Issue 13, 2014

Towards a carbon independent and CO2-free electrochemical membrane process for NH3 synthesis

Abstract

Ammonia is exclusively synthesized by the Haber–Bosch process starting from precious carbon resources such as coal or CH4. With H2O, H2 is produced and with N2, NH3 can be synthesized at high pressures and temperatures. Regrettably, the carbon is not incorporated into NH3 but emitted as CO2. Valuable carbon sources are consumed which could be used otherwise when carbon sources become scarce. We suggest an alternative process concept using an electrochemical membrane reactor (ecMR). A complete synthesis process with N2 production and downstream product separation is presented and evaluated in a multi-scale model to quantify its energy consumption. A new micro-scale ecMR model integrates mass, species, heat and energy balances with electrochemical conversions allowing further integration into a macro-scale process flow sheet. For the anodic oxidation reaction H2O was chosen as a ubiquitous H2 source. Nitrogen was obtained by air separation which combines with protons from H2O to give NH3 using a hypothetical catalyst recently suggested from DFT calculations. The energy demand of the whole electrochemical process is up to 20% lower than the Haber–Bosch process using coal as a H2 source. In the case of natural gas, the ecMR process is not competitive under today's energy and resource conditions. In future however, the electrochemical NH3 synthesis might be the technology-of-choice when coal is easily accessible over natural gas or limited carbon sources have to be used otherwise but for the synthesis of the carbon free product NH3.

Graphical abstract: Towards a carbon independent and CO2-free electrochemical membrane process for NH3 synthesis

Supplementary files

Article information

Article type
Paper
Submitted
13 Jan 2014
Accepted
06 Feb 2014
First published
06 Feb 2014

Phys. Chem. Chem. Phys., 2014,16, 6129-6138

Author version available

Towards a carbon independent and CO2-free electrochemical membrane process for NH3 synthesis

K. Kugler, B. Ohs, M. Scholz and M. Wessling, Phys. Chem. Chem. Phys., 2014, 16, 6129 DOI: 10.1039/C4CP00173G

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