Pierluigi Genevini

Assessing amendment properties of digestate by studying the organic matter composition and the degree of biological stability during the anaerobic digestion of the organic fraction of MSW.

The transformation of organic matter during anaerobic digestion of mixtures of energetic crops, cow slurry, agro-industrial waste and organic fraction of municipal solid waste (OFMSW) was studied by analysing different samples at diverse points during the anaerobic digestion process in a full-scale plant. Both chemical (fiber analysis) and spectroscopic approaches ((13)C CPMAS NMR) indicated the anaerobic digestion process proceeded by degradation of more labile fraction (e.g. carbohydrate-like molecules) and concentration of more recalcitrant molecules (lignin and non-hydrolysable lipids). These modifications determined a higher degree of biological stability of digestate with respect to the starting mixture, as suggested, also, by the good correlations found between the cumulative oxygen uptake (OD(20)), and the sum of (cellulose+hemicellulose+cell soluble) contents of biomasses detected by fiber analysis (r=0.99; P<0.05), and both O-alkyl-C (r=0.98; P<0.05) and alkyl-C (r=-0.99; P<0.05) measured by (13)C CPMAS NMR.

The effect of commercial humic acid on tomato plant growth and mineral nutrition

Abstract The effects of humic acids extracted from two commercially‐available products (CP‐A prepared from peat and CP‐B prepared from leonardite) on the growth and mineral nutrition of tomato plants (Lycopersicon esculentum L.) in hydroponics culture were tested at concentrations of 20 and 50 mg L‐1. Both the humic acids tested stimulated plants growth. The CP‐A stimulated only root growth, especially at 20 mg L‐1 [23% and 22% increase over the control, on fresh weight basis (f.w.b.), and dry weight basis (d.w.b.), respectively]. In contrast, CP‐B showed a positive effect on both shoots and roots, especially at 50 mg L‐1 (shoots: 8% and 9% increase over the control; roots: 18% and 16% increase over the control, on f.w.b. and d.w.b., respectively). Total ion uptake by the plants was affected by the two products. In particular, CP‐A showed an increase in the uptake of nitrogen (N), phosphorus (P), iron (Fe), and copper (Cu), whereas, CP‐B showed positive effects for N, P, and Fe uptake. The change in the F...

The influence of biomass temperature on biostabilization-biodrying of municipal solid waste.

A laboratory study was carried out to obtain data on the influence of biomass temperature on biostabilization-biodrying of municipal solid waste (initial moisture content of 410 g kg wet weight (w.w.)(-1)). Three trials were carried out at three different biomass temperatures, obtained by airflow rate control (A = 70 degrees C, B = 60 degrees C and C = 45 degrees C). Biodegradation and biodrying were inversely correlated: fast biodrying produced low biological stability and vice versa. The product obtained from process A was characterized by the highest degradation coefficient (166 g kg TS0(-1); TS0(-1) = initial total solid content) and lowest water loss (409 g kg W0(-1); W0 = initial water content). Due to the high reduction of easily degradable volatile solid content and preservation of water, process A produced the highest biological stability (dynamic respiration index, DRI = 141 mg O2 kg VS(-1); VS = volatile solids) but the lowest energy content (EC = 10,351 kJ kg w.w.(-1)). Conversely, process C which showed the highest water elimination (667 g kg W0(-1)), and lowest degradation rate (18 g kg TS0(-1)) was optimal for refuse-derived fuel (RDF) production having the highest energy content (EC = 14,056 kJ kg w.w.(-1)). Nevertheless, the low biological stability reached, due to preservation of degradable volatile solids, at the end of the process (DRI = 1055 mg O2 kg VS(-1)), indicated that the RDF should be used immediately, without storage. Trial B showed substantial agreement between low moisture content (losses of 665 g kg W0(-1)), high energy content (EC = 13,558 kJ kg w.w.(-1)) and good biological stability (DRI = 166 mg O2 kg VS(-1)), so that, in this case, the product could be used immediately for RDF or stored with minimum pollutant impact (odors, leaches and biogas production).

Determination of Biological Stability by Oxygen Uptake on Municipal Solid Waste and Derived Products

A new scientific apparatus and method are proposed for determining biological stability by oxygen uptake (respiration index, RI), on municipal solid waste (MSW) and derived products. For measuring the RI, a dynamic approach (with continuous aeration) was demonstrated to be more effective than the static approach (without aeration). The validity of the method was tested by comparing carbon losses calculated using both respirometric (carbon lossesresp) and analytical data (carbon lossesanal) during four trials performed on MSW and products derived from it. Carbon losses (expressed as g kg−1Ci, in which Ci represents initial carbon content) were: 219.0 and 248.0, 67.9 and 57.1, 39.6 and 36.4, and 250.7 and 280.3, using respirometric and analytical data alternately for Trials 1,2,3, and 4. The comparison between respirometric data using continuous or no aeration showed, for the latter, an underestimation of RI of between 70% and 90% that was more evident for unstable biomass leading to more similar values when stabilization occurred. The scientific apparatus proposed made it possible to measure oxygen uptake under autothermal conditions and avoid problems connected with the use of a preset temperature, biomass temperature being a consequence of the microbial activity, as is also suggested by the significant linear regression of T versus RI (R2 = 0.84, 0.73, 0.82, and 0.90 for the four trials, respectively). The methods proposed could be used with advantage in the future for biological stability measurements, above all for heterogeneous material such as MSW and its products, thus obtaining respirometric data that better reflect what happens during an aerobic process.

Chemical characterization of humic substances extracted from organic-waste-amended soils

Humic substances were extracted from a soil treated, in a 4-year experiment, at different rates with a sludge from anaerobic treatment of combined civil and industrial wastes, and with agricultural manure. Elemental and chemical analyses, molecular weight (MW) distribution and infrared (IR) spectroscopy were performed on the purified humic acids (HA). Organic wastes significantly increased the HA content of the treated soils and improved CEC. The C/N, C/H and C/O ratios of HA extracted from the original wastes showed a higher degree of humification for sludge than for manure. This difference was also noticed for the C/N ratio of soil humic extracts, indicating a faster humification process for the sludges in soil. The content of oxygen-containing functional groups was lower than the ‘model’ HA reported in the literature, and even more so for HA from sludges, reflecting their anaerobic formation. MW distribution and E4/E6 ratios showed that the sludge material had a higher molecular complexity than manure, supporting the high degree of humification attributed to the former. HA extracted from sludge-treated soils revealed a molecular dimension increasing with the application doses of waste material. Infrared spectra showed that HA formed in soils after waste additions reflected the chemical composition of the original organic material, which was rich in aliphatic groups and peptides for sludge and in carbohydrates for manure. On the basis of this study, it is concluded that not only are organic waste additions able to build up the HA content in soils but the HA formed assume the chemical characteristics and the degree of humification of the original material.

Qualitative modifications of humic acid-like and core-humic acid-like during high-rate composting of pig faeces amended with wheat straw

Abstract Humic acid-like (HA-like) and core-humic acid-like (core-HA-like) were characterized during the high-rate composting process by CP-MAS 13C NMR, pyrolysis-gas chromatography (GC)/mass spectrometry (MS), and elemental analysis. Results obtained indicated that humification proceeded through a relative concentration of aromatic fractions due to the faster degradation of the O-alkyl and alkyl fractions. Core-HA-like, after purification of the parent material, showed a large reduction of the O-alkyl fraction in terms of HA-like. We concluded that HA-like consisted of refractory organic molecules, such as lignin and biopolymers, which formed a stable structure (core-HA-like) coated with degradable material associated with the core by weak physical association, ether or ester bounds.

Effect of compost application rate on carbon degradation and retention in soils

We investigated the effect of a single compost application at two rates (50 and 85Mgha(-1)) on carbon (C) degradation and retention in an agricultural soil cropped with maize after 150d. We used both C mass balance and soil respiration data to trace the fate of compost C. Our results indicated that compost C accumulated in the soil after 150d was 4.24Mgha(-1) and 6.82Mg C ha(-1) for 50 and 85Mg ha(-1) compost rate, respectively. Compost C was sequestered at the rate of 623 and 617g C kg(-1) compost TOC for 50 and 85Mgha(-1) compost dose, respectively. These results point to a linear response between dose of application and both C degradation and retention. The amount of C sequestered was similar to the total recalcitrant C content of compost, which was 586g C kg(-1) compost TOC, indicating that, probably, during the short experiment, the labile C pool of compost (414g C kg(-1) of compost TOC) was completely degraded. Soil respiration measured at different times during the crop growth cycle was stable for soils amended with compost (CO2 flux of 0.96+/-0.11g CO2 m(-2) h(-1) and 1.07+/-0.10g CO2 m(-2) h(-1), respectively, for 50 and 85Mgha(-1)), whereas it increased in the control. The CO2 flux due to compost degradation only, though not statistically significant, was always greatest for the highest compost doses applied (0.22+/-0.40g CO2 m(-2) h(-1) and 0.33+/-0.25g CO2 m(-2) h(-1) for the 50 and 85Mgha(-1) compost dose, respectively). This seems to confirm the highest C degradation for the 85Mgha(-1) compost dose as a consequence of the presence of more labile C. Unlike other studies, the results show a slight increase in the fraction of carbon retained with the increase in compost application rate. This could be due to the highly stable state of the compost prior to application, although it could also be due to sampling uncertainty. Further investigations are needed to better explain how the compost application rate affects carbon sequestration, and how characterization into labile and recalcitrant C can predict the amount of C sequestered in the soil.

Rice hull degradation by co-composting with dairy cattle slurry

Abstract A liquid dairy cattle slurry was composted using rice hulls as absorbing matrix and bulking agent. The main results obtained were as follows: 1) The structure and size of the rice hulls as well as their absorption capacity, enables to obtain a good composting mixture (moisture: 714.2 g kg−1; C/N ratio: 28.80; bulk density: 0.429 Mg m−3). 2) Compost stability was reached after 58 d of composting, with the following characteristic: (on a dry matter basis), volatile solids 730.0 g kg−1, C/N 18.36, TKN 19.8 g kg−1, K 18.4 g kg−1, P 11.3 g kg−1, humfied carbon 46 J g kg−1, respirometric index 0.88 mg O2 g−1 VS h−1, dry matter yield 573.4 g kg−1, organic matter yield 500.5 g kg−1, water losses 569.9 g kg−1 and airlow-rate (m3 kg−1 d.m. d−1): maximum 2.96, minimum 0.28, mean 0.75. 3) The curing phase was determined when a high degree of compost maturity was reached. After 254 d of composting the data obtained (on a dry matter basis) were as follow: volatile solids 658.9 g kg−1, C/N 13.52, TKN 25.1 g kg−...

The Effects of Short-Term Compost Application On Soil Chemical Properties and on Nutritional Status of Maize Plant

Compost may improve the soil quality and contribute to C sequestration. The short-term effects of compost application on soil properties of soil cropped with maize are reported here. Soil plots to which mature compost was added (at 50 Mg ha−1 and 85 Mg ha−1) were analyzed for total organic carbon (TOC), nutrients, heavy metals and other soil properties. In addition, maize plants were weighed at the end of the trial and analyzed for carbon (C), nitrogen (N), phosphorus (P) and heavy metals. The results demonstrate that soil amended with compost has an increased TOC content. The increase was proportional to the amount of compost used. At the highest dose used, compost also increased soil N and P content and the pH. Moreover, after compost application, the total heavy metal contents in soils did not increase. There was no difference between the maize yield from compost treated plots and the control plots. However, maize grains were found to be C, N and P enriched due to the increased nutrient status of the amended soil. In conclusion, the addition of mature compost improves soil properties by increasing the soil TOC content and this depends on the characteristics and the amount of compost used.

The role of manure in the management of phosphorus resources at an Italian crop-livestock production farm

A quantitative knowledge of P cycling in dairy farms during a production cycle is the basis for optimizing fertilizer P management, because utilization of P by farm animals and its transfer to barn products are incomplete; animal manure represents a valuable source of P to sustain crop requirements. The nutrient content of manure is always difficult to determine precisely, because of the variability and fluctuation in daily water content and composition. Estimates of the P content of each material that moves to, from and within a dairy farm located in Lombardy were determined for one year by collecting farm data, sampling and analyzing farm materials (feeds, beddings, milk, hays and silage, etc.) and estimating through model calculation P retained in animals and in farm wastes. Two subcycles were investigated: the barn subcycle and the soil-crop subcycle, connected together by wastes, grasses and corn silage. The overall P balance in the farm studied with total stocking of 1.1 t of liveweight/ha, indicated a high manure potential for crop-needs that excludes use of inorganic P fertilizers. Moreover, detailed analysis of the various P pools has shown the relative contribution of each component to P cycling at the farm.