Food without sun: price and life-saving potential

Denkenberger, David; Pearce, Joshua M.; Taylor, Andrew; Black, Ryan D.

doi:10.1108/fs-04-2018-0041

Cited by 26 publications

(27 citation statements)

References 21 publications

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“…If the capital, labor, material, knowledge and production capacity of the sector could be leveraged entirely for fast construction of H₂ SCP facilities without bottlenecks, enough food could theoretically be produced to feed the entire global population in just over 1 year. This is longer than the time that current food reserves would last in a sun-blocking scenario, estimated at about 6 months ( Denkenberger et al., 2019a ). In addition, the titanic effort in international cooperation required would be unprecedented.…”

Section: Discussionmentioning

confidence: 86%

“…those that include disabling of industry ( Denkenberger et al., 2019b , 2017 )), it is found to be a promising technology for providing a substantial fraction of humanity's protein needs during a severe global food catastrophe. Due to these potential difficulties and the existence of other available alternative foods with lower cost per calorie ( Denkenberger et al., 2019a ; Throup et al., 2020 ) and faster production ramp up ( Alvarado et al., 2020 ; Denkenberger and Pearce, 2015 ; Throup et al., 2020 ), it does not seem reasonable to recommend ramping up H₂ SCP any further than required to fulfill the protein requirements of the population. At the speed described by Figs.…”

Section: Discussionmentioning

confidence: 99%

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Potential of microbial protein from hydrogen for preventing mass starvation in catastrophic scenarios

Martínez¹,

Egbejimba

Throup³

et al. 2021

Sustainable Production and Consumption

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Human civilization's food production system is currently unprepared for catastrophes that would reduce global food production by 10% or more, such as nuclear winter, supervolcanic eruptions or asteroid impacts. Alternative foods that do not require much or any sunlight have been proposed as a more cost-effective solution than increasing food stockpiles, given the long duration of many global catastrophic risks (GCRs) that could hamper conventional agriculture for 5 to 10 years. Microbial food from single cell protein (SCP) produced via hydrogen from both gasification and electrolysis is analyzed in this study as alternative food for the most severe food shock scenario: a sun-blocking catastrophe. Capital costs, resource requirements and ramp up rates are quantified to determine its viability. Potential bottlenecks to fast deployment of the technology are reviewed. The ramp up speed of food production for 24/7 construction of the facilities over 6 years is estimated to be lower than other alternatives (3-10% of the global protein requirements could be fulfilled at end of first year), but the nutritional quality of the microbial protein is higher than for most other alternative foods for catastrophes. Results suggest that investment in SCP ramp up should be limited to the production capacity that is needed to fulfill only the minimum recommended protein requirements of humanity during the catastrophe. Further research is needed into more uncertain concerns such as transferability of labor and equipment production. This could help reduce the negative impact of potential food-related GCRs.

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Section: Discussionmentioning

confidence: 86%

Section: Discussionmentioning

confidence: 99%

Potential of microbial protein from hydrogen for preventing mass starvation in catastrophic scenarios

Martínez¹,

Egbejimba

Throup³

et al. 2021

Sustainable Production and Consumption

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show abstract

“…Another protein option that could be grown at household scale is insects. Particularly valuable would be those insects that could feed on residues from leaf processing and also animal waste [120]. Another option for local food production in sunblocking catastrophes would be methane consuming microbes (single cell protein) because of continuing natural gas supply to houses.…”

Section: Discussionmentioning

confidence: 99%

U.S. Potential of Sustainable Backyard Distributed Animal and Plant Protein Production during and after Pandemics

et al. 2021

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To safeguard against meat supply shortages during pandemics or other catastrophes, this study analyzed the potential to provide the average household’s entire protein consumption using either soybean production or distributed meat production at the household level in the U.S. with: (1) pasture-fed rabbits, (2) pellet and hay-fed rabbits, or (3) pellet-fed chickens. Only using the average backyard resources, soybean cultivation can provide 80–160% of household protein and 0–50% of a household’s protein needs can be provided by pasture-fed rabbits using only the yard grass as feed. If external supplementation of feed is available, raising 52 chickens while also harvesting the concomitant eggs or alternately 107 grain-fed rabbits can meet 100% of an average household’s protein requirements. These results show that resilience to future pandemics and challenges associated with growing meat demands can be incrementally addressed through backyard distributed protein production. Backyard production of chicken meat, eggs, and rabbit meat reduces the environmental costs of protein due to savings in production, transportation, and refrigeration of meat products and even more so with soybeans. Generally, distributed production of protein was found to be economically competitive with centralized production of meat if distributed labor costs were ignored.

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“…Preparing for alternative food production is a very cost-effective way to save expected lives, both globally [35] and from the perspective of only the United States [36]. These calculations are all based on technical feasibility and considerable future research is necessary for more extreme scenarios [37,38], particularly considering the transition from conventional to alternative foods and being able to afford the food without subsidy [39]. It is critical to have a resilient global food system [40] that is continuous (e.g., able to maintain caloric intake consistently).…”

Section: Introductionmentioning

confidence: 99%

“…The largest challenge with this transition is between the time that stored foods run out globally following a sun-blocking global catastrophe (about six months) [1,32] and the time that many alternative foods are ramped up to full production (about one year) [1,32]. The best theoretical solution for this transition problem is to use leaves killed by the catastrophe (as opposed to leaves that are depleted of nutrients and shed naturally (leaf litter)), especially because the price compared to many alternative foods is reasonable [39]. However, food from leaves presents several challenges [32].…”

Section: Introductionmentioning

confidence: 99%

Preliminary Automated Determination of Edibility of Alternative Foods: Non-Targeted Screening for Toxins in Red Maple Leaf Concentrate

Pearce

Khaksari

Denkenberger

2019

Plants

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Alternative food supplies could maintain humanity despite sun-blocking global catastrophic risks (GCRs) that eliminate conventional agriculture. A promising alternative food is making leaf concentrate. However, the edibility of tree leaves is largely uncertain. To overcome this challenge, this study provides the methods for obtaining rapid toxics screening of common leaf concentrates. The investigation begins with a non-targeted approach using an ultra-high-resolution hybrid ion trap orbitrap mass spectrometer with electrospray ionization (ESI) coupled to an ultra-high pressure two-dimensional liquid chromatograph system on the most common North American leaf: the red maple. Identified chemicals from this non-targeted approach are then cross-referenced with the OpenFoodTox database to identify toxic chemicals. Identified toxins are then screened for formula validation and evaluated for risk as a food. The results after screening show that red maple leaf concentrate contains at least eight toxic chemicals, which upon analysis do not present substantial risks unless consumed in abundance. This indicates that red maple leaf is still a potential alternative food. The results are discussed in the context of expanding the analysis with open science and using leaf extract from other plants that are not traditionally used as foods to offset current global hunger challenges, and move to a more sustainable food system while also preparing for GCRs.

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Food without sun: price and life-saving potential

Cited by 26 publications

References 21 publications

Potential of microbial protein from hydrogen for preventing mass starvation in catastrophic scenarios

Potential of microbial protein from hydrogen for preventing mass starvation in catastrophic scenarios

U.S. Potential of Sustainable Backyard Distributed Animal and Plant Protein Production during and after Pandemics

Preliminary Automated Determination of Edibility of Alternative Foods: Non-Targeted Screening for Toxins in Red Maple Leaf Concentrate

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