Energy Efficiency and Sustainability Assessment for Methane Harvesting from Lake Kivu

Natanael Bolson; Maxim Yutkin; Tadeusz Patzek

doi:10.1016/j.energy.2021.120215

Energy Efficiency and Sustainability Assessment for Methane Harvesting from Lake Kivu

Natanael Bolson, Maxim Yutkin, Tadeusz Patzek^*

^*Corresponding author for this work

Mechanical Engineering

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Abstract

Lake Kivu is a great environmental and economic resource in Rwanda. Its deep-water methane reservoir can help the country to narrow its energy supply gap. However, mishandling of the lake could lead to devastating consequences, from potable water contamination to limnic eruption. To evaluate the lake’s potential for energy harvesting, we have developed a numerical model and validated it experimentally. Based on this model, we propose an optimal methane harvesting strategy. The harvesting efficiency improvement is from 4 to 6% relative to the alternatives. While seemingly insignificant, a 1% improvement of harvesting efficiency extends the operational time of a gas power plant by ∼5%. With these improvements, the lake will sustainably supply 100 MW of electricity for up to 100 years. Potential CO₂ emissions are negligible in comparison with the low-emitting developed countries. We conclude that forestry and agroforestry can mitigate CO₂ emissions and reduce currently widespread deforestation. The degassed water after methane extraction poses another environmental concern. It must be reinjected at the depth of 190–250 m to minimize the environmental impacts on the lake and allow for continuous methane harvesting.

Original language	English
Article number	120215
Number of pages	11
Journal	Energy
Volume	225
Early online date	4 Mar 2021
DOIs	https://doi.org/10.1016/j.energy.2021.120215
Publication status	Published - 15 Jun 2021

Keywords

Rwanda
Double diffusion-convection
Limnic eruption
Eutrophication
Deforestation
PHREEQC

UN SDGs

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

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10.1016/j.energy.2021.120215Licence: Creative Commons: Attribution (CC BY)

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@article{2e702f5f21e64cc2a4571c765d236fec,

title = "Energy Efficiency and Sustainability Assessment for Methane Harvesting from Lake Kivu",

abstract = "Lake Kivu is a great environmental and economic resource in Rwanda. Its deep-water methane reservoir can help the country to narrow its energy supply gap. However, mishandling of the lake could lead to devastating consequences, from potable water contamination to limnic eruption. To evaluate the lake{\textquoteright}s potential for energy harvesting, we have developed a numerical model and validated it experimentally. Based on this model, we propose an optimal methane harvesting strategy. The harvesting efficiency improvement is from 4 to 6% relative to the alternatives. While seemingly insignificant, a 1% improvement of harvesting efficiency extends the operational time of a gas power plant by ∼5%. With these improvements, the lake will sustainably supply 100 MW of electricity for up to 100 years. Potential CO2 emissions are negligible in comparison with the low-emitting developed countries. We conclude that forestry and agroforestry can mitigate CO2 emissions and reduce currently widespread deforestation. The degassed water after methane extraction poses another environmental concern. It must be reinjected at the depth of 190–250 m to minimize the environmental impacts on the lake and allow for continuous methane harvesting.",

keywords = "Rwanda, Double diffusion-convection, Limnic eruption, Eutrophication, Deforestation, PHREEQC",

author = "Natanael Bolson and Maxim Yutkin and Tadeusz Patzek",

year = "2021",

month = jun,

day = "15",

doi = "10.1016/j.energy.2021.120215",

language = "English",

volume = "225",

journal = "Energy",

issn = "0360-5442",

publisher = "Elsevier Korea",

}

TY - JOUR

T1 - Energy Efficiency and Sustainability Assessment for Methane Harvesting from Lake Kivu

AU - Bolson, Natanael

AU - Yutkin, Maxim

AU - Patzek, Tadeusz

PY - 2021/6/15

Y1 - 2021/6/15

N2 - Lake Kivu is a great environmental and economic resource in Rwanda. Its deep-water methane reservoir can help the country to narrow its energy supply gap. However, mishandling of the lake could lead to devastating consequences, from potable water contamination to limnic eruption. To evaluate the lake’s potential for energy harvesting, we have developed a numerical model and validated it experimentally. Based on this model, we propose an optimal methane harvesting strategy. The harvesting efficiency improvement is from 4 to 6% relative to the alternatives. While seemingly insignificant, a 1% improvement of harvesting efficiency extends the operational time of a gas power plant by ∼5%. With these improvements, the lake will sustainably supply 100 MW of electricity for up to 100 years. Potential CO2 emissions are negligible in comparison with the low-emitting developed countries. We conclude that forestry and agroforestry can mitigate CO2 emissions and reduce currently widespread deforestation. The degassed water after methane extraction poses another environmental concern. It must be reinjected at the depth of 190–250 m to minimize the environmental impacts on the lake and allow for continuous methane harvesting.

AB - Lake Kivu is a great environmental and economic resource in Rwanda. Its deep-water methane reservoir can help the country to narrow its energy supply gap. However, mishandling of the lake could lead to devastating consequences, from potable water contamination to limnic eruption. To evaluate the lake’s potential for energy harvesting, we have developed a numerical model and validated it experimentally. Based on this model, we propose an optimal methane harvesting strategy. The harvesting efficiency improvement is from 4 to 6% relative to the alternatives. While seemingly insignificant, a 1% improvement of harvesting efficiency extends the operational time of a gas power plant by ∼5%. With these improvements, the lake will sustainably supply 100 MW of electricity for up to 100 years. Potential CO2 emissions are negligible in comparison with the low-emitting developed countries. We conclude that forestry and agroforestry can mitigate CO2 emissions and reduce currently widespread deforestation. The degassed water after methane extraction poses another environmental concern. It must be reinjected at the depth of 190–250 m to minimize the environmental impacts on the lake and allow for continuous methane harvesting.

KW - Rwanda

KW - Double diffusion-convection

KW - Limnic eruption

KW - Eutrophication

KW - Deforestation

KW - PHREEQC

UR - http://hdl.handle.net/10754/667899

U2 - 10.1016/j.energy.2021.120215

DO - 10.1016/j.energy.2021.120215

M3 - Article

SN - 0360-5442

VL - 225

JO - Energy

JF - Energy

M1 - 120215

ER -

Energy Efficiency and Sustainability Assessment for Methane Harvesting from Lake Kivu

Abstract

Keywords

UN SDGs

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