Publication result detail

Limitations and Benefits of MAX Phases in Electroanalysis

TESAŘ, J.; MUÑOZ MARTIN, J.; PUMERA, M.

Original Title

Limitations and Benefits of MAX Phases in Electroanalysis

English Title

Limitations and Benefits of MAX Phases in Electroanalysis

Type

WoS Article

Original Abstract

MAX phases are a group of layered 2D materials made of early transition metal, A-group element (e.g., Al, Sn or Si), and C or N. These nanolaminated carbides and nitrides combine many attractive characteristics of metals and ceramics such as excellent electric and thermal conductivity and high chemical resistance. Although MAX phases have shown promising electrochemical results in the field of energy conversion, their use for electroanalytical approaches is nowadays an unexplored field. Herein, the potential use of MAX phases for electroanalytical approaches has been investigated. For this aim, seven different MAX phases (Cr2AlC, Mo2AlC, Ta2AlC, Ti2AlN, Ti2SnC, Ti3AlC2, Ti3SiC2, and V2AlC) have been drop-casted upon a conventional glassy-carbon electrode and tested at different pH media, also providing their potential towards the determination of different analytes. Overall, our findings elucidate the limitations and benefits of using MAX phases for electroanalysis, demonstrating that a proper combination of both MAX phases and electrolyte media is a must to direct efficient performances as electrode for electroanalysis. Accordingly, this work provides new knowledge about the electrochemical behaviour of MAX phases and their potential in the field of electronic devices.

English abstract

MAX phases are a group of layered 2D materials made of early transition metal, A-group element (e.g., Al, Sn or Si), and C or N. These nanolaminated carbides and nitrides combine many attractive characteristics of metals and ceramics such as excellent electric and thermal conductivity and high chemical resistance. Although MAX phases have shown promising electrochemical results in the field of energy conversion, their use for electroanalytical approaches is nowadays an unexplored field. Herein, the potential use of MAX phases for electroanalytical approaches has been investigated. For this aim, seven different MAX phases (Cr2AlC, Mo2AlC, Ta2AlC, Ti2AlN, Ti2SnC, Ti3AlC2, Ti3SiC2, and V2AlC) have been drop-casted upon a conventional glassy-carbon electrode and tested at different pH media, also providing their potential towards the determination of different analytes. Overall, our findings elucidate the limitations and benefits of using MAX phases for electroanalysis, demonstrating that a proper combination of both MAX phases and electrolyte media is a must to direct efficient performances as electrode for electroanalysis. Accordingly, this work provides new knowledge about the electrochemical behaviour of MAX phases and their potential in the field of electronic devices.

Keywords

Electroanalysis; catalysis; analytical chemistry; MXene; MAX phases

Key words in English

Electroanalysis; catalysis; analytical chemistry; MXene; MAX phases

Authors

TESAŘ, J.; MUÑOZ MARTIN, J.; PUMERA, M.

RIV year

2023

Released

01.01.2022

Publisher

WILEY-V C H VERLAG GMBH

Location

WEINHEIM

ISBN

1521-4109

Periodical

ELECTROANALYSIS

Volume

34

Number

1

State

Federal Republic of Germany

Pages from

56

Pages to

60

Pages count

5

URL

https://analyticalsciencejournals.onlinelibrary.wiley.com/doi/10.1002/elan.202100473

BibTex

@article{BUT174926,
  author="Jan {Tesař} and Jose Maria {Muñoz Martin} and Martin {Pumera}",
  title="Limitations and Benefits of MAX Phases in Electroanalysis",
  journal="ELECTROANALYSIS",
  year="2022",
  volume="34",
  number="1",
  pages="56--60",
  doi="10.1002/elan.202100473",
  issn="1040-0397",
  url="https://analyticalsciencejournals.onlinelibrary.wiley.com/doi/10.1002/elan.202100473"
}