☆ 4.7 Article

Enhanced CO2 capture capacities and efficiencies with N-doped nanoporous carbons synthesized from solvent-modulated, pyridinedicarboxylate-containing Zn-MOFs

CRYSTENGCOMM (2015)

Journal

CRYSTENGCOMM

Volume 17, Issue 42, Pages 8015-8020

Publisher

ROYAL SOC CHEMISTRY

DOI: 10.1039/c5ce00828j

Keywords

Funding

University of Notre Dame

Ask authors/readers for more resources

Protocol

Community support

Reagent

Community support

Abstract

This paper describes the pyrolysis of pyridinedicarboxylate-containing Zn-based metal-organic frameworks (MOFs) to form nanoporous carbons with accessible N dopants to adsorb CO2. The optimal materials were synthesized using N-heterocycle additives to control the amount of coordinated DMF in the base MOF structure, thereby increasing its thermal stability prior to pyrolysis.

Authors

I am an author on this paper

Click your name to claim this paper and add it to your profile.

Reviews

Primary Rating

4.7

Not enough ratings

Enhanced CO2 capture capacities and efficiencies with N-doped nanoporous carbons synthesized from solvent-modulated, pyridinedicarboxylate-containing Zn-MOFs

Journal

CRYSTENGCOMM

Publisher

ROYAL SOC CHEMISTRY

Keywords

Categories

Funding

Ask authors/readers for more resources

Protocol

Reagent

Authors

I am an author on this paper

Reviews

Primary Rating

Secondary Ratings

Novelty

Significance

Scientific rigor

Rate this paper

Recommended

Enhanced CO2 capture capacities and efficiencies with N-doped nanoporous carbons synthesized from solvent-modulated, pyridinedicarboxylate-containing Zn-MOFs

Journal

CRYSTENGCOMM

Publisher

ROYAL SOC CHEMISTRY

Keywords

Categories

Funding

Ask authors/readers for more resources

Protocol

Reagent

Authors

I am an author on this paper

Reviews

Primary Rating

Secondary Ratings

Novelty

Significance

Scientific rigor

Rate this paper

Recommended

Export Citation

Share Paper