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The oleaginous alga Chlorella protothecoides accumulates lipid in its biomass when grown in nitrogen-restricted conditions. To assess the relationship between nitrogen provision and lipid accumulation and to determine the contribution of photosynthesis in mixotrophic growth, C. protothecoides was grown in mixo- and heterotrophic nitrogen-limited continuous flow cultures. Lipid content increased with decreasing C/N, while biomass yield on glucose was not affected. Continuous production of high lipid levels (57% of biomass) was possible at high C/N (87-94). However, the lipid production rate (2.48 g L(-1) d(-1)) was higher at D=0.84 d(-1) with C/N 37 than at D=0.44 d(-1) and C/N 87 even though the lipid content of the biomass was lower (38%). Photosynthesis contributed to biomass and lipid production in mixotrophic conditions, resulting in 13-38% reduction in CO2 production compared with heterotrophic cultures, demonstrating that photo- and heterotrophic growth occurred simultaneously in the same population.

Abstract Nitrous oxide (N2O) is an important long-lived greenhouse gas and precursor of stratospheric ozone-depleting mono-nitrogen oxides. The atmospheric concentration of N2O is persistently increasing; however, large uncertainties are associated with the distinct source strengths. Here we investigate for the first time N2O emission from terrestrial vegetation in response to natural solar ultra violet radiation. We conducted field site measurements to investigate N2O atmosphere exchange from grass vegetation exposed to solar irradiance with and without UV-screening. Further laboratory tests were conducted with a range of species to study the controls and possible loci of UV-induced N2O emission from plants. Plants released N2O in response to natural sunlight at rates of c. 20–50 nmol m−2 h−1, mostly due to the UV component. The emission response to UV-A is of the same magnitude as that to UV-B. Therefore, UV-A is more important than UV-B given the natural UV-spectrum at Earth's surface. Plants also emitted N2O in darkness, although at reduced rates. The emission rate is temperature dependent with a rather high activation energy indicative for an abiotic process. The prevailing zone for the N2O formation appears to be at the very surface of leaves. However, only c. 26% of the UV-induced N2O appears to originate from plant-N. Further, the process is dependent on atmospheric oxygen concentration. Our work demonstrates that ecosystem emission of the important greenhouse gas, N2O, may be up to c. 30% higher than hitherto assumed.

Abstract The combination of catch crop cultivation with its use for biogas production would increase renewable energy production in the form of methane, without interfering with the production of food and fodder crops. The low biomass yield of catch crops has been shown as the main limiting factor for using these crops as co-substrate in biogas plants, since the profit obtained from the sale of methane barely compensates the harvest costs. Therefore, a new agricultural strategy to harvest catch crops together with the residual straw of the main crop was investigated, in order to increase the biomass and the methane yield per hectare. Seven catch crops harvested together with stubble from the previous main crop were evaluated. The effects of stubble height, harvest time and ensiling as a storage method for the different catch crops/straw blends were studied. Biomass yields as TS ranged between 3.2 and 3.6 t ha−1 y−1of which the catch crop constituted around 10% of the total biomass yield. Leaving the straw on the field until harvest of the catch crop in the autumn could benefit methane production from the straw both due to increased biomass yield and an increased organic matter bioavailability of the straw taking place on the field during the autumn months. Ensiling as a storage method could be feasible in terms of energy storage and guaranteeing the feedstock availability for the whole year. This new agricultural strategy may be a good alternative for economically feasible supply of catch crops and straw for biogas production.

Abstract This paper presents a study of the energy balance of utilising nature conservation biomass from meadow habitats in Danish biogas production. Utilisation of nature conservation grass in biogas production in Denmark represents an interesting perspective for enhancing nature conservation of the open grassland habitats, while introducing an alternative to the use of intensively cultivated energy crops as co-substrates in manure based biogas plants. The energy balance of utilising nature conservation grass was investigated by using: data collected from previous investigations on the productivity of meadow areas, different relevant geo-datasets, spatial analyses, and various statistical analyses. The results show that values for the energy return on energy invested (EROEI) ranging from 1.7 to 3.3 can be obtained when utilising meadow grasses in local biogas production. The total national net energy gain (NEG) was estimated to more than 600,000 GJ corresponding to ≈15% of the total Danish biogas production in 2012.

Based on the approach of 'arena of development' controversies over bioenergy in the shaping of a Danish climate strategy are analyzed as a contribution to a sustainable transition perspective on bioenergy in industrialized societies with substantial agricultural production. Bioenergy plays a prominent role in several Danish climate and energy plans, alongside with wind and solar energy, and energy savings. There are major controversies about targets for bioenergy with respect to acceptable types, sources and amounts of biomass. Strong path dependency is identified. Energy companies in Denmark convert coal fired power plants to biomass in order to sustain the role of these power plants. Their increasing use of imported wood pellets is criticized for increasing greenhouse gas emissions because of fast logging of years of forest growth. A Danish biotech company is developing enzymes for processing of biomass for biofuels. The alignment with the private car regime is strong, because biofuel enables continuation of fuel-driven vehicles as dominating transportation mode. Danish farmers see manure as important source for biogas while arguing for reduction of climate impact and nuisances from digested manure. Such biogas is questioned by some NGOs who fear manure-based biogas is used as argument for increased animal husbandry. The bioenergy controversies concern also methodologies for environmental assessments, including for indirect land use changes (ILUC), and reliability of certification schemes. The mapping of controversies identifies issues that probably need to be taken into account in shaping of Danish bioenergy strategies if these strategies should gain substantial legitimacy among environmental NGOs.

AbstractEnvironments are changing rapidly, and to cope with these changes, organisms have to adapt. Adaptation can take many shapes and occur at different speeds, depending on the type of response, the trait, the population, and the environmental conditions. The biodiversity crisis that we are currently facing illustrates that numerous species and populations are not capable of adapting with sufficient speed to ongoing environmental changes. Here, we discuss current knowledge on the ability of animals and plants to adapt to environmental stress on different timescales, mainly focusing on thermal stress and ectotherms. We discuss within‐generation responses that can be fast and induced within minutes or hours, evolutionary adaptations that are often slow and take several generations, and mechanisms that lay somewhere in between and that include epigenetic transgenerational effects. To understand and predict the impacts of environmental change and stress on biodiversity, we suggest that future studies should (1) have an increased focus on understanding the type and speed of responses to fast environmental changes; (2) focus on the importance of environmental fluctuations and the predictability of environmental conditions on adaptive capabilities, preferably in field studies encompassing several fitness components; and (3) look at ecosystem responses to environmental stress and their resilience when disturbed.

Abstract This study discusses about the environmental performance of Miscanthus conversion to district heat. Life Cycle Impact Assessment (LCIA) is used as a tool to assess the environmental impacts related to the biomass conversion to heat. Energy conversion of Miscanthus is compared in two combustion scenarios: (i) in Combined Heat and Power (CHP) plant and (ii) in a Boiler (producing heat only). Biomass conversion to heat is also compared with the conversion of natural gas (NG). The environmental impact categories considered for the assessment are: Global Warming Potential (GWP), Non-Renewable Energy (NRE) use and Land use (LU). The current study revealed that for 1 MJ of heat production, Miscanthus fired in the CHP plant would lead to a GWP at −0.071 kg CO 2 -eq, an NRE use −0.767-MJ primary, and LU 0.09 m 2 -a (square metre-annual). For the same heat output, Miscanthus fired in the boiler would lead to a GWP of 0.005 kg CO 2 -eq, NRE use 0.172 MJ-primary and land use 0.063 m 2 -a. Miscanthus fired in the CHP plant is better than in the boiler from the stand point of lowering the GWP and increasing the savings in fossil fuel, but with slightly higher LU. A comparison between Miscanthus and NG has showed that despite the biomass possessed advantage in reducing GWP and NRE use, additional land required for Miscanthus could be seen as a disadvantage.

One of the common tendencies of animal production activities in Europe and in developed countries in general is to intensify the animal production and to increase the size of the animal production units. High livestock density is always accompanied by production of a surplus of animal manure, representing a considerable pollution threat for the environment in these areas. Avoiding over-fertilization is not only important for environmental protection reasons but also for economical reasons. Intensive animal production areas need therefore suitable manure management, aiming to export and to redistribute the excess of nutrients from manure and to optimize their recycling. Anaerobic digestion of animal manure and slurries offers several benefits by improving their fertilizer qualities, reducing odors and pathogens and producing a renewable fuel - the biogas. The EU policies concerning renewable energy systems (RES) have set forward a fixed goal of supplying 20% of the European energy demands from RES by year 2020. A major part of the renewable energy will originate from European farming and forestry. At least 25% of all bioenergy in the future can originate from biogas, produced from wet organic materials such as: animal manure, whole crop silages, wet food and feed wastes, etc.