南洋楹无性系抗寒性研究

【目的】南洋楹属典型热带树种,抗寒性较差,严重制约其推广应用。开展南洋楹无性系抗寒性评价,对于提高其造林成效、拓广其栽培区域具有重要意义。【方法】以生长较好的9个南洋楹无性系组培苗为研究对象,通过系列低温处理,观测幼苗叶片形态变化,分析测定叶片相对电导率(REC)、脯氨酸(PRO)含量以及超氧化物歧化酶(SOD)的活性,揭示南洋楹无性系在低温胁迫下的生理响应,并进行无性系抗寒性评价。【结果】在2℃时,所有无性系均出现不同程度落叶;0℃时所有无性系均出现顶芽死亡,其抗寒性差异主要表现在0~2℃温度区间;9个无性系的REC随温度降低呈单调上升和先上升后下降再上升的2种变化趁势,属于后者的无性系抗寒性更强,0℃下S5、S7的REC最低;PRO含量随温度降低整体上呈现递增趁势,TL18、S7、S5、A8的PRO含量增幅最大,均在1倍以上;SOD活性在同一温度下无性系之间差异显著,但随温度降低无明显变化规律。应用REC进行聚类分析,将9个无性系分为3类,S7、S5、TL18抗寒性最强,A8抗寒性最差,其它6个无性系抗寒性居中。【结论】建议生产上推广S7、S5和TL18无性系。     

挥发性抑芽物质对马铃薯块茎萌芽的影响及其作用机制

马铃薯块茎过早萌芽会降低商品价值,本试验比较挥发性物质的抑芽效应,并从转录和蛋白水平分析其作用机制。结果表明,抑芽能力薄荷醇(29)樟脑(29)萘,萌芽受抑降低代谢消耗,薄荷醇处理180 d时的重量损失只有对照损失的36%。樟脑处理萌芽块茎3 d引起表达显著上调(或下调)的基因和蛋白分别有1227 (299)和296 (204)个,主要参与响应刺激、防御反应。贮藏期间,果胶代谢基因PEL、PME、PG,角质合成基因CYP77A6、HPFT、WES,乙烯合成基因ACO以及转录因子编码基因GATA4L的表达量随时间升高。樟脑早期不同程度地刺激这些基因表达,中后期则抑制,49d时只有对照的0.68%～23.35%。薄荷醇使上述基因表达保持低水平,但可提高细胞周期负控基因KRP4的表达,为对照的15.9倍。植物病原菌互作通路中的基因WRKY75、STH-2、RBOH表达受樟脑诱导并在后期高表达。樟脑和薄荷醇均能抑制生长发育基因的表达,造成芽死亡,降低贮藏损耗。前者早期能促进合成保护性物质,萌芽时有更强烈的抗菌反应;后者则阻碍细胞分裂。     

Ridge-furrow plastic mulching with a suitable planting density enhances rainwater productivity,grain yield and economic benefit of rainfed maize

Soil surface mulching and planting density regulation are widely used for effective utilization of limited rainwater resources and improvement of crop productivity in dryland farming.However,the combined effects of mulching type and planting density on maize growth and yield have been seldom studied,especially in different hydrological years.A field experiment was conducted to evaluate the effects of mulching type and planting density on the soil temperature,growth,grain yield(GY),water use efficiency(WUE)and economic benefit of rainfed maize in the drylands of northern China during 2015-2017.Precipitation fluctuated over the three years.There were four mulching types(NM,flat cultivation with non-mulching;SM,flat cultivation with straw mulching;RP,plastic-mulched ridge plus bare furrow;RPFS,plastic-mulched ridge plus straw-mulched furrow)and three planting densities(LD,low planting density,45.0×10^3 plants/hm^2;MD,medium planting density,67.5×10^3 plants/hm^2;HD,high planting density,90.0×10^3 plants/hm^2).Results showed that soil temperature was higher with RP and lower with SM compared with NM,but no significant difference was found between RPFS and NM.More soil water was retained by soil mulching at the early growth stage,but it significantly varied at the middle and late growth stages.Maize growth was significantly improved by soil mulching.With increasing planting density,stem diameter,net photosynthetic rate and chlorophyll content tended to decline,whereas a single-peak trend in biomass yield was observed.Mulching type and planting density did not have significant effect on evapotranspiration(ET),but GY and WUE were significantly affected.There were significant interacting effects of mulching type and planting density on biomass yield,GY,ET and WUE.Compared with NM,RPFS,RP and SM increased GY by 57.5%,50.8%and 18.9%,and increased WUE by 66.6%,54.3%and 18.1%,respectively.At MD,GY increased by 41.4%and 25.2%,and WUE increased by 38.6%and 22.4%compared with those of at LD and HD.The highest maize GY(7023.2 kg/hm^2)was observed under MD+RPFS,but the value(6699.1 kg/hm^2)was insignificant under MD+RP.Similar trends were observed for WUE under MD+RP and MD+RPFS,but no significant difference was observed between these two combinations.In terms of economic benefit,net income under MD+RP was the highest with a 9.8%increase compared with that of under MD+RPFS.Therefore,we concluded that RP cultivation pattern with a suitable planting density(67.5×10^3 plants/hm^2)is promising for rainwater resources utilization and maize production in the drylands of northern China.     

金花茶对低温胁迫的生理响应及耐寒性分析

为探究金花茶幼苗对低温胁迫的生理响应及其耐寒性,本研究以2 a生金花茶幼苗为材料,进行6~-9℃低温胁迫处理,测定了细胞伤害率(CIR)、丙二醛(MDA)、过氧化物酶(POD)、过氧化氢酶(CAT)、超氧化物歧化酶(SOD)、束缚水(BW)/自由水(FW)、脯氨酸(Pro)、可溶性糖(SS)等指标,并进行了低温半致死温度(LT₅₀)和抗寒生理指标相关性分析。结果表明,3~12 h的低温LT₅₀为-6.62~-3.94℃,且随着时间的延长而升高。随着温度的降低, CIR、SS含量及POD、CAT活性总体呈上升趋势, BW/FW、MDA、Pro含量呈先上升后下降趋势, SOD活性总体呈下降趋势;随着胁迫时间的延长,CIR含量呈上升趋势,3~-9℃的SOD活性、0~-9℃的POD活性、-6~-9℃的BW/FW比值呈下降趋势,6~-6℃的SS含量变化较小,-9℃的SS含量呈下降趋势。相关性分析表明,CIR可作为耐寒性鉴定的主要指标,BW、SS、SOD、POD、CAT可作为辅助指标。本研究结果为金花茶引种区域和耐寒性鉴定指标的确定提供了理论依据。     

常温真空包装对保持小米储藏品质的影响

为了探究一种有效的小米储藏方法,以晋谷42号小米为试材,采用0.08 mm厚尼龙(polyamide,PA)复合聚乙烯(polyethylene,PE)袋包装,常温((20±2)℃)环境中储藏,研究小米在常规、常规密闭和真空包装储藏120 d品质指标的变化规律。结果表明:相对于常规包装,真空包装储藏有效降低脂肪氧合酶的活性(P<0.05),延缓小米脂质的氧化分解(P<0.05),抑制小米游离脂肪酸含量的升高(P<0.05),较好地保持了小米的水分(P<0.05),延缓了小米黄色素的损耗(P<0.05),较好地保持了小米的亮度(P<0.05)、米黄色(P<0.05)以及弹性(P<0.05)和黏附性(P<0.05);常规密闭包装具有一定的储藏效果,但不及真空包装。因此,常温下真空包装储藏可以有效延缓小米的陈化,保持小米的储藏品质。研究结果为小米储藏,提升小米储藏品质提供了理论依据和技术支持。     

不同激励下宽频磁浮俘能器俘能试验

振动能量俘获是获取可再生的清洁能源一种有效途径，具有广阔的应用前景，有利于社会的可持续性发展。目前，随机功率谱激励下的高功率密度和宽频能量回收仍然是研究的难点。该研究设计了一种可有效利用宽频振动能量的高功率密度磁浮式俘能器，采用COMSOL Multiphysics软件计算悬浮磁体非线性回复力与位移的关系式，根据磁浮振动系统的控制方程和基尔霍夫定律建立俘能器的数学模型，详细研究了模型参数变化对俘能器性能的影响。随后进行正弦扫频和驻频试验以验证俘能器的发电能力。同时，从俘能器的效率、效能和体积优质3个指标对俘能性能进行评价；并结合实际应用，设计俘能器稳压电路。根据丘陵山区农业机械工作的随机路谱特性，建立随机激励的数学模型，根据响应幅值的概率密度函数的FPK方程表达式，得到了平稳概率密度函数的解。结果表明：在激励频率从9.77到31.75 Hz变化时，俘能器最大输出电压在5.92和21.52 V之间；最大输出功率在10 Hz时达81.93 mW，从5到50Hz，输出功率范围为5.76到81.93 mW；俘能器的效率、效能和体积优质分别为2.85%，9.85%和39.74%；俘能器电压输出的功率谱密度有5个峰值点，对应频率分别为9.804、29.41、36.76、36.76、51.47和71.08 Hz，进一步验证了该研究提出的磁浮式俘能器具有宽频发电性能，并可满足丘陵山区农机设备监测传感器的供电需求。     

规模化奶牛场粪污全量贮存及肥料化还田工艺设计

为推进粪污全量贮存和肥料化还田模式在规模化奶牛场的应用，该研究以存栏500头规模奶牛场为例，分析了粪污收集量、贮存工艺与设施和粪肥还田等内容，提出了粪污贮存池设计容积和粪肥还田配套土地面积等参数。结果表明：奶牛粪污全量收集量为17.33 t/d，全量贮存设施分为舍内贮存池和舍外贮存囊2种。单个舍内贮存池尺寸为85 m×12 m×2 m（长×宽×深），粪污存储期9个月，所需贮存池数量为5个，总容积10 200 m3；舍外贮存囊占地尺寸为90 m×30 m（长×宽），深2.2 m，总容积5 615 m3。粪肥全部还田所需土地面积与种植作物类型和种植制度相关，种植作物为小麦、玉米、小麦+玉米和水稻（1年2熟）时，需配套土地分别为248.4、400.6、122.8和127.0 hm2。粪肥还田成本为10.37万元/a，全部还田可节省化肥22.8万元/a，年可产生经济效益12.43万元。     

Soil carbon increases with long-term cattle stocking in northern temperate grasslands

Grassland management aimed at enhancing carbon (C) in soil is an important tool in mitigation of rising atmospheric CO₂, yet little is known of how grassland soil C changes with livestock stocking rate (SR). We relate soil organic and inorganic C mass (t ha⁻¹ to 60 cm depth) with cattle stocking over periods of 7–27 year for 32 paddocks distributed across nine community pastures in the mixed-grass prairie of Saskatchewan, Canada. Initial analysis comparing Akaike information criterion models showed that cattle SR explained a greater proportion of variance in soil C, particularly soil organic C, than rainfall. Soil organic C mass increased with cattle SR (R² = .293; p = .001), even when the latter was normalized to account for differences in vegetation composition and growing conditions among pastures. Normalized SR varied from 0.49 to 2.30 times recommended levels, over which SOC increased from 24.7 to 57.4 t ha⁻¹. Increases in soil organic C under greater stocking coincided with increased abundance of introduced vegetation, particularly the rhizomatous grass Poa pratensis. Inorganic soil C accounted for 34.6% of total soil C, being particularly large below 30 cm soil depth, but did not vary with stocking rate. These findings indicate that both organic and inorganic C are important pools of C in northern temperate grassland soils, with soil organic C positively associated with long-term cattle SR. Further studies are recommended to understand more fully the mechanisms regulating grazing impacts on soil C mass in northern temperate grasslands.     

Biochar addition mitigates nitrogen loss induced by straw incorporation and nitrogen fertilizer application

Biochar has been shown to be potentially beneficial for enhancing yields and soil properties, and diminishing nitrogen (N) losses. However, it remains unclear how biochar regulates soil carbon (C) and N to mitigate N losses induced by straw mixing with N fertilizer in dryland soils. Therefore, we investigated the effects of straw mixing (S₁), S₁ with biochar (SB) and no straw inputs (S₀), and routine urea application rates (N₁) and 70% of routine rates (N_0.7) on yields and N losses, and identify the relationship between N losses and soil C and N compounds. Results showed that N_0.7 and N₁ were suitable for the maize and wheat seasons, respectively, contributing to mitigating N losses without reducing crop yields. Moreover, in the maize season, N_0.7-SB significantly mitigated the straw-induced NH₃-N and N₂O-N emissions by 106% and 81%, respectively. In the wheat season, N₁-SB reduced the straw-induced NH₃-N and N₂O-N emissions by 35% and 66%, respectively. In addition, N_0.7-SB sharply reduced soil inorganic N (SIN) storage in the maize season. Furthermore, the NH₃-N and N₂O-N emission rates were negatively correlated with dissolved organic carbon/SIN content (0–20 cm) (DOC/SIN_0-20). N losses (N₂O-N and NH₃-N emissions and SIN storage) were positively correlated with SIN_0-20, but negatively correlated with soil organic carbon / SIN_0-20 (SOC/ SIN_0-20). This study provides further evidence that biochar with an appropriate N application rate decreased SIN_0-20 and increased DOC/SIN_0-20, thus reducing SIN storage and the straw-induced gaseous N emissions without decreasing crop yields.