Effect of Feed Concentrate Intake on the Environmental Impact of Dairy Cows in an Alpine Mountain Region Including Soil Carbon Sequestration and Effect on Biodiversity

Sabia, Emilio; Kühl, Sarah; Flach, Laura; Lambertz, Christian; Gauly, Matthias

doi:10.3390/su12052128

Cited by 17 publications

(13 citation statements)

References 58 publications

(90 reference statements)

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“…In contrast, dairy LCAs usually presented their functional unit per liter or kg of dairy product (e.g. 115,118,145 ). Alternatively, LCAs for the livestock industry frequently used 'kg of live weight' as functional unit (e.g.…”

Section: Soil Carbon Sequestration (Scs)mentioning

confidence: 99%

Life cycle assessment of carbon dioxide removal technologies: a critical review

Terlouw

Bauer

Rosa

et al. 2021

Energy Environ. Sci.

192

150

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Section: Soil Carbon Sequestration (Scs)mentioning

confidence: 99%

Life cycle assessment of carbon dioxide removal technologies: a critical review

Terlouw

Bauer

Rosa

et al. 2021

Energy Environ. Sci.

192

150

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“…Wilkes et al ( 2020 ) observed that in farms with different feeding systems, the amount of kg CO 2 -eq was significantly higher in pure grazing systems than those from zero-grazing to semi-grazing. Therefore, such results would explain the lower value found in our study (in a semi-intensive system) once the pasture-based feed is directly correlated with the intensity of GHG emissions due to enteric fermentation (Sabia et al 2020 ).…”

Section: Resultsmentioning

confidence: 62%

Environmental life cycle assessment of cow milk in a conventional semi-intensive Brazilian production system

Carvalho

Willers

Soares

et al. 2021

Environ Sci Pollut Res

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“…Different European studies (e.g. Salvador et al , 2017; Eldesouky et al , 2018; Horrillo et al , 2020; Sabia et al , 2020) indicate that considering the potential of on-farm SOC sequestration could offset the C footprint of sheep and goat milk by up to 90%. In this study, we estimated values of SOC sequestration potential for current small ruminant systems in Europe that could offset about 17–23% of the C footprint, depending on the assumptions chosen.…”

Section: Discussionmentioning

confidence: 99%

The role of the European small ruminant dairy sector in stabilising global temperatures: lessons from GWP* warming-equivalent emission metrics

Prado

Manzano

Pardo

2021

Journal of Dairy Research

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Recent calls advocate that a huge reduction in the consumption of animal products (including dairy) is essential to mitigate climate change and stabilise global warming below the 1.5 and 2°C targets. The Paris Agreement states that to stabilise temperatures we must reach a balance between anthropogenic emissions by sources and removals by sinks of greenhouse gases (GHG) in the second half of this century. Consequently, many countries have adopted overall GHG reduction targets (e.g. EU, at least 40% by 2030 compared to 1990). However, using conventional metric-equivalent emissions (CO2-e GWP100) as the basis to account for emissions does not result in capturing the effect on atmospheric warming of changing emission rates from short-lived GHG (e.g. methane: CH4), which are the main source of GHG emissions by small ruminants. This shortcoming could be solved by using warming-equivalent emissions (CO2-we, GWP*), which can accurately link annual GHG emission rates to its warming effect in the atmosphere. In our study, using this GWP* methodology and different modelling approaches, we first examined the historical (1990–2018) contribution of European dairy small ruminant systems to additional atmosphere warming levels and then studied different emission target scenarios for 2100. These scenarios allow us to envision the necessary reduction of GHG emissions from Europe's dairy small ruminants to achieve a stable impact on global temperatures, i.e. to be climatically neutral. Our analysis showed that, using this type of approach, the whole European sheep and goat dairy sector seems not to have contributed to additional warming in the period 1990–2018. Considering each subsector separately, increases in dairy goat production has led to some level of additional warming into the atmosphere, but these have been compensated by larger emission reductions in the dairy sheep sector. The estimations of warming for future scenarios suggest that to achieve climate neutrality, understood as not adding additional warming to the atmosphere, modest GHG reductions of sheep and goat GHG would be required (e.g. via feed additives). This reduction would be even lower if potential soil organic carbon (SOC) from associated pastures is considered.

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Effect of Feed Concentrate Intake on the Environmental Impact of Dairy Cows in an Alpine Mountain Region Including Soil Carbon Sequestration and Effect on Biodiversity

Cited by 17 publications

References 58 publications

Life cycle assessment of carbon dioxide removal technologies: a critical review

Life cycle assessment of carbon dioxide removal technologies: a critical review

Environmental life cycle assessment of cow milk in a conventional semi-intensive Brazilian production system

The role of the European small ruminant dairy sector in stabilising global temperatures: lessons from GWP* warming-equivalent emission metrics

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