Publication result detail

2D Methyl Germanane Enhanced 3D Printed Photoelectrodes

NITTOOR VEEDU, R.; NG, S.; SANNA, M.; PUMERA, M.

Original Title

2D Methyl Germanane Enhanced 3D Printed Photoelectrodes

English Title

2D Methyl Germanane Enhanced 3D Printed Photoelectrodes

Type

WoS Article

Original Abstract

3D printing is a cutting-edge technology, that allows the printing of 3D objects according to the design provided. Nanocarbon electrodes that can be fabricated using 3D printing technology, suffer from a lack of required properties. For enhancing the photoelectrochemical properties of 3D printed electrodes, functionalized germanenes, belonging to the family of 2D materials are used here. Functionalized germananes are becoming popular for application in photoelectrochemical processes, due to their photoactivity in the visible spectral region and their tunable optoelectronic properties, thanks to covalent functionalization. It is shown that 2D methyl germanane has great potential for photoelectrocatalytic enhancement of 3D printed structures, and this potential goes beyond the demonstrated application of water splitting. 3D printing technology allows for the creation of 3D electrodes, however, printed devices lack certain properties. To improve the photoelectrochemical properties of these electrodes, functionalized 2D germananes can be beneficial and the enhancement of photoelectrocatalytic performance extending with applications beyond water splitting.image

English abstract

3D printing is a cutting-edge technology, that allows the printing of 3D objects according to the design provided. Nanocarbon electrodes that can be fabricated using 3D printing technology, suffer from a lack of required properties. For enhancing the photoelectrochemical properties of 3D printed electrodes, functionalized germanenes, belonging to the family of 2D materials are used here. Functionalized germananes are becoming popular for application in photoelectrochemical processes, due to their photoactivity in the visible spectral region and their tunable optoelectronic properties, thanks to covalent functionalization. It is shown that 2D methyl germanane has great potential for photoelectrocatalytic enhancement of 3D printed structures, and this potential goes beyond the demonstrated application of water splitting. 3D printing technology allows for the creation of 3D electrodes, however, printed devices lack certain properties. To improve the photoelectrochemical properties of these electrodes, functionalized 2D germananes can be beneficial and the enhancement of photoelectrocatalytic performance extending with applications beyond water splitting.image

Keywords

2D materials; additive manufacturing; photochemistry

Key words in English

2D materials; additive manufacturing; photochemistry

Authors

NITTOOR VEEDU, R.; NG, S.; SANNA, M.; PUMERA, M.

RIV year

2025

Released

01.03.2024

Publisher

WILEY

Location

HOBOKEN

ISBN

2196-7350

Periodical

Advanced Materials Interfaces

Volume

11

Number

7

State

Federal Republic of Germany

Pages count

5

URL

https://onlinelibrary.wiley.com/doi/10.1002/admi.202300557

Full text in the Digital Library

http://hdl.handle.net/11012/249987

BibTex

@article{BUT187155,
  author="Radhika {Nittoor Veedu} and Siow Woon {Ng} and Michela {Sanna} and Martin {Pumera}",
  title="2D Methyl Germanane Enhanced 3D Printed Photoelectrodes",
  journal="Advanced Materials Interfaces",
  year="2024",
  volume="11",
  number="7",
  pages="5",
  doi="10.1002/admi.202300557",
  issn="2196-7350",
  url="https://onlinelibrary.wiley.com/doi/10.1002/admi.202300557"
}

Documents

AdvMaterialsInter-2023-Nittoor‐Veedu