Publication detail

Advances in Designing 3D-Printed Systems for CO2 Reduction

KANDAMBATH PADINJAREVEETIL, A. PUMERA, M.

Original Title

Advances in Designing 3D-Printed Systems for CO2 Reduction

Type

journal article in Web of Science

Language

English

Original Abstract

The increasing level of atmospheric carbon dioxide (CO2), and the resultant global warming is a matter of growing concern among scientists, environmentalists, and climate experts across the globe over the past several decades. Numerous attempts are being undertaken today that seek solutions to mitigate this global crisis. This includes designing functional catalysts, devices and reactors to convert greenhouse gasses such as CO2 into useful products like low-carbon fuels and chemicals, thereby reducing the amount of CO2 considerably in the atmosphere. Advancements in emerging technologies like 3D-printing can effectively aid in the fabrication of electrodes and devices to tackle the rising CO2 concerns. Low cost, rapid prototyping ability, and printing simple and complex structure are few of the significant merits of this technology. Thus, in this perspective article, discussions on fabricating 3D-printed (electro)catalysts, customized devices, reactors, etc., via multiple strategies are put forward with emphasis on the electrochemical reduction of CO2. Also, a detailed discussion on the post-printing treatments, catalyst modifications, and other CO2 mitigation strategies is provided as well. Although studies in this direction are scarcely reported, observations made hitherto show promising possibilities of broadening this field for large scale CO2 reduction reaction applications, and similar catalytic applications in the near future.

Keywords

3D printing; carbon dioxide; CO2 capture; CO2 reduction reaction; electrocatalytic reduction; electrochemistry

Authors

KANDAMBATH PADINJAREVEETIL, A.; PUMERA, M.

Released

1. 3. 2022

Publisher

WILEY

Location

HOBOKEN

ISBN

2196-7350

Periodical

Advanced Materials Interfaces

Year of study

10

Number

8

State

Federal Republic of Germany

Pages from

1

Pages to

19

Pages count

19

URL

BibTex

@article{BUT183755,
  author="Akshay Kumar {Kandambath Padinjareveetil} and Martin {Pumera}",
  title="Advances in Designing 3D-Printed Systems for CO2 Reduction",
  journal="Advanced Materials Interfaces",
  year="2022",
  volume="10",
  number="8",
  pages="1--19",
  doi="10.1002/admi.202201734",
  issn="2196-7350",
  url="https://onlinelibrary.wiley.com/doi/10.1002/admi.202201734"
}