The potential for land sparing to offset greenhouse gas emissions from agriculture

Lamb, Anthony; Green, Rhys E.; Bateman, Ian J.; Broadmeadow, M. S. J.; Bruce, Toby J. A.; Burney, Jennifer; Carey, Peter; Chadwick, David R.; Crane, Ellie; Field, Ray; Goulding, Keith; Griffiths, Howard; Hastings, Astley; Kasoar, Tim; Kindred, D. R.; Phalan, Ben; Pickett, John A.; Smith, Pete; Wall, E.; Ermgassen, Erasmus zu; Balmford, Andrew

doi:10.1038/nclimate2910

Cited by 198 publications

(148 citation statements)

References 22 publications

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“…The first point about reducing the demand for livestock products is, at least in theory, a powerful mitigation option (Schösler et al 2012;Hedenus et al 2014;Davis et al 2016;Herrero et al 2016;Lamb et al 2016). This is particularly true for ruminant meat.…”

Section: Climate Change and Dietary Changesmentioning

confidence: 99%

“…This can be achieved by substituting animal protein with vegetable protein and making a transition from ruminants (e.g., cattle and sheep) (McAlpine et al 2009;Tilman and Clark 2014;Bryngelsson et al 2016) to lower impact species (e.g., pigs and poultry) (Steinfeld and Gerber 2010). Reducing meat consumption and combining this with land sparing have the potential to reduce greenhouse gas emissions (Lamb et al 2016) and increase biodiversity (Phalan et al 2011). Another mitigation measure is using feed with a low environmental impact for the production of fish, pigs or poultry.…”

Section: Climate Change and Dietary Changesmentioning

confidence: 99%

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The environmental sustainability of insects as food and feed. A review

Huis

Oonincx

2017

Agron. Sustain. Dev.

631

381

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With a growing world population, increasingly demanding consumers, and a limited amount of agricultural land, there is an urgent need to find alternatives to conventional meat products. Livestock production is, moreover, a leading cause of anthropogenic-induced climate change. To mediate this, more sustainable diets are needed, with reduced meat consumption or the use of alternative protein sources. Insects are promoted as human food and animal feed worldwide. In tropical countries, edible insects are harvested from nature, but overexploitation, habitat changes, and environmental contamination threaten this food resource. Therefore, sustainable harvesting practices need to be developed and implemented. We provide examples of (1) aquatic insects whose populations are threatened by pollution, (2) caterpillar species in Africa that are disappearing due to overexploitation and habitat change, (3) edible insects species that are considered pests in agro-ecosystems, and (4) edible insect species that can be conserved and enhanced in forest management systems. Insect farming can be conducted either on small-scale farms or in large-scale industrialized rearing facilities. We review the environmental sustainability of insect farming compared to livestock production. The major environmental advantages of insect farming compared to livestock production are as follows: (1) less land and water is required; (2) greenhouse gas emissions are lower; (3) insects have high feed conversion efficiencies; (4) insects can transform low-value organic by-products into highquality food or feed; and (5) certain insect species can be used as animal feed or aqua feed. For instance, they can replace fish meal, which is becoming increasingly scarce and expensive.However, edible insect species intended for production should be screened for risks to humans, animals, plants, and biodiversity.

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Section: Climate Change and Dietary Changesmentioning

confidence: 99%

Section: Climate Change and Dietary Changesmentioning

confidence: 99%

The environmental sustainability of insects as food and feed. A review

Huis

Oonincx

2017

Agron. Sustain. Dev.

631

381

View full text Add to dashboard Cite

show abstract

“…In ruminant production, for instance, the maximum mitigation potential ranges from 4 to 7% depending on the level of adoption rate (historical adoption rates to full adoption rates) of technologies such as cultivated pastures, better nutrition, changes in land-use practices, and changing breeding (Thornton and Herrero, 2010). Lamb et al (2016), however, acknowledged that their technological advancements might be untenable in practice, leading us back to the starting point. These authors also alluded the fact that reducing meat consumption would alleviate the growth of GHG emissions and perhaps a legislative incentive would be needed in the form of taxation on meat.…”

Section: Sustainable Intensificationmentioning

confidence: 99%

“…In the livestock arena, the upper-bound livestock productivity gains of Lamb et al (2016) assumed that technological advancements would lead to continued genetic gains through breeding and improved animal health and nutrition. The authors did not provide exact ways in which these improvements could offset livestock GHG emissions.…”

Section: Sustainable Intensificationmentioning

confidence: 99%

“…Sustainability does not necessarily imply organic agriculture, though some organic components might be needed to establish sustainable farming systems (Reganold and Wachter, 2016). Lamb et al (2016) laid out the "land sparing" concept for parts of Europe. It essentially seeks to increase yields, leading to a reduction on farmland area to produce the same amount of food/feed, allowing farmland to be spared and used to offset GHG emissions.…”

Section: Sustainable Intensificationmentioning

confidence: 99%

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A glimpse of the future in animal nutrition science. 1. Past and future challenges

et al. 2017

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-If the world population continues to increase exponentially, wealth and education inequalities might become more pronounced in the developing world. Thus, offering affordable, high-quality protein food to people will become more important and daunting than ever. Past and future challenges will increasingly demand quicker and more innovative and efficient solutions. Animal scientists around the globe currently face many challenging issues: from ensuring food security to prevent excess of nutrient intake by humans, from animal welfare to working with genetic-engineered animals, from carbon footprint to water footprint, and from improved animal nutrition to altering the rumen microbiome. Many of these issues are most likely to continue (or to exacerbate further) in the coming years, but animal scientists have many options to surmount the obstacles posed to the livestock industry through tools that are presently available. The frequency, interval, and intensity of livestock impacts, however, differ across regions, production systems, and among livestock species. These differences are such that the generalization of these issues is impossible and dangerous. For instance, when we discuss domesticated ruminant nutrition in the human food context, we look for the most efficient ruminant feeds that complement, rather than compete with, grains grown for direct human nutrition. Greater scrutiny and standardization are needed when developing and validating methodologies to assess short-and long-term impacts of livestock production. Failure in correctly quantifying these impacts may lead to disregard and disbelief by the livestock industry, increased public confusion, and the development of illusionary solutions that may amplify the impacts, thereby invalidating its original intent.Key Words: challenges, issues, livestock, ruminant, production Revista Brasileira de Zootecnia

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High carbon burial rates by small ponds in the landscape

Taylor

Gilbert

Cooke

et al. 2019

Frontiers in Ecol & Environ

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Temperate ponds may be important sinks and sources of greenhouse gases but just how quickly ponds bury carbon (C) is poorly understood. We derived – to the best of our knowledge – the first organic carbon (OC) burial rates for small ponds of known age by digging out the whole sediment from ponds, and determined that the average C burial rate was 142 g m−2 yr−1, with a range of 79–247 g m−2 yr−1, depending on the ponds' vegetation. Burial rates in the ponds were 20–30 times higher than rates estimated for many other habitat types, such as woodlands or grasslands, and higher than those of other natural wetlands. Although small ponds occupy a very small proportion of the landscape as compared to these other habitats, their high OC burial rates result in comparable annual OC burial overall. Ponds are easy to create, can fit in with other land uses, and are a globally ubiquitous habitat. Our results indicate that ponds have the potential to be a very useful additional tool for mitigating C emissions.

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The potential for land sparing to offset greenhouse gas emissions from agriculture

Cited by 198 publications

References 22 publications

The environmental sustainability of insects as food and feed. A review

The environmental sustainability of insects as food and feed. A review

A glimpse of the future in animal nutrition science. 1. Past and future challenges

High carbon burial rates by small ponds in the landscape

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