Litcius/Paper detail

Greenhouse gas, water, and land footprint per unit of production of the California dairy industry over 50 years

Anna Naranjo, A.C.B. Johnson, H.A. Rossow, E. Kebreab

2020Journal of Dairy Science81 citationsDOIOpen Access PDF

Abstract

e in 1964, a reduction of 45.0 to 46.9% over the last 50 yr, depending on the model used. Greater reductions in enteric methane intensity (i.e., methane production per kilogram of ECM) were observed (reduction of 54.1 to 55.7%) compared with manure GHG (reduction of 8.73 to 11.9%) in 2014 compared with 1964. This was mainly because manure management in the state relies on lagoons for storage, which has a greater methane conversion factor than solid manure storage. Water use intensity was reduced by 88.1 to 89.9%, with water reductions of 88.7 to 90.5% in crop production, 55.3 to 59.2% in housing and milking, and 52.4 to 54% in free water intake. Improved crop genetics and management have contributed to large efficiencies in water utilization. Land requirements for crop production were reduced by 89.4 to 89.7% in 2014 compared with 1964. This was mainly due to dramatic increases in crop yields in the last 50 yr. The increases in milk production per cow through genetic improvements and better nutrition and animal care have contributed to reductions in greenhouse gas emissions and land and water usage when calculated per unit of production (intensity) basis.

Topics & Concepts

Environmental scienceManureLife-cycle assessmentGreenhouse gasManure managementWater useAgricultureMilkingProduction (economics)Environmental engineeringEnvironmental protectionAnimal scienceAgronomyGeographyEcologyMacroeconomicsEconomicsBiologyArchaeologyAgriculture Sustainability and Environmental ImpactEnvironmental Impact and SustainabilityWater-Energy-Food Nexus Studies