and their usual low field‐effect mobility, OECTs are frequently considered low‐end category devices. Toward high‐performance OECTs, microtubular electrochemical devices based on strain‐engineering are presented here by taking advantage of the exclusive shape features of self‐curled nanomembranes. Such novel OECTs outperform the state‐of‐the‐art organic liquid‐gated transistors, reaching lower operating voltage, improved ion doping, and a signal amplification with a >104 intrinsic gain. The multipurpose OECT concept is validated with different electrolytes and distinct nanometer‐thick molecular films, namely, phthalocyanine and thiophene derivatives. The OECTs are also applied as transducers to detect a biomarker related to neurological diseases, the neurotransmitter dopamine. The self‐curled OECTs update the premises of electrochemical energy conversion in liquid‐gated transistors, yielding a substantial performance improvement and new chemical sensing capabilities within picoliter sampling volumes.

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Edge-driven nanomembrane-based vertical organic transistors showing a multi-sensing capability

Cited by 39 publications

References 66 publications

Reorganization Energy upon Controlled Intermolecular Charge‐Transfer Reactions in Monolithically Integrated Nanodevices

Reorganization Energy upon Controlled Intermolecular Charge‐Transfer Reactions in Monolithically Integrated Nanodevices

High‐Performance Ultrathin Molecular Rectifying Diodes Based on Organic/Inorganic Interface Engineering

Ultrahigh‐Gain Organic Electrochemical Transistor Chemosensors Based on Self‐Curled Nanomembranes

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