INTEGRATED CROP-LIVESTOCK SYSTEMS: LESSONS FROM NEW YORK,BRITISH COLUMBIA,AND THE SOUTH-EASTERN UNITED STATES

• Livestock production in North America has moved to fewer farms with greater inventories • Land application of livestock manures is a preferred nutrient recycling strategy • Confined animal feeding operations have challenges to utilize livestock manure sustainably • Integration of livestock and cropping systems is possible on a farm or among farms • Nutrient balance is needed for environmental sustainability Livestock production in the United States (US) and Canada is diverse, but shows a common trend in most livestock sectors toward fewer farms producing the majority of animal products despite a large number of farms still small in production scale. The migration to larger and more concentrated animal feeding operations in beef finishing and poultry, swine, and dairy production allows processors to streamline supplies to meet market demand for abundant, low-cost livestock products, whether that be for packaged meat, dairy products, or eggs. With concentration of livestock operations comes the challenge of managing manures. When sufficient land is available and nutrients are needed, livestock manure is an excellent nutrient source and land application is the preferred method of recycling this resource. However, when livestock production is constrained in a geographical area and animal densities are high, manure may become an environmental liability with potentially greater risk for runoff and leaching of nutrients, emission of odors, ammonia, and greenhouse gases, and release to the environment of pathogens and chemicals of emerging concern. Addressing these challenges now and into the future requires learning from mistakes and adopting successful approaches. We describe different levels of integration between livestock and crop producers in New York, British Columbia, and the south-eastern US as learning opportunities to improve economic and environmental sustainability. Examples show that effective solutions should recognize (1) manure has value and is not just a cost, (2) farmers, farm advisors, extension educators, nutrient management planners, crop advisors, nutritionists, state agency personnel, regulators, and university researchers need to be active participants in development of solutions, and (3) change to a sustainable future requires a combination of government regulation and outcome-based incentives.     

Rainbow trout (Oncorhynchus mykiss,Walbaum ) develop a more robust body shape under organic rearing

Prolonged exposure to captive conditions has led to the development of a rainbow trout ‘farmed’ phenotype, which is different from that of wild trout. Selection for desirable productive traits in hatcheries has resulted in the development of some morphological traits that are maladaptive in nature. The recent development of organic aquaculture, guided by the well‐being of the fish, could potentially produce a new farmed phenotype that would be more adaptive in nature. In this study, rainbow trout reared in intensive and organic farms were compared by means of shape analysis, to detect patterns of shape variation associated with rearing environment. The results of this study highlight a significant effect of the rearing method on rainbow trout shape: organically reared trout showed a higher body profile, in particular in the head and trunk regions, shorter median fins and a deeper caudal peduncle. A combined effect of density and habitat complexity could have contributed to the observed shape differences: in organic rearing systems, lower densities and steady water could increase territoriality and aggressive interactions, promoting body designs more functional in rapid attacks and escapes.     

Supplementation effect(s) of organic acids and/or lipid to plant protein‐based diets on juvenile yellowtail,Seriola quinqueradiata Temminck et Schlegel 1845, growth and,nitrogen and phosphorus excretion

A feeding experiment was conducted to investigate the effect of organic acids and/or lipid supplementation on growth, utilization and environmental loading of nitrogen (N) and phosphorus (P) in juvenile yellowtail fed fishmeal (FM) and plant protein (PP) diets. Six diets as FM (FM‐based), FM+P (FM with inorganic P), FM+L (FM with lipid), PP+CA (PP with citric acid), PP+L+CA (PP with lipid and citric acid) and PP+L+FA (PP with formic acid) were formulated. Yellowtails were fed each of the diets in duplicate groups; once a day, 6 days a week to near satiation at water temperature 19.0–25.0 °C for 16 weeks. Fishmeal with inorganic P gave the best growth while PP+L+FA the lowest. However, growth increased in PP+CA and PP+L+CA. Addition of lipid significantly increased N and P retention resulting in significant reduction in N and P excretion. Citric acid and FA supplementation to PP diets also increased retention of P; hence, its excretion was lowered. Thus, CA, FA and lipid in juvenile yellowtail diets can help to partially replace FM with PP sources and reduce inorganic P use to minimize environmental loading from aquafeeds.     

鸡粪高效降解微生物菌剂富集培养新法

以新鲜鸡粪为主要培养基,自然腐熟鸡粪(处理1),菌剂腐熟鸡粪和土壤(处理2),菌剂腐熟鸡粪(处理3)为富集样品连续5批堆肥驯化培养,使微生物菌群经历不同的生长环境,达到优胜劣汰的效果。处理1在5批富集培养中较处理2和处理3有较好的堆肥效果,说明其中有降解性能好的优势菌群,将其筛选出扩大培养,再回接到新鲜鸡粪中,将会快速、有效地降解新鲜鸡粪,达到良好的堆肥效果。     

我国畜禽粪便处理利用现状及展望

随着农业结构调整和农业产业化的推进,以及规模化、集约化畜禽养殖业的迅猛发展,其规模由小到大,范围由点到面,但由于畜禽养殖业管理薄弱和农业与养殖业脱节,致使大量畜禽粪便与污染物随意排放和流失,破坏了生态环境.为此,介绍了畜禽粪便的处理方法和资源化技术,并根据我国现状提出了畜禽粪便处理利用的发展方向.     

蔬菜农药残留快速检测中易出现的问题与对策

介绍蔬菜中有机磷和氨基甲酸酯类农药残留快速检测方法的原理,指出实际检测过程巾易出现的问题,并针对这些问题提出相应的解决措施,总结出检测操作中的几点注意事项,以减小误差、避免失误,提高检测结果的可信度。     

环保视阈下恩施州肥料利用问题及对策

指出了提高肥料利用率,减少肥料损失和对农业环境的污染是目前农业生产中急需解决的重要问题,针对恩施州有机肥用量不足、肥料投入结构不合理、肥料流失量较大、农业环境污染加重和边际效益下降等问题,提出了有机肥资源高效利用、采用新型科学施肥技术和减少环境污染的施肥技术等提高肥料利用率的建议。     

长期绿肥还田对江南稻田系统生产力及抗逆性的影响

 依据江南丘陵地区双季稻田28年（1981-2008年）长期绿肥还田的田间定位试验和4年的养分耗竭盆栽试验,分析比较了长期不同量绿肥还田对稻田系统生产力和抗逆性的综合影响。结果表明,常量绿肥还田和高量绿肥还田处理下,早稻、晚稻和历年的全年平均籽粒产量和生物学产量及其变异系数与长期单施化肥处理差异不显著,但由于绿肥还田处理施用绿肥替代部分化肥,平均每年的化肥N、P和K投入量比单施化肥处理分别减少90.0、9.9和72.0 kg/hm2。绿肥处理的双季稻全年产量呈上升趋势,而长期化肥处理则呈下降趋势,且前者的全年产量可持续性产量指数均略高于后者,常量绿肥还田下稻田系统的耐瘠能力也显著高于长期单施化肥处理。不同量绿肥还田下稻田系统生产力差异不显著,但耐瘠能力常量还田处理较高。     

茶园绿肥品种的筛选

对绿肥1号和四种不同的绿肥品种分别进行植株N、P、K养分含量和产青量分析评价。结果表明,绿肥1号是一种含N量高,产青量高的绿肥品种。     

SUSTAINABLE NUTRIENT MANAGEMENT PACKAGE FOR COST-EFFECTIVE BIOENERGY BIOMASS PRODUCTION

Commercial fertilizer (particularly nitrogen) costs account for a substantial portion of the total production costs of cellulosic biomass and can be a major obstacle to biofuel production. In a series of greenhouse studies, we evaluated the feasibility of co-applying Gibberellins (GA) and reduced nitrogen (N) rates to produce a bioenergy crop less expensively. In a preliminary study, we determined the minimum combined application rates of GA and N required for efficient biomass (sweet sorghum, Sorghum bicolor) production. Co-application of 75 kg ha^?1 (one-half of the recommended N rate for sorghum) and a modest GA rate of 3 g ha^?1 optimized dry matter yield (DMY) and N and phosphorus (P) uptake efficiencies, resulting in a reduction of N and P leaching. Organic nutrient sources such as manures and biosolids can be substituted for commercial N fertilizers (and incidentally supply P) to further reduce the cost of nutrient supply for biomass production. Based on the results of the preliminary study, we conducted a second greenhouse study using sweet sorghum as a test bioenergy crop. We co-applied organic sources of N (manure and biosolids) at 75 and 150 kg PAN ha^?1 (representing 50 and 100% N rate respectively) with 3 g GA ha^?1. In each batch of experiment, the crop was grown for 8 wk on Immokalee fine sand of minimal native fertility. After harvest, sufficient water was applied to soil in each pot to yield ～1.5 L (～0.75 pore volume) of leachate, and analyzed for total N and soluble reactive P (SRP). The reduced (50%) N application rate, together with GA, optimized biomass production. Application of GA at 3 g ha^?1, and the organic sources of N at 50% of the recommended N rate, decreased nutrient cost of producing the bioenergy biomass by ～$375 ha^?1 (>90% of total nutrient cost), and could reduce offsite N and P losses from vulnerable soils.