In situ 13C DEPT-MRI as a tool to spatially resolve chemical conversion and selectivity of a heterogeneous catalytic reaction occurring in a fixed-bed reactor.

Journal article

B. Akpa, M. Mantle, A. Sederman, L. Gladden
Chemical communications, 2005

Cite

APA Click to copy
Akpa, B., Mantle, M., Sederman, A., & Gladden, L. (2005). In situ 13C DEPT-MRI as a tool to spatially resolve chemical conversion and selectivity of a heterogeneous catalytic reaction occurring in a fixed-bed reactor. Chemical Communications.

Chicago/Turabian Click to copy
Akpa, B., M. Mantle, A. Sederman, and L. Gladden. “In Situ 13C DEPT-MRI as a Tool to Spatially Resolve Chemical Conversion and Selectivity of a Heterogeneous Catalytic Reaction Occurring in a Fixed-Bed Reactor.” Chemical communications (2005).

MLA Click to copy
Akpa, B., et al. “In Situ 13C DEPT-MRI as a Tool to Spatially Resolve Chemical Conversion and Selectivity of a Heterogeneous Catalytic Reaction Occurring in a Fixed-Bed Reactor.” Chemical Communications, 2005.

BibTeX Click to copy

@article{b2005a,
  title = {In situ 13C DEPT-MRI as a tool to spatially resolve chemical conversion and selectivity of a heterogeneous catalytic reaction occurring in a fixed-bed reactor.},
  year = {2005},
  journal = {Chemical communications},
  author = {Akpa, B. and Mantle, M. and Sederman, A. and Gladden, L.}
}

Abstract

The distortionless enhancement by polarisation transfer (DEPT) nuclear magnetic resonance (NMR) technique, combined with magnetic resonance imaging (MRI), has been used to provide the first in situ spatially-resolved and quantitative measurement of chemical conversion and selectivity within a fixed-bed reactor using natural abundance 13C NMR.