Carbon accounting of negative emissions technologies integrated in the life cycle of spirulina supplements.

Carbon dioxide removal (CDR) technologies are considered essential to accomplish the Paris Agreement targets. Given the important contribution of the food sector to climate change, this study aims to investigate the role of two carbon capture and utilization (CCU) technologies in decarbonizing the production of spirulina, an algae product commonly consumed for its nutritional characteristics. The proposed scenarios considered the replacement of synthetic food-grade CO in Arthrospira platensis cultivation (BAU scenario) with CO from beer fermentation (BRW) and CO from DACC (direct air carbon capture) (SDACC), representing two alternatives with great potential in the short and medium-long term, respectively.

Regionalized Strategies for Food Loss and Waste Management in Spain under a Life Cycle Thinking Approach.

Food loss and waste (FLW) has become a central concern in the social and political debate. Simultaneously, using FLW as a bioenergy source could significantly contribute to closing the carbon cycle by reintroducing energy into the food supply chain. This study aims to identify best strategies for FLW management in each of the 17 regions in Spain, through the application of a Life Cycle Assessment.

Bringing value to the chemical industry from capture, storage and use of CO: A dynamic LCA of formic acid production.

Low carbon options for the chemical industry include switching from fossil to renewable energy, adopting new low-carbon production processes, along with retrofitting current plants with carbon capture for ulterior use (CCU technologies) or storage (CCS). In this paper, we combine a dynamic Life Cycle Assessment (d-LCA) with economic analysis to explore a potential transition to low-carbon manufacture of formic acid. We propose new methods to enable early technical, environmental and economic assessment of formic acid manufacture by electrochemical reduction of CO (CCU), and compare this production route to the conventional synthesis pathways and to storing CO in geological storage (CCS).

Spatial patterns of agricultural expansion determine impacts on biodiversity and carbon storage.

The agricultural expansion and intensification required to meet growing food and agri-based product demand present important challenges to future levels and management of biodiversity and ecosystem services. Influential actors such as corporations, governments, and multilateral organizations have made commitments to meeting future agricultural demand sustainably and preserving critical ecosystems. Current approaches to predicting the impacts of agricultural expansion involve calculation of total land conversion and assessment of the impacts on biodiversity or ecosystem services on a per-area basis, generally assuming a linear relationship between impact and land area.