Wood Vault: remove atmospheric CO2 with trees, store wood for carbon sequestration for now and as biomass, bioenergy and carbon reserve for the future

Background Wood harvesting and storage (WHS) is a hybrid Nature-Engineering combination method to combat climate change by harvesting wood sustainably and storing it semi-permanently for carbon sequestration. To date, the technology has only been purposefully tested in small-scale demonstration proj...

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Published in	Carbon balance and management Vol. 17; no. 1; p. 2
Main Authors	Zeng, Ning, Hausmann, Henry
Format	Journal Article
Language	English
Published	Cham Springer International Publishing 01.04.2022 Springer Nature B.V BMC
Subjects	Agricultural economics Agriculture agrivoltaic systems Agrivoltaics Anaerobic environments Antarctica Anthropocene Anthropocene epoch bioenergy Biomass Biosphere carbon Carbon dioxide Carbon dioxide atmospheric concentrations Carbon dioxide removal carbon markets Carbon sequestration Carbon sinks climate Climate change cold Cold regions Decay decayed wood Deforestation Drawdown Durability Earth and Environmental Science Eastern United States Economic analysis Economic models Economics Ecosystems Environment Environmental Management Forestry forests hybrids Ice ages Landfills Net Primary Productivity prices Primary production prototypes quarries recreation Renewable energy Science and technology Sequestering Siphons Solar farms Solar power generation Storage facilities transportation Underground mines Waste disposal sites Wood Wood construction wood utilization woody biomass United States > US Eastern United States Antarctica
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Abstract	Background Wood harvesting and storage (WHS) is a hybrid Nature-Engineering combination method to combat climate change by harvesting wood sustainably and storing it semi-permanently for carbon sequestration. To date, the technology has only been purposefully tested in small-scale demonstration projects. This study aims to develop a concrete way to carry out WHS at large-scale. Results We describe a method of constructing a wood storage facility, named Wood Vault, that can bury woody biomass on a mega-tonne scale in specially engineered enclosures to ensure anaerobic environments, thus preventing wood decay. The buried wood enters a quasi-geological reservoir that is expected to stay intact semi-permanently. Storing wood in many environments is possible, leading to seven versions of Wood Vault: (1) Burial Mound (Tumulus or Barrow), (2) Underground (Pit, Quarry, or Mine), (3) Super Vault, (4) Shelter, (5) AquaOpen or AquaVault with wood submerged under water, (6) DesertOpen or DesertVault in dry regions, (7) FreezeVault in cold regions such as Antarctica. Smaller sizes are also possible, named Baby Vault. A prototype Wood Vault Unit (WVU) occupies 1 hectare (ha, 100 m by 100 m) of surface land, 20 m tall, stores up to 100,000 m 3 of wood, sequestering 0.1 MtCO 2 . A 1 MtCO 2 y −1 sequestration rate can be achieved by collecting currently unused wood residuals (WR) on an area of 25,000 km 2 , the size of 10 typical counties in the eastern US, corresponding to an average transportation distance of less than 100 km. After 30 years of operation, such a Wood Vault facility would have sequestered 30 MtCO 2 , stored in 300 WVUs, occupying a land surface of 300 ha. The cost is estimated at $10–50/tCO 2 with a mid-point price of $30/tCO 2 . To sequester 1 GtCO 2 y −1 , wood can be sourced from currently unexploited wood residuals on an area of 9 Mkm 2 forested land (9 million square kilometers, size of the US), corresponding to a low areal harvesting intensity of 1.1 tCO 2 ha −1 y −1 . Alternatively, giga-tonne scale carbon removal can be achieved by harvesting wood at a medium harvesting intensity of 4 tCO 2 ha −1 y −1 on 3 Mkm 2 of forest (equivalent to increasing current world wood harvest rate by 25%), or harvest on 0.8 Mkm 2 forest restored from past Amazon deforestation at high harvest intensity, or many combinations of these and other possibilities. It takes 1000 facilities as discussed above to store 1 GtCO 2 y −1 , compared to more than 6000 landfills currently in operation in the US. After full closure of a Wood Vault, the land can be utilized for recreation, agriculture, solar farm, or agrivoltaics. A more distributed small operator model (Baby Vault) has somewhat different operation and economic constraints. A 10 giga-tonne sequestration rate siphons off only 5% of total terrestrial net primary production, thus possible with WHS, but extreme caution needs to be taken to ensure sustainable wood sourcing. Conclusions Our technical and economic analysis shows that Wood Vault can be a powerful tool to sequester carbon reliably, using a variety of wood sources. Most pieces of the technology already exist, but they need to be put together efficiently in practice. Some uncertainties need to be addressed, including how durability of buried wood depends on detailed storage methods and burial environment, but the science and technology are known well enough to believe the practicality of the method. The high durability, verifiability and low-cost makes it already an attractive option in the current global carbon market. Woody biomass stored in Wood Vaults is not only a carbon sink to combat current climate crisis, but also a valuable resource for the future that can be used as biomass/bioenergy and carbon supply. The quantity of this wood utilization can be controlled carefully to maintain a desired amount of CO 2 in the atmosphere to keep the Earth’s climate from diving into the next ice age, acting as a climate thermostat. The CO 2 drawdown time is on the order of 100 years while the ramp-up time is a decade. A sense of urgency is warranted because the CO 2 removal rate is limited by biosphere productivity, thus delayed action means a loss of opportunity. In conclusion, WHS provides a tool for managing our Earth system, which will likely remain forever in the Anthropocene.
AbstractList	BackgroundWood harvesting and storage (WHS) is a hybrid Nature-Engineering combination method to combat climate change by harvesting wood sustainably and storing it semi-permanently for carbon sequestration. To date, the technology has only been purposefully tested in small-scale demonstration projects. This study aims to develop a concrete way to carry out WHS at large-scale.ResultsWe describe a method of constructing a wood storage facility, named Wood Vault, that can bury woody biomass on a mega-tonne scale in specially engineered enclosures to ensure anaerobic environments, thus preventing wood decay. The buried wood enters a quasi-geological reservoir that is expected to stay intact semi-permanently. Storing wood in many environments is possible, leading to seven versions of Wood Vault: (1) Burial Mound (Tumulus or Barrow), (2) Underground (Pit, Quarry, or Mine), (3) Super Vault, (4) Shelter, (5) AquaOpen or AquaVault with wood submerged under water, (6) DesertOpen or DesertVault in dry regions, (7) FreezeVault in cold regions such as Antarctica. Smaller sizes are also possible, named Baby Vault. A prototype Wood Vault Unit (WVU) occupies 1 hectare (ha, 100 m by 100 m) of surface land, 20 m tall, stores up to 100,000 m3 of wood, sequestering 0.1 MtCO2. A 1 MtCO2 y−1 sequestration rate can be achieved by collecting currently unused wood residuals (WR) on an area of 25,000 km2, the size of 10 typical counties in the eastern US, corresponding to an average transportation distance of less than 100 km. After 30 years of operation, such a Wood Vault facility would have sequestered 30 MtCO2, stored in 300 WVUs, occupying a land surface of 300 ha. The cost is estimated at $10–50/tCO2 with a mid-point price of $30/tCO2. To sequester 1 GtCO2 y−1, wood can be sourced from currently unexploited wood residuals on an area of 9 Mkm2 forested land (9 million square kilometers, size of the US), corresponding to a low areal harvesting intensity of 1.1 tCO2 ha−1 y−1. Alternatively, giga-tonne scale carbon removal can be achieved by harvesting wood at a medium harvesting intensity of 4 tCO2 ha−1 y−1 on 3 Mkm2 of forest (equivalent to increasing current world wood harvest rate by 25%), or harvest on 0.8 Mkm2 forest restored from past Amazon deforestation at high harvest intensity, or many combinations of these and other possibilities. It takes 1000 facilities as discussed above to store 1 GtCO2 y−1, compared to more than 6000 landfills currently in operation in the US. After full closure of a Wood Vault, the land can be utilized for recreation, agriculture, solar farm, or agrivoltaics. A more distributed small operator model (Baby Vault) has somewhat different operation and economic constraints. A 10 giga-tonne sequestration rate siphons off only 5% of total terrestrial net primary production, thus possible with WHS, but extreme caution needs to be taken to ensure sustainable wood sourcing.ConclusionsOur technical and economic analysis shows that Wood Vault can be a powerful tool to sequester carbon reliably, using a variety of wood sources. Most pieces of the technology already exist, but they need to be put together efficiently in practice. Some uncertainties need to be addressed, including how durability of buried wood depends on detailed storage methods and burial environment, but the science and technology are known well enough to believe the practicality of the method. The high durability, verifiability and low-cost makes it already an attractive option in the current global carbon market. Woody biomass stored in Wood Vaults is not only a carbon sink to combat current climate crisis, but also a valuable resource for the future that can be used as biomass/bioenergy and carbon supply. The quantity of this wood utilization can be controlled carefully to maintain a desired amount of CO2 in the atmosphere to keep the Earth’s climate from diving into the next ice age, acting as a climate thermostat. The CO2 drawdown time is on the order of 100 years while the ramp-up time is a decade. A sense of urgency is warranted because the CO2 removal rate is limited by biosphere productivity, thus delayed action means a loss of opportunity. In conclusion, WHS provides a tool for managing our Earth system, which will likely remain forever in the Anthropocene. BACKGROUND: Wood harvesting and storage (WHS) is a hybrid Nature-Engineering combination method to combat climate change by harvesting wood sustainably and storing it semi-permanently for carbon sequestration. To date, the technology has only been purposefully tested in small-scale demonstration projects. This study aims to develop a concrete way to carry out WHS at large-scale. RESULTS: We describe a method of constructing a wood storage facility, named Wood Vault, that can bury woody biomass on a mega-tonne scale in specially engineered enclosures to ensure anaerobic environments, thus preventing wood decay. The buried wood enters a quasi-geological reservoir that is expected to stay intact semi-permanently. Storing wood in many environments is possible, leading to seven versions of Wood Vault: (1) Burial Mound (Tumulus or Barrow), (2) Underground (Pit, Quarry, or Mine), (3) Super Vault, (4) Shelter, (5) AquaOpen or AquaVault with wood submerged under water, (6) DesertOpen or DesertVault in dry regions, (7) FreezeVault in cold regions such as Antarctica. Smaller sizes are also possible, named Baby Vault. A prototype Wood Vault Unit (WVU) occupies 1 hectare (ha, 100 m by 100 m) of surface land, 20 m tall, stores up to 100,000 m³ of wood, sequestering 0.1 MtCO₂. A 1 MtCO₂ y⁻¹ sequestration rate can be achieved by collecting currently unused wood residuals (WR) on an area of 25,000 km², the size of 10 typical counties in the eastern US, corresponding to an average transportation distance of less than 100 km. After 30 years of operation, such a Wood Vault facility would have sequestered 30 MtCO₂, stored in 300 WVUs, occupying a land surface of 300 ha. The cost is estimated at $10–50/tCO₂ with a mid-point price of $30/tCO₂. To sequester 1 GtCO₂ y⁻¹, wood can be sourced from currently unexploited wood residuals on an area of 9 Mkm² forested land (9 million square kilometers, size of the US), corresponding to a low areal harvesting intensity of 1.1 tCO₂ ha⁻¹ y⁻¹. Alternatively, giga-tonne scale carbon removal can be achieved by harvesting wood at a medium harvesting intensity of 4 tCO₂ ha⁻¹ y⁻¹ on 3 Mkm² of forest (equivalent to increasing current world wood harvest rate by 25%), or harvest on 0.8 Mkm² forest restored from past Amazon deforestation at high harvest intensity, or many combinations of these and other possibilities. It takes 1000 facilities as discussed above to store 1 GtCO₂ y⁻¹, compared to more than 6000 landfills currently in operation in the US. After full closure of a Wood Vault, the land can be utilized for recreation, agriculture, solar farm, or agrivoltaics. A more distributed small operator model (Baby Vault) has somewhat different operation and economic constraints. A 10 giga-tonne sequestration rate siphons off only 5% of total terrestrial net primary production, thus possible with WHS, but extreme caution needs to be taken to ensure sustainable wood sourcing. CONCLUSIONS: Our technical and economic analysis shows that Wood Vault can be a powerful tool to sequester carbon reliably, using a variety of wood sources. Most pieces of the technology already exist, but they need to be put together efficiently in practice. Some uncertainties need to be addressed, including how durability of buried wood depends on detailed storage methods and burial environment, but the science and technology are known well enough to believe the practicality of the method. The high durability, verifiability and low-cost makes it already an attractive option in the current global carbon market. Woody biomass stored in Wood Vaults is not only a carbon sink to combat current climate crisis, but also a valuable resource for the future that can be used as biomass/bioenergy and carbon supply. The quantity of this wood utilization can be controlled carefully to maintain a desired amount of CO₂ in the atmosphere to keep the Earth’s climate from diving into the next ice age, acting as a climate thermostat. The CO₂ drawdown time is on the order of 100 years while the ramp-up time is a decade. A sense of urgency is warranted because the CO₂ removal rate is limited by biosphere productivity, thus delayed action means a loss of opportunity. In conclusion, WHS provides a tool for managing our Earth system, which will likely remain forever in the Anthropocene. Wood harvesting and storage (WHS) is a hybrid Nature-Engineering combination method to combat climate change by harvesting wood sustainably and storing it semi-permanently for carbon sequestration. To date, the technology has only been purposefully tested in small-scale demonstration projects. This study aims to develop a concrete way to carry out WHS at large-scale.BACKGROUNDWood harvesting and storage (WHS) is a hybrid Nature-Engineering combination method to combat climate change by harvesting wood sustainably and storing it semi-permanently for carbon sequestration. To date, the technology has only been purposefully tested in small-scale demonstration projects. This study aims to develop a concrete way to carry out WHS at large-scale.We describe a method of constructing a wood storage facility, named Wood Vault, that can bury woody biomass on a mega-tonne scale in specially engineered enclosures to ensure anaerobic environments, thus preventing wood decay. The buried wood enters a quasi-geological reservoir that is expected to stay intact semi-permanently. Storing wood in many environments is possible, leading to seven versions of Wood Vault: (1) Burial Mound (Tumulus or Barrow), (2) Underground (Pit, Quarry, or Mine), (3) Super Vault, (4) Shelter, (5) AquaOpen or AquaVault with wood submerged under water, (6) DesertOpen or DesertVault in dry regions, (7) FreezeVault in cold regions such as Antarctica. Smaller sizes are also possible, named Baby Vault. A prototype Wood Vault Unit (WVU) occupies 1 hectare (ha, 100 m by 100 m) of surface land, 20 m tall, stores up to 100,000 m3 of wood, sequestering 0.1 MtCO2. A 1 MtCO2 y-1 sequestration rate can be achieved by collecting currently unused wood residuals (WR) on an area of 25,000 km2, the size of 10 typical counties in the eastern US, corresponding to an average transportation distance of less than 100 km. After 30 years of operation, such a Wood Vault facility would have sequestered 30 MtCO2, stored in 300 WVUs, occupying a land surface of 300 ha. The cost is estimated at $10-50/tCO2 with a mid-point price of $30/tCO2. To sequester 1 GtCO2 y-1, wood can be sourced from currently unexploited wood residuals on an area of 9 Mkm2 forested land (9 million square kilometers, size of the US), corresponding to a low areal harvesting intensity of 1.1 tCO2 ha-1 y-1. Alternatively, giga-tonne scale carbon removal can be achieved by harvesting wood at a medium harvesting intensity of 4 tCO2 ha-1 y-1 on 3 Mkm2 of forest (equivalent to increasing current world wood harvest rate by 25%), or harvest on 0.8 Mkm2 forest restored from past Amazon deforestation at high harvest intensity, or many combinations of these and other possibilities. It takes 1000 facilities as discussed above to store 1 GtCO2 y-1, compared to more than 6000 landfills currently in operation in the US. After full closure of a Wood Vault, the land can be utilized for recreation, agriculture, solar farm, or agrivoltaics. A more distributed small operator model (Baby Vault) has somewhat different operation and economic constraints. A 10 giga-tonne sequestration rate siphons off only 5% of total terrestrial net primary production, thus possible with WHS, but extreme caution needs to be taken to ensure sustainable wood sourcing.RESULTSWe describe a method of constructing a wood storage facility, named Wood Vault, that can bury woody biomass on a mega-tonne scale in specially engineered enclosures to ensure anaerobic environments, thus preventing wood decay. The buried wood enters a quasi-geological reservoir that is expected to stay intact semi-permanently. Storing wood in many environments is possible, leading to seven versions of Wood Vault: (1) Burial Mound (Tumulus or Barrow), (2) Underground (Pit, Quarry, or Mine), (3) Super Vault, (4) Shelter, (5) AquaOpen or AquaVault with wood submerged under water, (6) DesertOpen or DesertVault in dry regions, (7) FreezeVault in cold regions such as Antarctica. Smaller sizes are also possible, named Baby Vault. A prototype Wood Vault Unit (WVU) occupies 1 hectare (ha, 100 m by 100 m) of surface land, 20 m tall, stores up to 100,000 m3 of wood, sequestering 0.1 MtCO2. A 1 MtCO2 y-1 sequestration rate can be achieved by collecting currently unused wood residuals (WR) on an area of 25,000 km2, the size of 10 typical counties in the eastern US, corresponding to an average transportation distance of less than 100 km. After 30 years of operation, such a Wood Vault facility would have sequestered 30 MtCO2, stored in 300 WVUs, occupying a land surface of 300 ha. The cost is estimated at $10-50/tCO2 with a mid-point price of $30/tCO2. To sequester 1 GtCO2 y-1, wood can be sourced from currently unexploited wood residuals on an area of 9 Mkm2 forested land (9 million square kilometers, size of the US), corresponding to a low areal harvesting intensity of 1.1 tCO2 ha-1 y-1. Alternatively, giga-tonne scale carbon removal can be achieved by harvesting wood at a medium harvesting intensity of 4 tCO2 ha-1 y-1 on 3 Mkm2 of forest (equivalent to increasing current world wood harvest rate by 25%), or harvest on 0.8 Mkm2 forest restored from past Amazon deforestation at high harvest intensity, or many combinations of these and other possibilities. It takes 1000 facilities as discussed above to store 1 GtCO2 y-1, compared to more than 6000 landfills currently in operation in the US. After full closure of a Wood Vault, the land can be utilized for recreation, agriculture, solar farm, or agrivoltaics. A more distributed small operator model (Baby Vault) has somewhat different operation and economic constraints. A 10 giga-tonne sequestration rate siphons off only 5% of total terrestrial net primary production, thus possible with WHS, but extreme caution needs to be taken to ensure sustainable wood sourcing.Our technical and economic analysis shows that Wood Vault can be a powerful tool to sequester carbon reliably, using a variety of wood sources. Most pieces of the technology already exist, but they need to be put together efficiently in practice. Some uncertainties need to be addressed, including how durability of buried wood depends on detailed storage methods and burial environment, but the science and technology are known well enough to believe the practicality of the method. The high durability, verifiability and low-cost makes it already an attractive option in the current global carbon market. Woody biomass stored in Wood Vaults is not only a carbon sink to combat current climate crisis, but also a valuable resource for the future that can be used as biomass/bioenergy and carbon supply. The quantity of this wood utilization can be controlled carefully to maintain a desired amount of CO2 in the atmosphere to keep the Earth's climate from diving into the next ice age, acting as a climate thermostat. The CO2 drawdown time is on the order of 100 years while the ramp-up time is a decade. A sense of urgency is warranted because the CO2 removal rate is limited by biosphere productivity, thus delayed action means a loss of opportunity. In conclusion, WHS provides a tool for managing our Earth system, which will likely remain forever in the Anthropocene.CONCLUSIONSOur technical and economic analysis shows that Wood Vault can be a powerful tool to sequester carbon reliably, using a variety of wood sources. Most pieces of the technology already exist, but they need to be put together efficiently in practice. Some uncertainties need to be addressed, including how durability of buried wood depends on detailed storage methods and burial environment, but the science and technology are known well enough to believe the practicality of the method. The high durability, verifiability and low-cost makes it already an attractive option in the current global carbon market. Woody biomass stored in Wood Vaults is not only a carbon sink to combat current climate crisis, but also a valuable resource for the future that can be used as biomass/bioenergy and carbon supply. The quantity of this wood utilization can be controlled carefully to maintain a desired amount of CO2 in the atmosphere to keep the Earth's climate from diving into the next ice age, acting as a climate thermostat. The CO2 drawdown time is on the order of 100 years while the ramp-up time is a decade. A sense of urgency is warranted because the CO2 removal rate is limited by biosphere productivity, thus delayed action means a loss of opportunity. In conclusion, WHS provides a tool for managing our Earth system, which will likely remain forever in the Anthropocene. Abstract Background Wood harvesting and storage (WHS) is a hybrid Nature-Engineering combination method to combat climate change by harvesting wood sustainably and storing it semi-permanently for carbon sequestration. To date, the technology has only been purposefully tested in small-scale demonstration projects. This study aims to develop a concrete way to carry out WHS at large-scale. Results We describe a method of constructing a wood storage facility, named Wood Vault, that can bury woody biomass on a mega-tonne scale in specially engineered enclosures to ensure anaerobic environments, thus preventing wood decay. The buried wood enters a quasi-geological reservoir that is expected to stay intact semi-permanently. Storing wood in many environments is possible, leading to seven versions of Wood Vault: (1) Burial Mound (Tumulus or Barrow), (2) Underground (Pit, Quarry, or Mine), (3) Super Vault, (4) Shelter, (5) AquaOpen or AquaVault with wood submerged under water, (6) DesertOpen or DesertVault in dry regions, (7) FreezeVault in cold regions such as Antarctica. Smaller sizes are also possible, named Baby Vault. A prototype Wood Vault Unit (WVU) occupies 1 hectare (ha, 100 m by 100 m) of surface land, 20 m tall, stores up to 100,000 m3 of wood, sequestering 0.1 MtCO2. A 1 MtCO2 y−1 sequestration rate can be achieved by collecting currently unused wood residuals (WR) on an area of 25,000 km2, the size of 10 typical counties in the eastern US, corresponding to an average transportation distance of less than 100 km. After 30 years of operation, such a Wood Vault facility would have sequestered 30 MtCO2, stored in 300 WVUs, occupying a land surface of 300 ha. The cost is estimated at $10–50/tCO2 with a mid-point price of $30/tCO2. To sequester 1 GtCO2 y−1, wood can be sourced from currently unexploited wood residuals on an area of 9 Mkm2 forested land (9 million square kilometers, size of the US), corresponding to a low areal harvesting intensity of 1.1 tCO2 ha−1 y−1. Alternatively, giga-tonne scale carbon removal can be achieved by harvesting wood at a medium harvesting intensity of 4 tCO2 ha−1 y−1 on 3 Mkm2 of forest (equivalent to increasing current world wood harvest rate by 25%), or harvest on 0.8 Mkm2 forest restored from past Amazon deforestation at high harvest intensity, or many combinations of these and other possibilities. It takes 1000 facilities as discussed above to store 1 GtCO2 y−1, compared to more than 6000 landfills currently in operation in the US. After full closure of a Wood Vault, the land can be utilized for recreation, agriculture, solar farm, or agrivoltaics. A more distributed small operator model (Baby Vault) has somewhat different operation and economic constraints. A 10 giga-tonne sequestration rate siphons off only 5% of total terrestrial net primary production, thus possible with WHS, but extreme caution needs to be taken to ensure sustainable wood sourcing. Conclusions Our technical and economic analysis shows that Wood Vault can be a powerful tool to sequester carbon reliably, using a variety of wood sources. Most pieces of the technology already exist, but they need to be put together efficiently in practice. Some uncertainties need to be addressed, including how durability of buried wood depends on detailed storage methods and burial environment, but the science and technology are known well enough to believe the practicality of the method. The high durability, verifiability and low-cost makes it already an attractive option in the current global carbon market. Woody biomass stored in Wood Vaults is not only a carbon sink to combat current climate crisis, but also a valuable resource for the future that can be used as biomass/bioenergy and carbon supply. The quantity of this wood utilization can be controlled carefully to maintain a desired amount of CO2 in the atmosphere to keep the Earth’s climate from diving into the next ice age, acting as a climate thermostat. The CO2 drawdown time is on the order of 100 years while the ramp-up time is a decade. A sense of urgency is warranted because the CO2 removal rate is limited by biosphere productivity, thus delayed action means a loss of opportunity. In conclusion, WHS provides a tool for managing our Earth system, which will likely remain forever in the Anthropocene. Background Wood harvesting and storage (WHS) is a hybrid Nature-Engineering combination method to combat climate change by harvesting wood sustainably and storing it semi-permanently for carbon sequestration. To date, the technology has only been purposefully tested in small-scale demonstration projects. This study aims to develop a concrete way to carry out WHS at large-scale. Results We describe a method of constructing a wood storage facility, named Wood Vault, that can bury woody biomass on a mega-tonne scale in specially engineered enclosures to ensure anaerobic environments, thus preventing wood decay. The buried wood enters a quasi-geological reservoir that is expected to stay intact semi-permanently. Storing wood in many environments is possible, leading to seven versions of Wood Vault: (1) Burial Mound (Tumulus or Barrow), (2) Underground (Pit, Quarry, or Mine), (3) Super Vault, (4) Shelter, (5) AquaOpen or AquaVault with wood submerged under water, (6) DesertOpen or DesertVault in dry regions, (7) FreezeVault in cold regions such as Antarctica. Smaller sizes are also possible, named Baby Vault. A prototype Wood Vault Unit (WVU) occupies 1 hectare (ha, 100 m by 100 m) of surface land, 20 m tall, stores up to 100,000 m 3 of wood, sequestering 0.1 MtCO 2 . A 1 MtCO 2 y −1 sequestration rate can be achieved by collecting currently unused wood residuals (WR) on an area of 25,000 km 2 , the size of 10 typical counties in the eastern US, corresponding to an average transportation distance of less than 100 km. After 30 years of operation, such a Wood Vault facility would have sequestered 30 MtCO 2 , stored in 300 WVUs, occupying a land surface of 300 ha. The cost is estimated at $10–50/tCO 2 with a mid-point price of $30/tCO 2 . To sequester 1 GtCO 2 y −1 , wood can be sourced from currently unexploited wood residuals on an area of 9 Mkm 2 forested land (9 million square kilometers, size of the US), corresponding to a low areal harvesting intensity of 1.1 tCO 2 ha −1 y −1 . Alternatively, giga-tonne scale carbon removal can be achieved by harvesting wood at a medium harvesting intensity of 4 tCO 2 ha −1 y −1 on 3 Mkm 2 of forest (equivalent to increasing current world wood harvest rate by 25%), or harvest on 0.8 Mkm 2 forest restored from past Amazon deforestation at high harvest intensity, or many combinations of these and other possibilities. It takes 1000 facilities as discussed above to store 1 GtCO 2 y −1 , compared to more than 6000 landfills currently in operation in the US. After full closure of a Wood Vault, the land can be utilized for recreation, agriculture, solar farm, or agrivoltaics. A more distributed small operator model (Baby Vault) has somewhat different operation and economic constraints. A 10 giga-tonne sequestration rate siphons off only 5% of total terrestrial net primary production, thus possible with WHS, but extreme caution needs to be taken to ensure sustainable wood sourcing. Conclusions Our technical and economic analysis shows that Wood Vault can be a powerful tool to sequester carbon reliably, using a variety of wood sources. Most pieces of the technology already exist, but they need to be put together efficiently in practice. Some uncertainties need to be addressed, including how durability of buried wood depends on detailed storage methods and burial environment, but the science and technology are known well enough to believe the practicality of the method. The high durability, verifiability and low-cost makes it already an attractive option in the current global carbon market. Woody biomass stored in Wood Vaults is not only a carbon sink to combat current climate crisis, but also a valuable resource for the future that can be used as biomass/bioenergy and carbon supply. The quantity of this wood utilization can be controlled carefully to maintain a desired amount of CO 2 in the atmosphere to keep the Earth’s climate from diving into the next ice age, acting as a climate thermostat. The CO 2 drawdown time is on the order of 100 years while the ramp-up time is a decade. A sense of urgency is warranted because the CO 2 removal rate is limited by biosphere productivity, thus delayed action means a loss of opportunity. In conclusion, WHS provides a tool for managing our Earth system, which will likely remain forever in the Anthropocene.
ArticleNumber	2
Author	Zeng, Ning Hausmann, Henry
Author_xml	– sequence: 1 givenname: Ning orcidid: 0000-0002-7489-7629 surname: Zeng fullname: Zeng, Ning email: zeng@umd.edu organization: Department of Atmospheric and Oceanic Science, University of Maryland, Earth System Science Interdisciplinary Center, University of Maryland, Department of Geology, University of Maryland, Maryland Energy Innovation Institute, University of Maryland – sequence: 2 givenname: Henry surname: Hausmann fullname: Hausmann, Henry organization: Department of Atmospheric and Oceanic Science, University of Maryland
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Adair JC, Hofberg M, Junghans M, Kerrick J, Luo H, Mercado G, Oliver M, O'Neill S, RemerS, Schulzinger D, Shofnos M, Tolley R, H Tse, Wesley, The Effect of Wood Burial and Submersion on Decomposition: Implications for Reducing Carbon Emissions. 2010: College Park, Maryland, USA LentonTMThe potential for land-based biological CO2 removal to lower future atmospheric CO2 concentrationCarbon Manage2010111451601:CAS:528:DC%2BC3cXhsFKnur7P10.4155/cmt.10.12 JoppaLMicrosoft's million-tonne CO2-removal purchase—lessons for net zeroNature202159778786296321:CAS:528:DC%2BB3MXitFCmsLnN10.1038/d41586-021-02606-3 MartinCREvaluation and environmental correction of ambient CO2 measurements from a low-cost NDIR sensorAtmospheric Meas Tech2017107238323951:CAS:528:DC%2BC1cXkvV2rur0%3D10.5194/amt-10-2383-2017 Duffy DP. Landfill Economics Part 1: Getting Down to Business. 2015, MSW Management. 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Analysis of the NOAA GMCC data, 1974–1985J Geophys Res Atmospheres198994D6854985651:CAS:528:DyaK3cXhs1Cis7o%3D10.1029/JD094iD06p08549 SteffenWCrutzenPJMcNeillJRThe Anthropocene: are humans now overwhelming the great forces of natureAmbio20073686146211:CAS:528:DC%2BD1cXksFSqsrs%3D10.1579/0044-7447(2007)36[614:TAAHNO]2.0.CO;2 ZengNGlacial-interglacial atmospheric CO2 change—the glacial burial hypothesisAdv Atmos Sci200320567769310.1007/BF02915395 N Zeng (202_CR4) 2013; 118 CR Martin (202_CR13) 2017; 10 WF Ruddiman (202_CR25) 2020; 240 S Pacala (202_CR32) 2004; 305 N Zeng (202_CR24) 2007; 3 TM Lenton (202_CR14) 2010; 1 C Le Quere (202_CR28) 2015; 7 202_CR20 National Academies of Sciences Engineering and Medicine (NASEM) (202_CR2) 2019 F Ximenes (202_CR16) 2015; 41 202_CR18 D Liu (202_CR12) 2021; 21 L Joppa (202_CR9) 2021; 597 202_CR5 202_CR1 N Zeng (202_CR23) 2003; 20 CS Galik (202_CR11) 2009; 107 International Monetary Fund (202_CR8) 2019 N Zeng (202_CR3) 2008; 3 XM Wang (202_CR19) 2016; 557 W Steffen (202_CR27) 2007; 36 SJ Davis (202_CR7) 2018; 360 PC Tzedakis (202_CR22) 2012; 5 202_CR10 KW Thoning (202_CR30) 1989; 94 RD Perlack (202_CR6) 2005 T Sayara (202_CR21) 2019; 9 WF Ruddiman (202_CR26) 2003; 61 JS Hansen (202_CR31) 2008; 2 B Bereiter (202_CR29) 2015; 42 FA Ximenes (202_CR15) 2008; 28 JA Micales (202_CR17) 1997; 39
References_xml	– reference: GalikCSAbtRWuYForest biomass supply in the Southeastern United States-implications for industrial roundwood and bioenergy productionJ Forest200910726977 – reference: IPCC, 2019 Refinement to the 2006 IPCC Guidelines for National Greenhouse Gas Inventories. Switzerland: IPCC; 2019. – reference: PerlackRDWrightLLTurhollowAFGrahamRLStokesBJErbachDCBiomass as feedstock for a bioenergy and bioproducts industry: the technical feasibility of a billion-ton annual supply2005Oak RidgeLUS Department of Energy, Oak Ridge National Laboratory78 – reference: DavisSJNet-zero emissions energy systemsScience2018360639614191:CAS:528:DC%2BC1cXht1SrtrfN10.1126/science.aas9793 – reference: PacalaSSocolowRStabilization wedges: solving the climate problem for the next 50 years with current technologiesScience200430556869689721:CAS:528:DC%2BD2cXmsVGmt78%3D10.1126/science.1100103 – reference: HansenJSKharechaMBeerlingPBernerDMasson-DelmotteRPaganiVRaymoMRoyerMZachosDLJamesCTarget atmospheric CO2: where should humanity aim?Open Atmospheric Sci J200822172311:CAS:528:DC%2BD1MXht1Khu7Y%3D10.2174/1874282300802010217 – reference: ZengNCarbon sequestration via wood burialCarbon Balance Manage200831110.1186/1750-0680-3-1 – reference: ZengNQuasi-100 ky glacial-interglacial cycles triggered by subglacial burial carbon releaseClim Past.20073113515310.5194/cp-3-135-2007 – reference: JoppaLMicrosoft's million-tonne CO2-removal purchase—lessons for net zeroNature202159778786296321:CAS:528:DC%2BB3MXitFCmsLnN10.1038/d41586-021-02606-3 – reference: Blanchette RA et al. 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Snippet	Background Wood harvesting and storage (WHS) is a hybrid Nature-Engineering combination method to combat climate change by harvesting wood sustainably and... BackgroundWood harvesting and storage (WHS) is a hybrid Nature-Engineering combination method to combat climate change by harvesting wood sustainably and... Wood harvesting and storage (WHS) is a hybrid Nature-Engineering combination method to combat climate change by harvesting wood sustainably and storing it... BACKGROUND: Wood harvesting and storage (WHS) is a hybrid Nature-Engineering combination method to combat climate change by harvesting wood sustainably and... Abstract Background Wood harvesting and storage (WHS) is a hybrid Nature-Engineering combination method to combat climate change by harvesting wood sustainably...
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SubjectTerms	Agricultural economics Agriculture agrivoltaic systems Agrivoltaics Anaerobic environments Antarctica Anthropocene Anthropocene epoch bioenergy Biomass Biosphere carbon Carbon dioxide Carbon dioxide atmospheric concentrations Carbon dioxide removal carbon markets Carbon sequestration Carbon sinks climate Climate change cold Cold regions Decay decayed wood Deforestation Drawdown Durability Earth and Environmental Science Eastern United States Economic analysis Economic models Economics Ecosystems Environment Environmental Management Forestry forests hybrids Ice ages Landfills Net Primary Productivity prices Primary production prototypes quarries recreation Renewable energy Science and technology Sequestering Siphons Solar farms Solar power generation Storage facilities transportation Underground mines Waste disposal sites Wood Wood construction wood utilization woody biomass
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Title	Wood Vault: remove atmospheric CO2 with trees, store wood for carbon sequestration for now and as biomass, bioenergy and carbon reserve for the future
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