Soil carbon sequestration in global working lands as a gateway for negative emission technologies

The ongoing climate crisis merits an urgent need to devise management approaches and new technologies to reduce atmospheric greenhouse gas concentrations (GHG) in the near term. However, each year that GHG concentrations continue to rise, pressure mounts to develop and deploy atmospheric CO₂ removal pathways as a complement to, and not replacement for, emissions reductions. Soil carbon sequestration (SCS) practices in working lands provide a low-tech and cost-effective means for removing CO₂ from the atmosphere while also delivering co-benefits to people and ecosystems. Our model estimates suggest that, assuming additive effects, the technical potential of combined SCS practices can provide 30%–70% of the carbon removal required by the Paris Climate Agreement if applied to 25%–50% of the available global land area, respectively. Atmospheric CO₂ drawdown via SCS has the potential to last decades to centuries, although more research is needed to determine the long-term viability at scale and the durability of the carbon stored. Regardless of these research needs, we argue that SCS can at least serve as a bridging technology, reducing atmospheric CO₂ in the short term while energy and transportation systems adapt to a low-C economy. Soil C sequestration in working lands holds promise as a climate change mitigation tool, but the current rate of implementation remains too slow to make significant progress toward global emissions goals by 2050. Outreach and education, methodology development for C offset registries, improved access to materials and supplies, and improved research networks are needed to accelerate the rate of SCS practice implementation. Herein, we present an argument for the immediate adoption of SCS practices in working lands and recommendations for improved implementation.     

Nutrient status of NPK-treated coffee plots

Summary The chemical properties of 128 soil samples collected from the surface and subsurface layers of 64 NPK treated coffee (Coffea canephora P.) plots were analysed. The ensuing data were compared with those from other coffee, cocoa and tropical soils of West Africa and Brazil. After seven years of NPK application to the coffee soil in Southwestern Nigeria, the soil was considered deficient in base elements especially Ca and Mg, N, P and K were considered fairly marginal. NPK treatments were found to effect statistically significant differences in the nutrient contents of coffee plots.     

玉米大豆对农林复合系统小气候的光合响应

对黄土区核桃(Juglans regia L.)-(玉米+大豆)、李子(Prunus salicina)-(玉米+大豆)农林复合系统小气候效应的研究表明,在玉米和大豆的花期,农林间作系统与对照地相比可以降低农田地面温度1.7-1.9℃,减低风速55%-67%,提高相对湿度6.9%-8.4%,降低光合有效辐射强度13.9%-24.5%和大气CO2浓度5.3-10.9μmol.mol-1。本研究中,单作大豆叶片光合速率午间变化主要受到非气孔的限制作用。逐步回归分析结果表明,光合有效辐射强度和大气CO2浓度是影响林下作物光合速率的主要环境因子。林下小气候可能是作物避免"午休"现象的主要原因。     

Phospholipids profile in chloroplasts of Coffea spp. genotypes differing in cold acclimation ability

Environmental temperature change may induce modifications in membrane lipid properties and composition, which account for different physiological responses among plant species. Coffee plants, as many tropical species, are particularly sensitive to cold, but genotypes can present differences that can be exploited to improve crop management and breeding. This work intended to highlight the changes promoted by low non-freezing temperatures (chilling) in phospholipid (PL) composition of chloroplast membranes of genotypes from two Coffea species, Coffea arabica cv. Catuaí (moderately tolerant) and Coffea canephora cv. Conilon (Clone 153, more susceptible), and relate them with cold sensitivity differences. Such evaluation was performed considering a gradual temperature decrease, chilling (4 °C) exposure and a recovery period under rewarming conditions. Catuaí presented an earlier acclimation response than Clone 153 (CL 153). It displayed a higher metabolic activity during acclimation (total fatty acids and total PL increases) and chilling (phosphatidylglycerol increases), and an overall better recovery. Catuaí also showed the highest phosphatidylglycerol unsaturation (higher double bond index) after chilling, in contrast with CL 153 (gradual unsaturation decrease). Higher unsaturation degree in Catuaí than in CL 153 was also observed for phosphatidylcholine and phosphatidylinositol, resulting, mainly, from raises in unsaturated C18:2 and C18:3. It is suggested that an enhanced PL synthesis and turnover induced by a gradual cold exposure, as well as unsaturation increases in major PL classes, is related to decreased Catuaí susceptibility to low temperatures and strongly contributes to sustain photosynthetic activity in this genotype under chilling conditions, as reported in previous work by this team.     

Floral species richness,structural diversity and conservation value of vanilla agroecosystems in Madagascar

Agricultural landscapes provide financial livelihoods for farming communities in rural areas. However, such agroenvironments can significantly impact the local floral biodiversity and introduce harmful invasive species to the ecosystem. Despite the prominence of plantations throughout the tropics, their effects on local flora are limited to only a few specific cash crops and geographical regions. Here, we compared the species richness and structural diversity of vegetation in natural forest fragments and three types of vanilla plantation within the Sava region of north-east Madagascar ranging from those within or adjacent to existing forests, to intensively cultivated plantations. We recorded data on plant species abundance, diameter at breast height and canopy cover within multiple sites of each habitat. We used abundance data to calculate species richness indices, and we compared these metrics between habitats. Forested habitats contained a significantly higher floral species richness, structural diversity and more endemic and regionally native species than nonforested, anthropogenic vanilla plantations. However, our results suggest that the high floral species richness and structural diversity of natural forests can be partially achieved in vanilla plantations, depending on the site's management regime; traditionally managed vanilla plantations located close to natural forests can support diverse floral communities. These encouraging findings for plant conservation and sustainable agroforestry in Madagascar suggest that that newly created vanilla plantations and already existing nonforested plantations should endeavour to follow the more traditional forested approach to enhance the future sustainability and promote floristic diversity.     

Determinants of the economic viability of mallee eucalypts as a short rotation coppice crop integrated into farming systems of Western Australia

Mallee eucalypts are being developed as a short rotation coppice crop for integration into agricultural systems in the south‐west of Western Australia. These have potential for biomass production for bioenergy, eucalyptus oil and generating carbon credits and to help control the extensive occurrence of dryland salinity. Some 12,000 ha of mallee planting has been undertaken since 1994, mostly in the form of wide‐spaced, narrow belts within the annual agricultural system. Production and market data were used to estimate levelized costs (LC) of mallee biomass production under different harvest regimes across 11 sites from 2006 to 2012. We found LC ranged from AUD40 to AUD257 fresh Mg^?1. LC was most strongly determined by mallee production, followed by the crop/pasture rotation decisions of the landholder. Mallee harvest regime had minor impact on LC. Crop and pasture yield loss due to competition from the mallee belts accounted for 38% of costs, harvesting biomass was 32%, opportunity cost of the land occupied by the mallee belts was 16% while establishment and maintenance costs accounted for 14% of the costs. When income from carbon sequestered in mallee root biomass was included, the LC dropped by an average of 11% at the current Australian price of AUD15 Mg^?1 CO₂ equivalent (CO₂e). The income from carbon sequestered in root biomass alone is unlikely to make mallee agroforestry economically viable. Hence, income from harvested biomass in the form of feedstocks for industry or carbon credits is necessary to make mallee agroforestry commercially attractive. LC for unharvested mallee belts ranged from AUD33 to AUD237 Mg^?1. Where above‐ and below‐ground biomass is converted to CO₂e at AUD15 Mg^?1, the LC drops to AUD11–AUD64, with three of 11 sites likely to be profitable. These three sites were characterized by high biomass production with low agricultural gross margins.