Public Reference Data for Megawatt-Scale Hydrogen Electrolysis - NLR Historical Solar PV
The U.S. Department of Energy and National Laboratory of the Rockies (NLR) demonstrate hydrogen electrolysis from variable sources, hydrogen compression and storage, and hydrogen fuel cell power production using megawatt-scale equipment at NLR?s Flatirons Campus as part of the Advanced Research on Integrated Energy Systems (ARIES) research platform. This dataset represents part of that effort and is intended for academic, national laboratory, industrial, and other stakeholders to plan, design, and validate models of megawatt-scale hydrogen technologies and diverse energy infrastructure nationwide. These data provide a baseline for how existing hydrogen electrolysis technologies perform when coupled with various energy technologies. Future datasets will demonstrate how existing hydrogen fuel cell technologies can provide controllable, dispatchable, and variable power output for artificial intelligence data centers and other variable loads. This dataset entry describes the behavior of a 1.25-MW proton exchange membrane MC250 electrolyzer system, manufactured by Nel Hydrogen,[1] when fed historical data generated by the 430-kW, fixed-axis solar photovoltaic (PV) array located at NLR?s Flatirons Campus. (While the electrolyzer balance of plant supports up to 2.5 MW of electrolysis, NLR only has a single 1.25-MW electrolysis stack.)Solar PV power output data for the 2020 calendar year were categorized on a daily basis by total energy generation and standard deviation. Each day was then ranked by these metrics, and the 25th, 50th, and 100th percentiles were selected. The 75th percentile day did not exhibit sufficient variability to make for a valuable experiment. A similar process was used for the related historical wind dataset.[2] The historical days in 2020 that represented these percentiles are Dec. 19, March 29, and May 4, respectively. The entire solar day?s power profile was then fed through the MC250 electrolyzer.Due to its length, the 100th percentile day experiment was split into two parts, and the final 3 hours of the solar day were not captured. These final 3 hours contained no spikes or dips of interest and simply represented a slow decay of input solar power. Also, a single timestamp (13:13:47 on Jan. 14, 2026) was lost in the hydrogen system supervisory control and data acquisition. Finally, during the 25th percentile experiment (solar day Dec. 19, 2020) data recording was lost from 11:00:13 to 11:14:45. The roughly 15 minutes of the solar profile were rerun at the end of the experiment and spliced into this time slot during post-processing. The electrolysis system controls hydrogen production by varying direct current applied to the stack, from a maximum of 3,000 A to a minimum safe operation of 300 A, or 10%. Because the current?voltage characteristic changes as the stack ages and efficiency degrades, the actual minimum safe operating power changes over time. The historical solar profiles were translated from power (kilowatts) to current (amperes) using a curve fit with calibration data and sent to the electrolyzer power supply at 1-Hz frequency. For more details on the statistical analysis process, see the slide deck ?Public Reference Data for Megawatt-Scale Hydrogen Electrolysis: NLR Historical Solar PV Analysis and Profile Generation? accessible with this data entry.These datasets report relevant hydrogen balance-of-plant and system data, all captured at 1 Hz, including hydrogen mass production measured with an Emerson Coriolis flow meter. Each .zip file represents a single solar PV electrolysis experiment and is formatted as:{technology}_{percentile}_{scaling factor}For instance, ?solarPV-430kW_25_2x.zip? reports the experiment using the 25th percentile solar data from the historical 2020 solar PV dataset, scaled to 200%. Scaling factors were applied to the generated solar PV power output files to more closely match the 1.25-MW capacity of the electrolyzer. Each .zip folder contains the following files: A .csv file containing raw data.An .xlsx file explaining all the fields in the raw data.A .png plot showing the time series of hydrogen production, electrolysis power consumption, and solar power input.A PDF file detailing the historical solar data statistical analysis used to generate the solar profile.An experiment labeled ?characterization_200.zip? demonstrates the MC250 electrolyzer steady-state response with 30-minute load steps for a total duration of 5 hours.Finally, a .csv file is provided with all experiments combined into one dataset labeled "combined_solarPV_experiments.csv".[1]nelhydrogen.com/product/mc-series-electrolyser.[2]data.nlr.gov/submissions/316.
Citation Formats
TY - DATA
AB - The U.S. Department of Energy and National Laboratory of the Rockies (NLR) demonstrate hydrogen electrolysis from variable sources, hydrogen compression and storage, and hydrogen fuel cell power production using megawatt-scale equipment at NLR’s Flatirons Campus as part of the Advanced Research on Integrated Energy Systems (ARIES) research platform. This dataset represents part of that effort and is intended for academic, national laboratory, industrial, and other stakeholders to plan, design, and validate models of megawatt-scale hydrogen technologies and diverse energy infrastructure nationwide. These data provide a baseline for how existing hydrogen electrolysis technologies perform when coupled with various energy technologies. Future datasets will demonstrate how existing hydrogen fuel cell technologies can provide controllable, dispatchable, and variable power output for artificial intelligence data centers and other variable loads. This dataset entry describes the behavior of a 1.25-MW proton exchange membrane MC250 electrolyzer system, manufactured by Nel Hydrogen,[1] when fed historical data generated by the 430-kW, fixed-axis solar photovoltaic (PV) array located at NLR’s Flatirons Campus. (While the electrolyzer balance of plant supports up to 2.5 MW of electrolysis, NLR only has a single 1.25-MW electrolysis stack.)Solar PV power output data for the 2020 calendar year were categorized on a daily basis by total energy generation and standard deviation. Each day was then ranked by these metrics, and the 25th, 50th, and 100th percentiles were selected. The 75th percentile day did not exhibit sufficient variability to make for a valuable experiment. A similar process was used for the related historical wind dataset.[2] The historical days in 2020 that represented these percentiles are Dec. 19, March 29, and May 4, respectively. The entire solar day’s power profile was then fed through the MC250 electrolyzer.Due to its length, the 100th percentile day experiment was split into two parts, and the final 3 hours of the solar day were not captured. These final 3 hours contained no spikes or dips of interest and simply represented a slow decay of input solar power. Also, a single timestamp (13:13:47 on Jan. 14, 2026) was lost in the hydrogen system supervisory control and data acquisition. Finally, during the 25th percentile experiment (solar day Dec. 19, 2020) data recording was lost from 11:00:13 to 11:14:45. The roughly 15 minutes of the solar profile were rerun at the end of the experiment and spliced into this time slot during post-processing. The electrolysis system controls hydrogen production by varying direct current applied to the stack, from a maximum of 3,000 A to a minimum safe operation of 300 A, or 10%. Because the current–voltage characteristic changes as the stack ages and efficiency degrades, the actual minimum safe operating power changes over time. The historical solar profiles were translated from power (kilowatts) to current (amperes) using a curve fit with calibration data and sent to the electrolyzer power supply at 1-Hz frequency. For more details on the statistical analysis process, see the slide deck “Public Reference Data for Megawatt-Scale Hydrogen Electrolysis: NLR Historical Solar PV Analysis and Profile Generation” accessible with this data entry.These datasets report relevant hydrogen balance-of-plant and system data, all captured at 1 Hz, including hydrogen mass production measured with an Emerson Coriolis flow meter. Each .zip file represents a single solar PV electrolysis experiment and is formatted as:{technology}_{percentile}_{scaling factor}For instance, “solarPV-430kW_25_2x.zip” reports the experiment using the 25th percentile solar data from the historical 2020 solar PV dataset, scaled to 200%. Scaling factors were applied to the generated solar PV power output files to more closely match the 1.25-MW capacity of the electrolyzer. Each .zip folder contains the following files: A .csv file containing raw data.An .xlsx file explaining all the fields in the raw data.A .png plot showing the time series of hydrogen production, electrolysis power consumption, and solar power input.A PDF file detailing the historical solar data statistical analysis used to generate the solar profile.An experiment labeled “characterization_200.zip” demonstrates the MC250 electrolyzer steady-state response with 30-minute load steps for a total duration of 5 hours.Finally, a .csv file is provided with all experiments combined into one dataset labeled "combined_solarPV_experiments.csv".[1]nelhydrogen.com/product/mc-series-electrolyser.[2]data.nlr.gov/submissions/316.
AU - Abel, Riley
A2 - Schwarz, Marty
A3 - Leighton, Daniel
A4 - Nagasawa, Kazunori
DB - Open Energy Data Initiative (OEDI)
DP - Open EI | National Laboratory of the Rockies
DO -
KW - hydrogen
KW - electrolysis
KW - proton exchange membrane electrolyzer
KW - hydrogen production
KW - energy storage
KW - ARIES
KW - ECaSS
KW - HyPPS
KW - Alternative Fuels and Feedstock Office
KW - direct solar irradiance
KW - solar photovoltaic
KW - solar power
KW - PV photovoltaic solar energy
LA - English
DA - 2026/06/15
PY - 2026
PB - National Laboratory of the Rockies
T1 - Public Reference Data for Megawatt-Scale Hydrogen Electrolysis - NLR Historical Solar PV
UR - https://data.openei.org/submissions/8711
ER -
Abel, Riley, et al. Public Reference Data for Megawatt-Scale Hydrogen Electrolysis - NLR Historical Solar PV. National Laboratory of the Rockies, 15 June, 2026, NREL. https://data.nlr.gov/submissions/318.
Abel, R., Schwarz, M., Leighton, D., & Nagasawa, K. (2026). Public Reference Data for Megawatt-Scale Hydrogen Electrolysis - NLR Historical Solar PV. [Data set]. NREL. National Laboratory of the Rockies. https://data.nlr.gov/submissions/318
Abel, Riley, Marty Schwarz, Daniel Leighton, and Kazunori Nagasawa. Public Reference Data for Megawatt-Scale Hydrogen Electrolysis - NLR Historical Solar PV. National Laboratory of the Rockies, June, 15, 2026. Distributed by NREL. https://data.nlr.gov/submissions/318
@misc{OEDI_Dataset_8711,
title = {Public Reference Data for Megawatt-Scale Hydrogen Electrolysis - NLR Historical Solar PV},
author = {Abel, Riley and Schwarz, Marty and Leighton, Daniel and Nagasawa, Kazunori},
abstractNote = {The U.S. Department of Energy and National Laboratory of the Rockies (NLR) demonstrate hydrogen electrolysis from variable sources, hydrogen compression and storage, and hydrogen fuel cell power production using megawatt-scale equipment at NLR?s Flatirons Campus as part of the Advanced Research on Integrated Energy Systems (ARIES) research platform. This dataset represents part of that effort and is intended for academic, national laboratory, industrial, and other stakeholders to plan, design, and validate models of megawatt-scale hydrogen technologies and diverse energy infrastructure nationwide. These data provide a baseline for how existing hydrogen electrolysis technologies perform when coupled with various energy technologies. Future datasets will demonstrate how existing hydrogen fuel cell technologies can provide controllable, dispatchable, and variable power output for artificial intelligence data centers and other variable loads.\ This dataset entry describes the behavior of a 1.25-MW proton exchange membrane MC250 electrolyzer system, manufactured by Nel Hydrogen,[1] when fed historical data generated by the 430-kW, fixed-axis solar photovoltaic (PV) array located at NLR?s Flatirons Campus. (While the electrolyzer balance of plant supports up to 2.5 MW of electrolysis, NLR only has a single 1.25-MW electrolysis stack.)Solar PV power output data for the 2020 calendar year were categorized on a daily basis by total energy generation and standard deviation. Each day was then ranked by these metrics, and the 25th, 50th, and 100th percentiles were selected. The 75th percentile day did not exhibit sufficient variability to make for a valuable experiment. A similar process was used for the related historical wind dataset.[2] The historical days in 2020 that represented these percentiles are Dec. 19, March 29, and May 4, respectively. The entire solar day?s power profile was then fed through the MC250 electrolyzer.Due to its length, the 100th percentile day experiment was split into two parts, and the final 3 hours of the solar day were not captured. These final 3 hours contained no spikes or dips of interest and simply represented a slow decay of input solar power. Also, a single timestamp (13:13:47 on Jan. 14, 2026) was lost in the hydrogen system supervisory control and data acquisition. Finally, during the 25th percentile experiment (solar day Dec. 19, 2020) data recording was lost from 11:00:13 to 11:14:45. The roughly 15 minutes of the solar profile were rerun at the end of the experiment and spliced into this time slot during post-processing.\ The electrolysis system controls hydrogen production by varying direct current applied to the stack, from a maximum of 3,000 A to a minimum safe operation of 300 A, or 10\%. Because the current?voltage characteristic changes as the stack ages and efficiency degrades, the actual minimum safe operating power changes over time. The historical solar profiles were translated from power (kilowatts) to current (amperes) using a curve fit with calibration data and sent to the electrolyzer power supply at 1-Hz frequency. For more details on the statistical analysis process, see the slide deck ?Public Reference Data for Megawatt-Scale Hydrogen Electrolysis: NLR Historical Solar PV Analysis and Profile Generation? accessible with this data entry.These datasets report relevant hydrogen balance-of-plant and system data, all captured at 1 Hz, including hydrogen mass production measured with an Emerson Coriolis flow meter. Each .zip file represents a single solar PV electrolysis experiment and is formatted as:{technology}_{percentile}_{scaling factor}For instance, ?solarPV-430kW_25_2x.zip? reports the experiment using the 25th percentile solar data from the historical 2020 solar PV dataset, scaled to 200\%.\ Scaling factors were applied to the generated solar PV power output files to more closely match the 1.25-MW capacity of the electrolyzer.\ Each .zip folder contains the following files:\ A .csv file containing raw data.An .xlsx file explaining all the fields in the raw data.A .png plot showing the time series of hydrogen production, electrolysis power consumption, and solar power input.A PDF file detailing the historical solar data statistical analysis used to generate the solar profile.An experiment labeled ?characterization_200.zip? demonstrates the MC250 electrolyzer steady-state response with 30-minute load steps for a total duration of 5 hours.Finally, a .csv file is provided with all experiments combined into one dataset labeled "combined_solarPV_experiments.csv".[1]nelhydrogen.com/product/mc-series-electrolyser.[2]data.nlr.gov/submissions/316.},
url = {https://data.nlr.gov/submissions/318},
year = {2026},
howpublished = {NREL, National Laboratory of the Rockies, https://data.nlr.gov/submissions/318},
note = {Accessed: 2026-07-13}
}
Details
Data from Jun 15, 2026
Last updated Jun 15, 2026
Submitted Jun 15, 2026
Organization
National Laboratory of the Rockies
Contact
Riley Abel
Authors
Original Source
https://data.nlr.gov/submissions/318Research Areas
Keywords
hydrogen, electrolysis, proton exchange membrane electrolyzer, hydrogen production, energy storage, ARIES, ECaSS, HyPPS, Alternative Fuels and Feedstock Office, direct solar irradiance, solar photovoltaic, solar power, PV photovoltaic solar energyDOE Project Details
Project Name Public Reference Data for Megawatt-Scale Hydrogen Electrolysis Production and Energy Storage Using Fuel Cell Power
Project Number WBS 7.3.0.508

