Your search keyword '"Medlín, Rostislav"' showing total 3 results

1. TaS3 Nanofibers: Layered Trichalcogenide for 2 High-Performance Electronic and Sensing 3 Devices

Author

Mayorga-Martínez, Carmen C., Sofer, Zdeněk B., Luxa, Jan, Huber, Štěpán P., Sedmidubský, David, Brázda, Petr, Palatinus, Lukáš, Mikulics, Martin, Lazar, Petr, Medlín, Rostislav, and Pumera, Martin

Subjects

vrstevný trisulfid, plynový senzor, fotodetektory, tranzistory řízené polem, vzdušné znečišťující látky, layered trisulfide, gas sensor, photodetector, field-effect transistor, air pollutants

Abstract

Vrstvené materiály, jako dichalcogenidy přechodného kovu, vykazují široké spektrum vlastností s obrovským aplikačním potenciálem, zatímco další skupina příbuzných materiálů, vrstevnaté trichalcogenidy přechodných kovů, zůstává neprozkoumaná. Zde uvádíme široký aplikační potenciál tohoto zajímavého strukturního typu vrstveného trisulfidu tantalu připraveného ve formě nanovláken. Tento materiál vykazuje zajímavé přitažlivé elektronické vlastnosti v závislosti na namáhání v tahu. Struktura této tzv. ortorombické fáze TaS3 pěstované ve formě dlouhých nanovláken byla vyřešena a předefinována. Využitím těchto vlastností demonstrujeme vysoce specifický impedimetrický NO senzor na bázi nanovláken TaS3, stejně jako konstrukci fotodetektorů s vynikajícími reakčními vlastnostmi a tranzistory řízeným polem. Různé pružné substráty byly použity pro konstrukci čidla NO. Takové zařízení vykazuje nízký limit detekce 0,48 ppb, což je hodně pod povolenou hodnotou stanovenou agenturou pro ochranu životního prostředí pro NOx (50 ppb). Kromě toho tento NO snímač plynu také vykazoval vynikající selektivitu za přítomnosti společných interferencí vzniklých při spalování paliva. Nanovlákna TaS3 vyráběná ve velkém měřítku vykazovaly vynikající široký aplikační potenciál pro různé typy zařízení zahrnující nanoelektronické, optoelektronické a plynové senzory. Layered materials, like transition metal dichalcogenides, exhibit broad spectra with outstanding properties with huge application potential, whereas another group of related materials, layered transition metal trichalcogenides, remains unexplored. Here, we show the broad application potential of this interesting structural type of layered tantalum trisulfide prepared in a form of nanofibers. This material shows tailorable attractive electronic properties dependent on the tensile strain applied to it. Structure of this so-called orthorhombic phase of TaS3 grown in a form of long nanofibers has been solved and refined. Taking advantage of these capabilities, we demonstrate a highly specific impedimetric NO gas sensor based on TaS3 nano-fibers as well as construction of photodetectors with excellent responsivity and fieldeffect transistors. Various flexible substrates were used for the construction of a NO gas sensor. Such a device exhibits a low limit of detection of 0.48 ppb, well under the allowed value set by environmental agencies for NOx (50 ppb). Moreover, this NO gas sensor also showed excellent selectivity in the presence of common interferences formed during fuel combustion. TaS3 nanofibers produced in large scale exhibited excellent broad application potential for various types of devices covering nanoelectronic, optoelectronic, and gas-sensing applications

Published

2018

2. Chemical-Dealloying-Derived PtPdPb-Based Multimetallic Nanoparticles: Dimethyl Ether Electrocatalysis and Fuel Cell Application.

Author

Gebru MG, Subramanian P, Bělský P, Yadav RS, Pitussi I, Sasi S, Medlín R, Minar J, Švec P, Kornweitz H, and Schechter A

Abstract

In this work, we report a novel multimetallic nanoparticle catalyst composed of Pt, Pd, and Pb and its electrochemical activity toward dimethyl ether (DME) oxidation in liquid electrolyte and polymer electrolyte fuel cells. Chemical dealloying of the catalyst with the lowest platinum-group metal (PGM) content, Pt 2 PdPb 2 /C, was conducted using HNO 3 to tune the catalyst activity. Comprehensive characterization of the chemical-dealloying-derived catalyst nanoparticles unambiguously showed that the acid treatment removed 50% Pb from the nanoparticles with an insignificant effect on the PGM metals and led to the formation of smaller-sized nanoparticles. Electrochemical studies showed that Pb dissolution led to structural changes in the original catalysts. Chemical-dealloying-derived catalyst nanoparticles made of multiple phases (Pt, Pt 3 Pb, PtPb) provided one of the highest PGM-normalized power densities of 118 mW mg PGM -1 in a single direct DME fuel cell operated at low anode catalyst loading (1 mg PGM cm -2 ) at 70 °C. A possible DME oxidation pathway for these multimetallic catalysts was proposed based on an online mass spectrometry study and the analysis of the reaction products.

Published

2023

3. TaS 3 Nanofibers: Layered Trichalcogenide for High-Performance Electronic and Sensing Devices.

Author

Mayorga-Martinez CC, Sofer Z, Luxa J, Huber Š, Sedmidubský D, Brázda P, Palatinus L, Mikulics M, Lazar P, Medlín R, and Pumera M

Abstract

Layered materials, like transition metal dichalcogenides, exhibit broad spectra with outstanding properties with huge application potential, whereas another group of related materials, layered transition metal trichalcogenides, remains unexplored. Here, we show the broad application potential of this interesting structural type of layered tantalum trisulfide prepared in a form of nanofibers. This material shows tailorable attractive electronic properties dependent on the tensile strain applied to it. Structure of this so-called orthorhombic phase of TaS 3 grown in a form of long nanofibers has been solved and refined. Taking advantage of these capabilities, we demonstrate a highly specific impedimetric NO gas sensor based on TaS 3 nanofibers as well as construction of photodetectors with excellent responsivity and field-effect transistors. Various flexible substrates were used for the construction of a NO gas sensor. Such a device exhibits a low limit of detection of 0.48 ppb, well under the allowed value set by environmental agencies for NO x (50 ppb). Moreover, this NO gas sensor also showed excellent selectivity in the presence of common interferences formed during fuel combustion. TaS 3 nanofibers produced in large scale exhibited excellent broad application potential for various types of devices covering nanoelectronic, optoelectronic, and gas-sensing applications.

Published

2018