Comment on “How green is blue hydrogen?”

Matteo C. Romano; Cristina Antonini; André Bardow; Valentin Bertsch; Nigel P. Brandon; Jack Brouwer; Stefano Campanari; Luigi Crema; Paul E. Dodds; Stefania Gardarsdottir; Matteo Gazzani; Gert Jan Kramer; Peter D. Lund; Niall Mac Dowell; Emanuele Martelli; Luca Mastropasqua; Russell C. McKenna; Juliana Garcia Moretz-Sohn Monteiro; Nicola Paltrinieri; Bruno G. Pollet; Jeffrey G. Reed; Thomas J. Schmidt; Jaap Vente; Dianne Wiley

doi:10.1002/ese3.1126

Comment on “How green is blue hydrogen?”

Matteo C. Romano^* (Corresponding Author), Cristina Antonini, André Bardow, Valentin Bertsch, Nigel P. Brandon, Jack Brouwer, Stefano Campanari, Luigi Crema, Paul E. Dodds, Stefania Gardarsdottir, Matteo Gazzani, Gert Jan Kramer, Peter D. Lund, Niall Mac Dowell, Emanuele Martelli, Luca Mastropasqua, Russell C. McKenna, Juliana Garcia Moretz-Sohn Monteiro, Nicola Paltrinieri, Bruno G. PolletJeffrey G. Reed, Thomas J. Schmidt, Jaap Vente, Dianne Wiley

^*Corresponding author for this work

Research output: Contribution to journal › Comment/debate › peer-review

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Abstract

This paper is written in response to the paper ?How green is blue hydrogen?? by R. W. Howarth and M. Z. Jacobson. It aims at highlighting and discussing the method and assumptions of that paper, and thereby providing a more balanced perspective on blue hydrogen, which is in line with current best available practices and future plant specifications aiming at low CO2 emissions. More specifically, in this paper, we show that: (i) the simplified method that Howarth and Jacobson used to compute the energy balance of blue hydrogen plants leads to significant overestimation of CO2 emissions and natural gas (NG) consumption and (ii) the assumed methane leakage rate is at the high end of the estimated emissions from current NG production in the United States and cannot be considered representative of all-NG and blue hydrogen value chains globally. By starting from the detailed and rigorously calculated mass and energy balances of two blue hydrogen plants in the literature, we show the impact that methane leakage rate has on the equivalent CO2 emissions of blue hydrogen. On the basis of our analysis, we show that it is possible for blue hydrogen to have significantly lower equivalent CO2 emissions than the direct use of NG, provided that hydrogen production processes and CO2 capture technologies are implemented that ensure a high CO2 capture rate, preferably above 90%, and a low-emission NG supply chain.

Original language	English
Pages (from-to)	1944-1954
Number of pages	11
Journal	Energy Science & Engineering
Volume	10
Issue number	7
Early online date	29 Mar 2022
DOIs	https://doi.org/10.1002/ese3.1126
Publication status	Published - 1 Jul 2022

Keywords

carbon capture
CCS
hydrogen
natural gas

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited. © 2022 The Authors. Energy Science & Engineering published by the Society of Chemical Industry and John Wiley & Sons Ltd. https://creativecommons.org/licenses/by/4.0/
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Romano, M. C., Antonini, C., Bardow, A., Bertsch, V., Brandon, N. P., Brouwer, J., Campanari, S., Crema, L., Dodds, P. E., Gardarsdottir, S., Gazzani, M., Jan Kramer, G., Lund, P. D., Mac Dowell, N., Martelli, E., Mastropasqua, L., McKenna, R. C., Monteiro, J. G. M.-S., Paltrinieri, N., ... Wiley, D. (2022). Comment on “How green is blue hydrogen?”. Energy Science & Engineering, 10(7), 1944-1954. https://doi.org/10.1002/ese3.1126

Romano, MC, Antonini, C, Bardow, A, Bertsch, V, Brandon, NP, Brouwer, J, Campanari, S, Crema, L, Dodds, PE, Gardarsdottir, S, Gazzani, M, Jan Kramer, G, Lund, PD, Mac Dowell, N, Martelli, E, Mastropasqua, L, McKenna, RC, Monteiro, JGM-S, Paltrinieri, N, Pollet, BG, Reed, JG, Schmidt, TJ, Vente, J & Wiley, D 2022, 'Comment on “How green is blue hydrogen?”', Energy Science & Engineering, vol. 10, no. 7, pp. 1944-1954. https://doi.org/10.1002/ese3.1126

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abstract = "This paper is written in response to the paper ?How green is blue hydrogen?? by R. W. Howarth and M. Z. Jacobson. It aims at highlighting and discussing the method and assumptions of that paper, and thereby providing a more balanced perspective on blue hydrogen, which is in line with current best available practices and future plant specifications aiming at low CO2 emissions. More specifically, in this paper, we show that: (i) the simplified method that Howarth and Jacobson used to compute the energy balance of blue hydrogen plants leads to significant overestimation of CO2 emissions and natural gas (NG) consumption and (ii) the assumed methane leakage rate is at the high end of the estimated emissions from current NG production in the United States and cannot be considered representative of all-NG and blue hydrogen value chains globally. By starting from the detailed and rigorously calculated mass and energy balances of two blue hydrogen plants in the literature, we show the impact that methane leakage rate has on the equivalent CO2 emissions of blue hydrogen. On the basis of our analysis, we show that it is possible for blue hydrogen to have significantly lower equivalent CO2 emissions than the direct use of NG, provided that hydrogen production processes and CO2 capture technologies are implemented that ensure a high CO2 capture rate, preferably above 90%, and a low-emission NG supply chain.",

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AU - Brouwer, Jack

AU - Campanari, Stefano

AU - Crema, Luigi

AU - Dodds, Paul E.

AU - Gardarsdottir, Stefania

AU - Gazzani, Matteo

AU - Jan Kramer, Gert

AU - Lund, Peter D.

AU - Mac Dowell, Niall

AU - Martelli, Emanuele

AU - Mastropasqua, Luca

AU - McKenna, Russell C.

AU - Monteiro, Juliana Garcia Moretz-Sohn

AU - Paltrinieri, Nicola

AU - Pollet, Bruno G.

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AB - This paper is written in response to the paper ?How green is blue hydrogen?? by R. W. Howarth and M. Z. Jacobson. It aims at highlighting and discussing the method and assumptions of that paper, and thereby providing a more balanced perspective on blue hydrogen, which is in line with current best available practices and future plant specifications aiming at low CO2 emissions. More specifically, in this paper, we show that: (i) the simplified method that Howarth and Jacobson used to compute the energy balance of blue hydrogen plants leads to significant overestimation of CO2 emissions and natural gas (NG) consumption and (ii) the assumed methane leakage rate is at the high end of the estimated emissions from current NG production in the United States and cannot be considered representative of all-NG and blue hydrogen value chains globally. By starting from the detailed and rigorously calculated mass and energy balances of two blue hydrogen plants in the literature, we show the impact that methane leakage rate has on the equivalent CO2 emissions of blue hydrogen. On the basis of our analysis, we show that it is possible for blue hydrogen to have significantly lower equivalent CO2 emissions than the direct use of NG, provided that hydrogen production processes and CO2 capture technologies are implemented that ensure a high CO2 capture rate, preferably above 90%, and a low-emission NG supply chain.

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KW - natural gas

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M3 - Comment/debate

SN - 2050-0505

VL - 10

SP - 1944

EP - 1954

JO - Energy Science & Engineering

JF - Energy Science & Engineering

IS - 7

ER -

Comment on “How green is blue hydrogen?”

Abstract

Keywords

UN SDGs

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