Surface Soil Salinity and Soluble Salts after 15 Applications of Composted or Stockpiled Manure with Straw or Wood-Chips

The influence of 15 annual applications of composted (CM) or stockpiled (SM) beef feedlot manure with straw (ST) or wood-chip (WD) bedding on electrical conductivity (EC), soluble cations and anions (Na, K, Ca, Mg, SO₄-S, Cl), sodium adsorption ratio (SAR), potassium adsorption ratio (PAR), and pH of a clay loam soil (0–15 cm) in southern Alberta was examined in an irrigated barley silage cropping system. Manure type (CM versus SM) had a significant effect on certain soil salinity parameters. Calcium, Mg, Na, K, and SO₄-S were significantly (p ≤ 0.05) greater for SM- than CM-amended soils for certain bedding materials and rates. Electrical conductivity, concentration of soluble cations and anions (Na, K, SO₄-S, Cl), SAR, PAR, and pH in the surface soil were greater for ST than WD bedding. Two exceptions were Ca and Mg, where soil concentrations were generally greater for WD than ST. Salinity parameters were greater with increased application rate, and greater for amended than unamended soils. Overall, bedding had considerably more significant effects on soil salinity parameters compared to manure type. Wood-chip bedding may be a management tool for feedlots to lower EC, soluble cations and anions, and pH of surface soils.     

Influence of long-term application of composted or stockpiled feedlot manure with straw or wood chips on soil cation exchange capacity

The influence of annual applications of composted (CM) or stockpiled (SM) beef feedlot manure with straw (ST) or wood-chip (WD) bedding on cation exchange capacity (CEC) of a clay loam soil in southern Alberta was examined after 1, 8, and 15 years. The hypotheses in our study were that soil CEC should be greater for amended than unamended soils; manure type and bedding should have no effect on soil CEC; and soil CEC should increase with greater manure application rate. After fifteen applications, the CEC was significantly greater for amended than unamended soils. Manure type had no significant (P > 0.05) effect on soil CEC after fifteen applications, and the mean soil CEC was 5% greater for WD than ST. Mean CEC was significantly greater by 7 to 12% for the 77 than the 13 and the 39 Mg ha^?1 rates after fifteen applications. The soil CEC was increased by 0.061 cmol_c kg^?1 for a unit increase in application rate (Mg dry wt. ha^?1 yr^?1), and 96% of the variation in CEC for amended soils could be explained by application rate. Overall, bedding, rate, or adjusting both bedding type and manure rate (but not manure type), may be possible practices for feedlot producers to manage soil CEC.     

Nitrogen Budgets Following Land Application of Composted or Stockpiled Feedlot Manure Containing Wood-Chips or Straw Bedding to Barley Silage for 12 Years

ABSTRACT

Land application of composted feedlot manure (CM) instead of stockpiled manure (SM) at increasing application rates to cropland, or use of wood-chip (WD) instead of straw (ST) bedding, may influence the nitrogen (N) balance and cause N surpluses. This could result in environmental losses of N to the atmosphere, surface, or ground waters. We determined the influence of manure type, bedding material, and application rate (13, 39, 77 Mg ha^?1 dry wt.) on cumulative N inputs, outputs, and N balance (aboveground system) for a long-term (since 1998) field experiment where manure had been repeatedly applied for 2, 7, and 12 yr. The annual N inputs considered were N in organic amendments or inorganic fertilizer (IN), and N in irrigation water. The annual N outputs considered were N in crop uptake, NH₃ volatilization, and N₂O gaseous loss. After 12 applications, cumulative N deficits occurred for the unamended control (?1140 kg N ha^?1) and IN treatment (?678 kg N ha^?1), and cumulative N surpluses were found for the organic amendments (689 to 12,200 kg N ha^?1). Manure type, bedding, and application rate influenced the N balance for the three timelines but their effects often involved two- or three-way interactions. The N balance after 7 and 12 applications was significantly lower for CM-WD treatment compared to CM-ST, SM-ST, and SM-WD at the 39 and 77 Mg ha^?1 rates, suggesting that composted manure with wood chips might be used to reduce cumulative N surplus at these two higher rates in the longer term.     

The Effect of Severe Drought on the Evolution of Urban and Manure Wastes in an Agricultural Soil in Mediterranean Ecosystems

In semi‐arid Mediterranean soils, water availability is the most limiting factor, negatively affecting the organic matter (OM) degradation. The aim of this work is to study under controlled laboratory conditions how three sources of OM [municipal solid waste (MSW), sheep manure (SM) and cow manure (CM)] behave when they are applied to an agricultural soil subjected to a severe year‐long drought. In order to apply the same concentration of OM to the soil (16·92 Mg OM ha⁻¹), 2 kg of soil was mixed with 30, 67·41 and 55·25 Mg ha⁻¹ (dry matter) of MSW, CM and SM, respectively. Two levels of irrigation were employed: (i) watered soils and (ii) non‐watered soils. Soil's chemical properties [water soluble carbon (WSC), humic acids, fulvic acids and protein mass distribution], biological properties (soil microbial biomass carbon and o‐diphenoloxidase activity) and solid‐state ¹³C cross‐polarisation magic angle spinning nuclear magnetic resonance spectroscopy were determined. In watered soils, the soil microbial biomass carbon was higher in the SM than in CM and MSW treatments (9·9% and 23·1%, respectively). The WSC was significantly higher in SM than in CM (55·7%) and MSW (78·7%) treatments. A decrease in the content of O‐alkyl C and an increase in alkyl C, aromatic C and carboxyl C were observed. In non‐watered soils, the biochemical properties and alkyl C and alkyl/O‐alkyl ratio decreased, whereas WSC content and O‐alkyl C increased. These results indicated that the evolution of OM and the activity of the microbial community in non‐watered soils were very different to those in the watered soils. Copyright © 2016 John Wiley & Sons, Ltd.     

Long-term tillage and straw returning effects on organic C fractions and chemical composition of SOC in rice-rape cropping system

Understanding the different C pools and chemical composition of soil organic carbon (SOC) in cropping system is imperative for sustaining soil quality. This study examined the effects of tillage and straw returning practices on organic C fractions and chemical composition of SOC under a rice-rape system in central China. The field experiment consisted of conventional tillage (CT); conventional tillage with straw returning (CTS); no-tillage (NT); and no-tillage with straw returning (NTS) treatments. Compared to CT, NT significantly increased SOC stocks, SCMI and C fractions of 0–20 cm depth by 6–50%. The SOC, particulate organic carbon (POC), microbial biomass carbon (MBC), easily oxidizable carbon (EOC), dissolved organic carbon (DOC) contents of 0–20 cm depth were 16, 80, 24, 22 and 13%, respectively, higher under NTS treatment. Straw returning enhanced the relative contents of O-alkyl C, carbonyl C, alkyl C, A/O-A ratio, and aromaticity. The correlations of SOC with C fractions and SCMI were significant. O-alkyl C was positively correlated with C fractions and negatively correlated with carbonyl C and alkyl C. In conclusion, long-term tillage and straw returning significantly affected the fractions and chemical compositions of SOC, could be viable option for improving the soil quality in the rice-rape rotation system.     

黑土根际土壤有机碳及结构对长期施肥的响应

由于人类农业措施的干扰,氮肥和畜禽粪污大量输入到黑土中,对土壤有机碳库产生了较大负面影响。根际有机碳在调控土壤碳循环和养分转化中发挥着重要的作用。探明根际有机碳对不同养分的生态响应,可为不同施肥处理下黑土农田生态系统碳固持和农田可持续利用提供理论依据。该研究以黑土长期定位试验为基础,采集长期不施肥（CK）、常量氮（N）、二倍量氮（N2）、常量有机肥（M）、二倍量有机肥（M2）、常量有机肥+常量氮（MN）、二倍量有机肥+二倍量氮（M2N2）7个处理下大豆根际土壤,分析了根际有机碳和活性有机碳特征,同时利用固态核磁共振技术分析其光谱特征。结果表明,N、M2、MN和M2N2处理的根际土壤有机碳含量显著高于非根际水平,且以MN和M2N2处理的根际效应最显著,分别比非根际增加了18.3%和26.7%。分析核磁共振光谱显示,与非根际土壤相比,根际土壤具有较高的烷氧基碳比例和较低芳香碳比例,表明根际效应能够改变土壤有机碳结构比例。与不施肥处理相比,大部分施肥处理提升了黑土根际有机碳含量,其中以氮肥马粪配施和二倍量马粪（M2N2）处理提升幅度最高。由核磁共振图谱可知,M2和M2N2处理均增加根际土壤难降解成分烷基碳比例、芳香基碳比例、烷基碳与烷氧基碳比值、芳香碳与总碳比值,而MN处理仅增加烷基碳比例、烷氧基碳比例以及烷基碳与烷氧基碳比值。二倍量氮肥（N2）处理降低烷基碳比例、芳香碳比例和烷氧基碳比例,根际土壤难降解成分降低,不利于土壤固碳,同时证明固态 13C-核磁共振技术结合半定量分析能够准确地分析不同有机碳结构组分变化,深刻认识根际土壤有机碳的稳定机制。     

The Role of Organic Soil Amendments on Soil Physical Properties and Yield of Maize (Zea mays L.)

The objective of this study is to examine the role of some organic (composted tobacco waste, CTW; bio-humus, BH; chicken manure, CM) soil amendments on soil physical properties and yield of maize. A 3-year field experiment was conducted at the Agricultural Research Farm of Ege University in Menemen, Izmir, Turkey from 2009 to 2011. The treatments, (1) control, (2) 4 t/ha CM+NPK, (3) 50 t/ha CTW, (4) 10 t/ha BH+NPK, were arranged in complete randomized block design with four treatment replications. Both of BH (composted plant residues) and CM were obtained from organic manure industry. Tobacco wastes were gathered from the cigarette industry and applied to maize (Zea mays L.) after composting period with the other amendments. During the experiment, two soil samples were collected in three different periods (3 June 2009–23 October 2009; 1 June 2010–5 November 2010; 13 July 2011–21 October 2011). The effects of CM, BH, and CTW on physical properties of the soil and yield were investigated. According to our results, all organic amendments increased porosity, structure stability index, field capacity, wilting point, and available water amount and decreased bulk density and particle density of soil when compared to the control. We additionally determined that these organic amendments positively affected grain yield.     

Effects of long-term application of various organic amendments on soil particulate organic matter storage and chemical stabilisation of vertisol soil

Current understanding of the effects of long-term application of various organic amendments on soil particulate organic matter (POM) storage and chemical stabilisation remains limited. Therefore, we collected soil samples from the soil profile (0–100?cm) under six treatments in a 31-year long-term fertilisation experiment: no fertiliser (CK), mineral fertilisers (NPK), mineral fertilisers plus 3.8 or 7.5?t?ha^?1?year^?1 (fresh base) the amount of wheat straw (1/2SNPK and SNPK) and mineral fertilisers plus swine or cattle manure (PMNPK and CMNPK). Long-term incorporation of wheat straw and livestock manure amendments significantly (p?<?0.05) increased crop yield and sustainable yield index, and POM storage compared with CK and NPK treatments. The mole ratios of H/C in the POM under organic amendment treatments significantly (p?<?0.05) decreased by 13.8% and 37.1%, respectively, compared with the NPK treatment. Similarly, solid state NMR spectroscopy showed that the O–alkyl carbon content of POM was greatly decreased, whereas aromatic carbon contents and alkyl to O–alkyl carbon ratios were substantially increased under PMNPK and CMNPK treatments. In conclusion, we recommend long-term livestock manure application as a preferred strategy for enhancing POM quantity and quality (chemical stability), and crop yield of vertisol soil in northern China.     

长期施肥条件下红壤有机碳化学结构与团聚体稳定性的关系

[目的]红壤普遍存在团聚体结构较差和有机碳含量较低的问题,土壤有机碳是影响土壤团聚体结构的重要指标,但以往研究主要关注有机碳含量与团聚体的相关关系,而对有机碳的化学结构如何调控团聚体结构则缺乏深入研究.[方法]依托始于1986年的红壤旱地长期施肥试验,选取不施肥(CK)、施用氮磷肥(NP)、施用氮磷钾肥(NPK)、施用...     

Utilizing Composted Beef Cattle Manure and Slaughterhouse Waste as Nitrogen and Phosphorus Fertilizers for Calcareous Soil

Effectively utilizing composts requires that their nitrogen (N) and phosphorus (P) contents be used as fertilizer, but how this is best accomplished is not fully understood. The authors' objective was to quantify N and P availability of a calcareous clay loam soil receiving composts derived from four contrasting beef cattle feedlot feedstocks applied at 50, 150, and 450 mg total P kg^?1 and supplemented twice with fertilizer N for a 42-week greenhouse plant bioassay. Three composted manures from beef cattle fed distinct diets and a composted mix of slaughterhouse and construction waste were applied. Inorganically fertilized and non-amended soils were included as controls. Canola (Brassica napus L.) and pea (Pisum sativum L.) were grown in pots containing 1.5 kg air-dried soil for six alternating 7-week cycles. Soils amended with composted manure from beef cattle fed typical finishing diets had the lowest apparent N recovery (31%) and the greatest soil nitrate after 42 weeks (25 mg N kg^?1). Phosphorus availability was greater with composted manure from beef cattle fed distillers' dried grains than composted manure from beef cattle fed typical finishing diets and a composted mixture of slaughterhouse and construction waste. Apparent P recovery (66%) was greatest from composted manure of beef cattle fed corn (Zea mays L.) distillers' dried grains applied at 50 mg total P kg^?1. Composted manure from beef cattle fed distillers' dried grains had greater P availability than conventional composted beef cattle feedlot manure. Overall, performance of the composted mixture of slaughterhouse and construction waste was similar to the composted beef cattle manures.     

Evaluation of Farm Plot Conditions and Effects of Fish Scrap Compost on Yield and Mineral Composition of Field Grown Maize

? The increasing availability of composted soil amendments derived from residues not normally encountered in farming has prompted this study of fish scrap compost. An on-farm field trial with maize (Zea mays) was established to test the effects of composted fish scrap (CFS) in comparison to un-composted farmyard manure (FYM) and inorganic nutrients (NPK). Fish scraps were previously composted with sawdust. Farm manure resulted from bedding dairy animals with a sawdust/straw mixture. Both CFS and FYM had C:N ratios of approximately 31. Yields and nutrient content were evaluated following application of 0.50, 23 and 106 Mg/ha of NPK, FYM and CFS, respectively which were applied based on estimated N-release. Ear-node leaves sampled at tasseling and analyzed for major and minor nutrients indicated that phosphorus was very significantly lower in compost compared to manure and NPK. Statistical analysis revealed that were was no significant differences in yields which decreased in the order FYM > NPK > CFS > Control. Simple regression analysis indicated that no single tissue trait explained yields but multiple regression showed that P and Cu levels in tissue explained 55% of yield variation (p=0.026). Apparently, the relatively high C:N of aged CFS and FYM had little or no effect on growth while slightly but not significantly decreasing plant total-N in CFS plots. The study underscores the fact that previous soil conditions on the farm must be accounted for before traits like C:N or other mineral characteristics of amendments are used to predict yield potential.     

Chemical composition of the organic matter in forest soils: The humus layer

Decomposition and humification were studied within three types of forest humus (mull, moder, and mor) by means of CPMAS ¹³C NMR spectroscopy combined with degradative methods. The NMR data show that O-alkyl carbon decreases in all soils, and alkyl as well as carboxyl carbon increase as depth and decomposition increase; the percentage of aromatic carbon remains constant at about 25%. With increasing depth the amount of carbon that can be identified as belonging to specific compound classes by wet chemical methods decreases from 60% to 40%. Microbial polysaccharides and the proportion of non polysaccharide O-alkyl carbon increase with depth. A selective preservation of recalcitrant, condensed lignin structural units is also observed. In order to relate the spectroscopic and chemical data from investigations of whole soils with studies of humification, samples were fractionated into fulvic acid, humic acid, and humin fractions. The fulvic acid fraction contains large concentrations of carbohydrates irrespective of the soil horizon. The humic acid fraction contains less polysaccharides, but high amounts of alkyl carbon and aromatic structures. The percentage of aromatic carbon existing in the humic acid fraction increases with depth, probably reflecting the amount and degree of oxidative decomposition of lignin. A loss of methoxyl and phenolic groups is evident in the ¹³C NMR spectra of the humic acid fraction. The humin fraction resembles relatively unchanged plant-derived materials as evident from the lignin parameters and carbohydrate contents. All the observed data seem to indicate that humic acids originate form oxidative degradation of humin or plant litter.     

The role of non‐crystalline Fe in the increase of SOC after long‐term organic manure application to the red soil of southern China

Because of the important role of soil organic carbon (SOC) in nutrient cycling and global climate changes, there has been an interest in understanding how different fertilizer practices affect the SOC preservation and promotion. The results from this study showed that long‐term application of manure (21 years) could increase significantly the content of SOC, total nitrogen (N) and soil pH in the red soil of southern China. The chemical structure of SOC was characterized by using solid‐state cross‐polarization magic angle spinning (CPMAS) ¹³C nuclear magnetic resonance (NMR) spectroscopy, and the aromatic C, ratio of alkyl C : O‐alkyl C, aromaticity and hydrophobicity of mineral fertilizers N, P and K plus organic manure (NPKM) and organic manure (M) treatments were less than those of mineral fertilizer nitrogen (N) and mineral fertilizers N, P and K (NPK) treatments. Both poorly crystalline (Fe_o) and organically complexed (Fe_p) iron contents were influenced significantly (P < 0.05) by different fertilizers, and it was observed that NPKM and M treatments increased the non‐crystalline Fe (Fe_o‐Fe_p) content. There was a significant (P < 0.01) positive correlation between soil organic C and non‐crystalline Fe in both the surface (0–20 cm) and subsurface (20–40 cm) soils. The results suggested that non‐crystalline Fe played an important role in the increase of SOC by long‐term application of organic manure (NPKM and M) in the red soil of southern China.     

施用玉米植株残体对土壤富里酸组成、结构及其变化的影响

采用元素分析和谱学方法对施入玉米植株残体后的土壤FA的变化进行了研究，结果表明，施入玉米植株残体后土壤FA的C、H、N含量均升高，而O的含量降低，并且C／H、O／C和C／N比值均降低。土壤中FA的羧基含量减少，芳香碳的含量下降，FA的氧化程度降低，芳香度显著下降，FA的分子结构向更为简单化的方向发展。同时，酰胺成分增加，脂族链烃结构成分明显增多。土壤FA与无机矿物质的结合能力相对减弱，FA上的羧基逐渐由羧酸盐的形式向游离的羧基形式过渡。玉米植株残体的加入使FA中糖类结构成分增加。对土壤中FA的影响，施入玉米秸秆和根系残体的处理有一定差别。     

Changes in Chemistry of Rice Husk Compost and Its Effect on Negative Charge and Nutrient Content of a Chemically Degraded Oxisol

Rice husk application and its long-term effects on charge characteristics and elemental composition of a chemically degraded Oxisol have not been rigorously studied. The objective of the study was to determine the ability of composted rice husk (CRH) to preserve organic carbon (C), generate negative charge, and release various ions in heavy clay Oxisol. The topsoil and subsoil, representing natural and erosion conditions, respectively, were incubated with CRH for 24 months. Results showed carbon types of CRH, as revealed by solid-state cross-polarization magic angle spinning ¹³C nuclear magnetic resonance (CP/MAS ¹³C NMR) spectroscopy, were relatively unchanged from months 5 to 12 after incubation, indicating limited decomposition. Carbon types were dominated by O-alkyl and di-O-alkyl C with small proportions of alkyl, methoxyl, aromatic, phenolic, and carboxyl C. After 24 months of incubation, O-alkyl and di-O-alkyl C decreased, indicating susceptibility, whereas alkyl, methoxyl, aromatic, and phenolic C increased, indicating resistance to decomposition. Values of pH₀ and point zero net charge (PZNC) were measured using potentiometric titration and ion adsorption indices, respectively. Values of pH₀ and PZNC decreased during CRH incubation for both topsoil and subsoil, suggesting the increase of soil negative charge. Total negative charge for topsoil and subsoil increased from 2.7 to 3.5 cmol_c/kg and 2.5 to 3.2 cmol_c/kg, respectively. This reflects that CRH was able to mask soil positive charge to increase negative charge. In situ soil solution study indicated CRH could release various elements in the order of potassium (K) > sulfur (S) > natrium (Na) > silicon (Si) > magnesium (Mg) > calcium (Ca). In addition, toxic elements, aluminum (Al) and manganese (Mn), were significantly suppressed. The implication of the study is that CRH offers a means to increase cation exchange capacity and nutrient content of highly weathered soils while preserving organic C, thereby reducing CO₂ emission from agriculture.     

Land-use effects on the composition of organic matter in particle-size separates of soils: II. CPMAS and solution 13C NMR analysis

Soils from A horizons of Eutrochrepts under spruce forest (Sf), mixed deciduous forest (Df), permanent grassland (Gp), and arable rotation (Ar) were fractionated into clay- (<2 μm), silt-(2–20 μm) and sand- (20–2000 μm) sized separates. ¹³C NMR spectroscopy was used to compare SOM composition across size separates and between land-use regimes. CPMAS ¹³C NMR spectroscopy showed that the intensity of signals assigned to carbohydrates (representing most O-alkyl C) and lignin (phenolic and methoxyl C) declined with decreasing particle size. Concurrently, alkyl C and C-substitution of aromatic C increased in the order sand, silt, clay. The amount of alkyl C correlated well with microbial resynthesis of carbohydrates. Solution ¹³C NMR spectra suggested that humic acids (HA) extracted from the size separates were richer in carboxyl C and aromatic C than the bulk size separates. Also HA reflected increasing percentage of alkyl C with decreasing particle size. O-alkyl C were lower in silt HA than in clay HA whereas aromatic C tended to peak in silt HA. These results suggested that sand-sized separates were enriched in plant residues (primary resources) whereas clay-sized separates were dominated by products of microbial resynthesis (secondary resources). Silt was rich in selectively preserved and microbially transformed primary resources. ¹³C NMR spectroscopy showed only small differences in SOM composition between land-use regimes, except that silt and silt HA from Ar were richer in aromatic C than those from the other plots. But enrichment factors (E= content in fraction/content in whole soil) revealed differences in the distribution of C species across the size separates. Relatively high E_aromatic (0.9) and E_o-alkyl (1.0) for sand from Gp indicated high amounts of plant residues, probably due to intense rhizodeposition and to occlusion of plant debris within aggregates. Low E_aromatic (0.3) and E_o-alkyl (0.3) for sand from Ar suggested depletion of primary resources, which could be attributed to disintegration of soil aggregates upon cultivation. A pronounced enrichment of alkyl C in Ar clay-sized separates (E_alkyl= 3.1) suggested large amounts of microbial carbon. Microbial products attached to clay surfaces by a variety of physico-chemical bondings appeared more stable against mineralization induced by cultivation than plant residues sequestered in aggregates.     

Spectroscopic (IR,NMR) characterization of water-soluble organic substances extracted from straw,straw incubated with Pleurotus ostreatus,and straw compost

Water extracts from fresh wheat and barley straw, straw incubated with Pleurotus ostreatus, and straw compost were studied by IR, ¹H NMR, and ¹³C NMR spectroscopy. During incubation lignin was degraded, water extractability increased, and water extracts were rich in polysaccharides. After composting solubility decreased and the water extracts were rich in aromatic, methoxyl, and carboxyl C, but poor in O-alkyl C indicating that during composting mainly polysaccharides had been mineralized. GPC revealed that water extracts from straw compost contained polysaccharides, peptides, C- and O-substituted aromatics, and alkyl compounds.     

Soil Biology Changes as a Consequence of Organic Amendments Subjected to a Severe Drought

Effect of severe drought events in combination with organic amendments (municipal solid waste, MSW, sheep manure, SM, and cow manure, CM) on soil dehydrogenase, urease, β‐glucosidase and phosphatase activities and microbial community by analyzing phospholipid fatty acids was studied under controlled laboratory conditions for one year. Two levels of irrigation were used: (1) watered soils, where the soils were maintained at 60% of their water holding capacity through the experiment, and (2) non‐watered soils, without irrigation through the experiment. The severe drought conditions negatively affected the soil enzymatic activities and total bacterial and fungal PLFA concentrations. The application of organic amendments to the soil subjected to severe drought increased soil water retention and encouraged the growth and activity of soil microbial populations. However, the chemical composition of the organic matter applied to the soil also strongly influenced soil moisture. In non‐watered soils and compared with the unamended soil, the dehydrogenase activity was 71 · 3%, 60 · 9% and 38 · 6% higher in the soil with SM, CM and MSW, respectively. Urease activity was 60 · 6%, 51 · 5% and 37% higher in the soil with SM, CM and MSW, respectively. β‐glucosidase and phosphatase activities had a similar trend. Water retention was higher when the organic wastes applied to the soils had a higher content of humic acids than fulvic acid contents. Copyright © 2016 John Wiley & Sons, Ltd.     

Temperature and Chemical Changes During Composting of Broiler Litter

Composting broiler litter (a mixture of manure, bedding material, and wasted feed) with commonly available high-C substrates may be a viable alternative to reduce current land disposal practices for litter. Broiler litter with wood shavings as a bedding material and broiler litter with peanut hulls as a bedding material were composted with wheat straw, peanut hulls, pine bark and paper mill sludge in 0.33 m³ batch reactors. Litters and C substrates were mixed to achieve C:N ratios of approximately 30:1. Dry weight, total N, total C, temperature, electrical conductivity and pH were determined at regular intervals. Maximum temperatures peaked near 70°C within 2.25 d after mixing peanut hulls with litter and within 2.58 d for pine bark and litter. Composts made from paper mill sludge approached 50°C within 3.71 d. Wheat straw composts never exceeded 40°C which could present potential health problems associated with pathogenic microorganisms. Mass loss and C:N ratio gradually declined and stabilized approximately 84 d after mixing. Mass loss averaged 73 percent for wheat straw compost, 33 percent for peanut hull composts, and 16 percent for the other mixes. Wheat straw compost C:N ratios stabilized near 14:1 and other mixes remained above 20:1, indicating N limited conditions for complete composting. Compost pH was 5.8 after 84 d from pine bark composted with wood shaving litter and was significantly lower than pH from paper mill sludge compost with an average pH of 6.9 but similar to all other compost mixes (pH 6.7). Electrical conductivity ranged from 0.35 S m^?1 for paper mill sludge composted with wood shaving litter to 0.91 S m^?1 from wheat straw composted with peanut hull litter. Composting temperature varied considerably among C sources and all required at least 72 d of curing to stabilize the C:N ratio. Composts made from wheat straw were most effective for waste reduction but temperatures were below the 50°C level generally considered necessary to kill pathogens.     

长期施肥对红壤性水稻土颗粒有机质和矿物结合态有机质含量与化学组成的影响

以江西红壤地区双季稻田肥料定位试验为依托,研究了不施肥(CK)、单施化肥(NPK)及3种不同比例有机无机肥配施(LM、MM、HM)对红壤性水稻土全土、颗粒有机质(POM)和矿物结合态有机质(MinOM)组分碳、氮含量及其化学结构的影响。结果表明:施肥处理全土、POM和MinOM组分中有机碳、全氮含量均显著高于CK处理(P<0.05);与CK处理相比,施肥提高了POM组分质量分布,其中中、高量有机肥配施(MM、HM)分别显著提高POM组分质量分数15.7%和25.1%;施肥处理POM有机碳对土壤有机碳贡献率显著增加13.4%~42.6%;施肥处理未显著影响全土和MinOM组分碳氮比,但显著降低了POM组分碳氮比,降低量为16.8%~25.0%。与NPK处理相比,有机无机配施处理显著提高POM-C/MinOM-C值27.7%~70.2%,提高了土壤有机质活性。红外光谱分析显示,施肥处理较CK处理分别提高全土烷基碳和芳香碳相对含量5.4%~33.2%和0~12.2%;而施肥处理提高了POM烷基碳含量并降低了其芳香碳含量,但几乎不影响POM羧基碳含量,其中MM、HM处理POM烷基碳含量分别较CK处理显著提高12.4%和40.6%;除NPK处理降低了MinOM烷基碳含量外,施肥均提高了MinOM烷基碳和羧基碳含量并降低了其芳香碳含量,其中NPK处理较CK处理显著提高MinOM羧基碳含量70.8%。研究结果说明施肥能提高供试土壤全土及各土壤组分有机碳、全氮含量,与单施化肥相比,有机无机配施更有利于提高土壤POM数量及其结构活性,改善稻田土壤质量。