文心兰矿质营养特性的初步研究

为了探明文心兰的矿质营养特性,以文心兰(Oncidium Gower Ramsey‘Gold 3’)为试材,通过2009～2011年定期对各生育阶段兰株进行跟踪取样调查,初步研究了植株不同器官干物质积累及其对矿质元素吸收、分配特性。结果表明,兰株总干物质量为苗期2.42 g/株,初花期15.04 g/株,盛花期50.57 g/株,叶片所占比例最大。其中,兰株对钾的需求量较大,各时期叶片K的分配率最高,N、Ca主要分配在叶片,P、Mg和S主要分配在叶片与假鳞茎。苗期N、P、K比例为:1∶0.41∶1.57,初花期N、P、K比例为:1∶0.27∶1.45,盛花期N、P、K比例为:1∶0.31∶1.62。生产一枝花平均需要干物质4.18 g,养分N 89.76、P 10.91、K 70.44、Ca 8.33、Mg 7.43、S 7.31 mg。     

配方施肥对设施‘87-1’葡萄植株矿质元素含量及果实品质的影响

为制定基于品质指数的最佳理论施肥方案及营养诊断标准,研究了不同施肥配比和植株矿质元素变化动态与品质形成的关系。以设施‘87-1’葡萄为试材,连续多年进行5416配方施肥试验,测定植株矿质元素含量及果实品质,并对其进行Topsis综合评价,计算品质指数。研究矿质元素含量与品质指数的相关性,确定营养诊断因子。应用非完全正交方差分析法和组分营养诊断法分别制定最佳综合品质的施肥方案及营养诊断标准。研究结果表明,单粒重在各处理条件下的分布范围是4.3～5.0 g。T10处理的可溶性固形物含量最高,为18.5%。T3处理的果实硬度最高,为471.9 g。T3处理的品质指数最高,为0.6071;除T6、T8、T14、T16处理外,其他处理品质指数均高于T1处理,增幅为1.8%～33.4%。成熟期果实N、成熟期叶柄P、成熟期叶柄K、成熟期叶片Ca、转色期叶柄Mg被选作为营养诊断因子。高优园矿质元素含量适宜范围为N 1.0～2.4 mg/g、P 1.0～3.0 mg/g、K 4.0～10.4 mg/g、Ca 2.9~9.6 mg/g、Mg 0.6～9.7 mg/g,低优园的需肥顺序为K>Ca>N>Mg>P,其中K和Ca元素含量表现偏低,其他元素含量充足。当单粒重、可溶性固形物、硬度和品质指数达到最佳时,每公顷的建议施肥总量分别为736.5、1332.0、788.3和1430.3 kg。在本试验条件下,品质指数达到最佳时的元素N∶P∶K∶Ca∶Mg理论配比为3∶3∶4∶3∶2,其N、P2O5、K2O、CaO、MgO施肥量分别为375.0、141.0、506.3、337.5、70.5 kg/hm²。     

不同施肥方式烤烟叶片矿质元素含量变化及其与干物质积累的关系

为了研究不同施肥方式下烤烟叶片中N、P、K、Ca、Mg、B、Cu、Fe、Mn、Zn 10种矿质元素的含量变化及其与干物质积累间的相关性,于2015~2016年连续2年以南阳市烤烟品种云烟87为试材,设置3种不同的施肥方式(T1:沟灌常规施肥,T2:水肥一体化,T3:水肥一体化+黄腐酸钾)在田间进行对比试验。结果显示,烟叶中10种矿质元素含量高低表现为NCaKPMgMnFeZnBCu;水肥一体化处理矿质元素含量显著高于常规处理。不同施肥方式下叶片内矿质元素含量的变化趋势表现为N、Ca、Mn、Zn,呈先上升后下降的趋势,60~80 d达到峰值;K、Cu、Fe含量在生育期内呈逐渐下降趋势,Mg元素含量表现为先下降后上升;B、P含量在生育期内变化差异不明显;叶片内N、P、K含量之间均呈极显著正相关,表明这3种元素彼此间存在增效作用;Fe与N、Ca、Mg、Mn 4种元素含量变化呈极显著负相关,表明Fe与这4种元素间均存在拮抗作用。元素含量与干物质积累间的相关性分析表明,N、P、K在40~70 d内均与干物质积累呈显著正相关。因此与常规处理相比,水肥一体化能提高烟株对矿质元素的吸收和积累,促进后期落黄成熟,提高干物质积累量。     

补光时间及光质对温室甜椒矿质元素吸收与分配的影响

为探究发光二极管(LED)补光对温室甜椒矿质元素吸收及分配的影响,以甜椒品种奥黛丽为试材,设置红光(R)和蓝光(B)组合2∶1(2R1B)、4∶1(4R1B)、8∶1(8R1B) 3种光质,2 h(18:00-20:00)、4 h(18:00-22:00)和8 h(18:00-02:00) 3个补光时间,以不补光为对照(CK),研究补光时间及光质对甜椒N、P、K、Ca、Mg、Mn、Zn积累及分配的影响。结果表明,光质与补光时间显著影响矿质元素在甜椒中的积累与分配,且二者存在显著的交互作用。与CK相比,LED补光显著促进了甜椒全株中N、P、K、Ca、Mg和Mn的积累,光质对N、P、K、Mg、Mn积累总量的影响无显著差异,但补光时间会显著影响矿质元素的积累,以补光8 h的元素积累量最高,其N、P、K、Ca、Mg和Mn的单株积累量分别较CK增加51.82%、55.56%、47.55%、50.00%、56.76%和36.23%,补光4 h的N、Ca、Mn积累总量与补光8 h无显著差异。从分配比例来看,与CK相比,补光2 h降低了N、P、Mg、Mn在果实中的分配比,补光4 h提高了N、P、K、M...     

烤烟矿质营养分布的因子分析

为了研究烤烟的B营养及B K交互作用 ,进行了烤烟生长期间不同施K、施B肥的盆栽试验。在两个生育期测定根、叶不同部位 1 0种矿质营养元素含量 ,并对试验结果作了因子分析和方差分析。分析结果表明 ,一个四因子模型解释了试验数据总方差的 92.1% ,10种矿质元素划分为有确切意义的公因子微量元素营养因子、常量元素营养因子、磷因子和硼因子。矿质营养分布方式主要受植株部位、施K量及两者交互效应的显著影响。根部有较高的微量元素浓度分布 ,叶部有较高的常量元素浓度分布。多施K肥可适当提高烟叶含K量 ,也可抑制叶片中的Ca、Mg、S含量 ,减小P营养。K充足时 ,多施B肥有可能增加根部微量元素营养。高B、高K会影响植株对P、B的吸收。     

设施基质条件下不同茬口樱桃番茄的养分吸收及分配规律研究

以樱桃番茄为供试材料,通过设施基质栽培试验,研究了不同茬口樱桃番茄的养分吸收规律和分配特点,旨在为樱桃番茄的科学施肥提供依据。结果表明:形成1000 kg果实樱桃番茄植株的N、P、K、Ca、Mg吸收量分别是4.31～4.79 kg、0.68～0.78 kg、5.60～6.43 kg、0.68～0.99 kg、0.31～0.48 kg,两茬樱桃番茄养分吸收比例N∶P∶K∶Ca∶Mg分别是1∶0.16∶1.30∶0.23∶0.11和1∶0.16∶1.34∶0.14∶0.06,在结果期,有40%～50%的N、P、K分配在果实中,而钙和镁在果实中的分配比例只有10%左右。Fe、Mn、B、Zn、Cu的吸收量分别是14～18 mg株-1、10～14 mg株-1、6.3～7.5 mg株-1、5.3～6.6 mg株-1、0.6～0.7 mg株-1。樱桃番茄的干物质累积以及养分吸收量从开花期以后迅速增加,N、P、K在开花期的累积量占整个生育期的比例是7.6%～14.4%,Ca、Mg在开花期的累积量能达到20%左右,所以在开花期要注重钙镁的补充。盛果期各养分的累积量占比最大,是养分大量吸收累积的关键时期,这一时期需要提供充足的营养保证果实的建成。     

镁、钾相互作用对水稻生长、养分吸收及有关生理特性的影响

在温室条件下,采用液体培养方法研究了Mg、K相互作用对水稻生长、养分吸收以及有关生理特性的影响。结果表明,在低Mg浓度条件下,水稻植株干物质积累随K浓度增加而减少;在高Mg条件下水稻植株干物质积累随K浓度增加而相应增加。在低Mg条件下,高浓度K显著抑制植株对Mg、K、N和P的吸收;在高Mg浓度下,植株对Mg、K、N和P的吸收有促进作用。植株叶片叶绿素含量在低Mg条件下随K浓度增加而减少,在高Mg条件下K浓度增加对叶绿素含量无显著影响。叶片硝酸还原酶活性和可溶性蛋白质含量随Mg浓度增加而增加,而K浓度增加对叶片硝酸还原酶活性和可溶性蛋白质含量无明显影响。高Mg条件下的叶片可溶性糖和淀粉含量明显高于低Mg处理,并随K浓度增加而提高。Mg、K营养拈抗作用主要表现在低Mg高K浓度条件下抑制Mg的吸收。     

冬枣果实发育期结果枝叶与营养枝叶矿质元素动态变化的比较

对比研究冬枣果实发育期内结果枝叶和营养枝叶片矿质元素动态变化的差异性,可为制定冬枣不同类型叶片的营养诊断标准提供理论依据。以沾化冬枣为试验材料,比较研究了沾化冬枣不同果实发育阶段（始花期、盛花期、末花期、硬核期、完熟期）结果枝叶和营养枝叶中矿质元素N、P、K、Ca、Mg、Na的含量动态变化及其差异性。结果表明,冬枣果实发育过程中,自始花期至完熟期叶片N、P含量呈下降趋势,K含量呈逐渐增高趋势,而Ca及Mg含量则呈先增高后降低的变化趋势,叶片Na含量在果实发育过程中变化较小,只有在完熟期呈现突然增高现象。在上述各生长发育阶段内,结果枝叶K含量多大于营养枝叶,而N、P、Ca、Mg、Na含量则呈相反的变化规律。方差分析表明,在盛花期至末花期内,两种类型叶片Ca、Mg含量的差异均达到显著水平（P<0.05）,N含量只有在盛花期存在显著差异,而两种类型叶片K和Na含量在各果实发育阶段内均无显著差异。叶片元素含量比值分析表明,冬枣叶片N/P在盛花期至完熟期逐渐增高,其值均大于16,可知该阶段冬枣叶片生长主要受P元素限制;K/Na、Ca/Na、Mg/Na在果实发育期内的变化规律与K、Ca、Mg元素变化规律基本类似,在完熟期这3个比值均较前期明显降低。相关分析结果表明,冬枣叶片中N/P主要由P含量决定,Ca/Na、Mg/Na分别由Ca与Na、Mg与Na共同决定,而在营养枝叶中K/Na主要由Na含量决定。综上,盛花期至末花期（6—7月）是冬枣矿质元素相对稳定时期,可作为冬枣结果枝叶和营养枝叶营养诊断的适宜时期,同时冬枣结果枝叶该时期可适当施加适量Ca、Mg肥料,从而保证冬枣的果实品质和产量。     

京北山区板栗林主要养分元素积累与分配的研究

对北京北部山区板栗林主要养分元素积累与分配的研究结果表明:22年生板栗林的生物量为38638kg/hm2,生物量在干、枝、叶、花、果、果苞及根中的分配比例为52.18∶21.82∶3.70∶2.26∶2.65∶2.07∶15.33。板栗林5种主要养分元素N、P、K、Ca和Mg的贮存量为315.38kg/hm2,不同器官中5种养分元素贮存量排序为干>枝>根>叶>花>果苞>果。土壤层中5种养分元素贮存总量为206427.59kg/hm2,有效养分元素贮存量为16188.29kg/hm2,板栗林5种养分元素贮存量占土壤层5种养分元素贮存总量的0.15%,占有效养分贮存量的1.95%。板栗林对N的富集能力最强,各元素的富集系数排序为N>P>K>Ca>Mg。板栗林生态系统每积累1t干物质需要5种养分元素总量7.17kg,其中对Ca元素的需求量最大,P的最小。     

基于遗传算法的基质培黄瓜营养液配方优化

为探究施肥多因子耦合对黄瓜产量、品质、肥料利用率等方面的综合调控,获取适宜的基质栽培营养液配方.以'博耐526'黄瓜为试材,通过四因素(N、K、Ca、Mg)五水平(1/2)二次正交旋转组合设计,共23个处理,利用四元二次回归分析建立了N、K、Ca、Mg对黄瓜产量品质综合评分的回归模型,分析了双因素与三因素耦合效应对黄瓜...     

Biomass and Accumulation of Potassium,Calcium, and Magnesium in Gladiolus as Affected by Heat Units and Corm Size

In México, gladiolus is an important crop cultivated in the central part of the country. In ornamental geophytes, the size of bulbs is a critical factor, impacting plant growth and quality. The objective of the present study was to model the accumulation of potassium (K), calcium (Ca) and Magnesium (Mg) in gladiolus plants as affected by corm size (3.5, 3.0 and 2.5 cm). Regardless of corm size, total dry mass of plants accumulated in three different stages. The initial stage occurred during the corm sprouting phase and continued through the vegetative phase, ending either shortly before (plants from 3.5 cm corms), at (plants from 3.0 cm corms) or shortly after (plants from 2.5 cm corms) the heading phase. The second stage, on which the plants exhibited a rapid dry mass accumulation, occurred shortly before or shortly after the heading phase, finishing with the elongation of the flowering stem. The third stage showed the highest dry mass accumulation rate, coinciding with the elongation of the flowering stem and ending at the blooming of the spike. To complete all the phenological phases, gladiolus required 1818 heat units regardless of corm size. Not considering the nutrients provided by the corm, gladiolus required a total of 6.33, 5.59 and 5.01 mmol plant^?1 of K, 2.22, 1.69 and 1.38 mmol plant^?1 of Ca and 2.49, 2.00 and 1.68 mmol plant^?1 of Mg when grown from 3.5, 3.0, and 2.5 cm corms. At the beginning of the vegetative phase, plants tended to increase Ca content at the expense of K, whereas the proportion of Mg remained unaffected, however, between the vegetative and heading phases, the proportion of Ca declined while that of K and Mg increased. At the end of the study, the proportion of K was much higher than that of Ca and Mg, whereas the proportion of Ca and Mg was similar.     

LEAF NUTRIENT CONTENT AND TOMATO FRUIT YIELD AS AFFECTED BY SINGLE SUPER PHOSPHATE RATES APPLIED BY DRIP IRRIGATION

A drip fertigation system should use low-cost phosphorus fertilizer available in small markets to smallholders such as especially Brazilian tomato growers. A study was conducted in an unheated greenhouse to establish an optimum rate of single superphosphate (SS) to formulate an aqueous solution that can be applied to tomato plants through a low-pressure drip irrigation system. Five rates of SS [18% phosphorus pentoxide (P₂O₅)] 0, 25, 50, 100, and 200 g·plant^?1, were evaluated in a randomized block design with four replications. Each rate was subdivided into 15 equal parts. Each part was dissolved in water (210 mL for each plant) and the mixture left to settle for 24 hours. The supernatant was applied by drip irrigation every week for 15 weeks. The tomato plants were grown in 9 dm³ plastic bags containing fertilized substrate in an unheated greenhouse. The leaf contents of nitrogen (N), potassium (K), calcium (Ca), magnesium (Mg), sulfur (S), copper (Cu), and zinc (Zn) were not affected by the treatments. The highest phosphorus (P), manganese (Mn), and iron (Fe) leaf contents were obtained from plants fertilized with SS at 79; 0; 0 g·plant^?1, respectively. The marketable tomato fruit yield, measured up to 123 days after transplanting, increased with the increasing SS up to 54 g·plant^?1, resulting in a yield of 6.16 kg·plant^?1, corresponding to 10.3 kg·m^?2. A settled aqueous solution of SS (54 g·210 mL^?1 of water) can be applied weekly to tomato plant through a low-pressure drip irrigation system during the plant cycle.     

长期施肥对红壤性水稻土有机磷组分的影响

以19年肥料长期定位试验为背景,应用Bowman和Cole的有机磷分组方法,对红壤性水稻土有机磷组分及其变化进行了研究。结果表明:红壤性水稻土耕层有机磷含量较高,为225.93～322.47mgkg-1,占土壤全磷的28.59%～42.34%。土壤有机磷各组分中以中度活性有机磷含量最高,平均为134.80mgkg-1,占有机磷总量的51 58%;中度稳定性有机磷(92.46mgkg-1)占35.38%;高度稳定性有机磷(20.35mgkg-1)占7.79%;活性有机磷含量最低(13.67mgkg-1),占5.23%;长期施肥对土壤各组分有机磷量产生影响,耗磷处理,主要是中度活性有机磷和活性有机磷下降,降低量以CKNK处理。施磷主要促进中度稳定性有机磷和高度稳定性有机磷的增加,增加幅度以NPK+OMPNPK处理。不同施肥措施对土壤有机磷和无机磷库的耗竭或积累速度是不同的,耗磷条件,土壤有机磷/无机磷的比值上升,施磷使有机磷/无机磷比值下降.土壤供磷强度与有机磷/无机磷的比值呈显著负相关(r=-0.9497* ,r0.05=0.878)。     

添加脲酶抑制剂NBPT对麦秆还田稻田氨挥发的影响

氨挥发是稻田氮素损失的重要途径,为探明脲酶抑制剂NBPT对小麦秸秆还田稻田中氨挥发的影响,采用密闭室通气法,在太湖地区乌珊土上,研究了脲酶抑制剂n-丁基硫代磷酰三胺(NBPT)对小麦秸秆还田稻田中施肥后尿素水解和氨挥发动态变化的影响。结果表明:稻田氨挥发损失主要集中在基肥和分蘖肥时期。添加NBPT可明显延缓尿素水解,推迟田面水NH4+-N峰值出现的时间,并降低NH4+-N峰值,降低了田面水氨挥发速率和挥发量。NBPT的效果在基肥和分蘖肥施用后尤为明显,不加NBPT时施入的尿素在2~3 d内基本水解彻底,NH4+-N和氨挥发速率在第2 d即达到峰值,两次施肥后NH4+-N峰值分别为132.3 mg·L-1和66.3mg·L-1,氨挥发峰值为15.6 kg·hm-2·d-1和10.4 kg·hm-2·d-1;而添加NBPT后,NH4+-N峰值推迟至施肥后第4 d出现,NH4+-N峰值降至70.7 mg·L-1和51.6 mg·L-1,氨挥发峰值降至4.7 kg·hm-2·d-1和2.6 kg·hm-2·d-1。添加NBPT使稻田氨挥发损失总量从73.3 kg(N)·hm-2(占施氮量的24.4%)降低至34.5 kg(N)·hm-2(占施氮量的11.5%),降低53%。在添加小麦秸秆稻田中添加NBPT通过延缓尿素水解而显著降低了氨挥发损失。     

Impact of Supplemental Calcium Chloride on Yield,Quality, Nutrient Status,and Postharvest Attributes of Tomato

Little is known regarding the impact of calcium chloride applications during growth and development on tomato postharvest quality. This trial investigated supplemental calcium chloride applications on yield, nutrient content, texture, and postharvest quality of tomato fruit. Calcium (Ca) nutrient solution concentrations were: 60, 180, and 360 mg·L^?1 calcium, while foliar applications were (0, 1, and 2% calcium chloride w/v). Plants grown with 60 mg·L^?1 Ca had a high incidence of blossom end rot, which was not affected by calcium chloride sprays. Fruit nutrient concentrations were affected by calcium delivered through the nutrient solution. As fruit cluster position increased, fruit nutrient concentrations significantly decreased. Foliar calcium chloride sprays affected fruit soluble solids content and dry weight, but did not affect texture. Pericarp elasticity increased concomitantly with calcium in the nutrient solution. Postharvest disease incidence was not affected by calcium treatment, though weight loss during storage was negatively affected by calcium chloride sprays.     

施磷对麦/玉/豆套作体系土壤磷素变化的影响

小麦/玉米/大豆带状套作是四川省丘陵低山区主要旱地作物生产体系,了解该体系磷养分变化对优化磷肥管理和促进可持续生产有重要意义。本研究通过连续3年(2011—2013年)田间定位试验,设置P0、P1、P2、P3和P4共5个磷(P2O5)水平(玉米带分别为0 kg·hm-2、37.5 kg·hm-2、75 kg·hm-2、112.5 kg·hm-2、150 kg·hm-2,小麦-大豆带分别为0 kg·hm-2、45 kg·hm-2、90 kg·hm-2、135 kg·hm-2、180 kg·hm-2),探讨该体系中土壤全磷、速效磷、水溶性磷的变化规律和速效磷的年际变化。结果表明:在麦/玉/豆套作体系中施磷165 kg(P2O5)·hm-2(玉米带75 kg·hm-2,小麦-大豆带90 kg·hm-2),可以满足体系作物对磷的需求,基本达到磷的表观平衡,维持土壤速效磷含量在20 mg·kg-1左右。3年后5个磷水平下体系耕层土壤(0~20 cm)全磷变化量分别为-0.024 g·kg-1·a-1、-0.016 g·kg-1·a-1、0.016 g·kg-1·a-1、0.11 g·kg-1·a-1、0.15 g·kg-1·a-1,速效磷变化量依次为-1.2 mg·kg-1·a-1、-0.9 mg·kg-1·a-1、0.2 mg·kg-1·a-1、2.0 mg·kg-1·a-1和2.7 mg·kg-1·a-1。通过线性平台函数的模拟,该体系中玉米、小麦、大豆产量的土壤速效磷临界值分别为16.5 mg·kg-1、12.6 mg·kg-1和8.8 mg·kg-1。当土壤全磷含量低于0.55 g·kg-1时,土壤全磷每增加0.1 g·kg-1,土壤速效磷增加1.70 mg·kg-1;当土壤全磷大于0.55 g·kg-1,全磷每增加0.1 g·kg-1,土壤速效磷增加6.49 mg·kg-1。当土壤速效磷含量在40 mg·kg-1以下时,速效磷每增加1 mg·kg-1,水溶性磷增加0.017 mg·kg-1。综上,在麦/玉/豆体系磷肥管理中应该维持土壤全磷含量低于0.55 g·kg-1,同时速效磷含量在20 mg·kg-1左右,这样既可以保证作物产量和系统生产力又不会产生较大的环境威胁。     

Optimum N and P rates for greenhouse production of vegetative coleus using constant liquid feed

Many new coleus (C. hybridus cv.) cultivars are vegetatively propagated and require different fertilization practices from seed propagated cultivars. Two experiments were conducted to evaluate growth responses of Henna, Indian Summer, Mint Mocha, New Orleans Red, Red Head, and Trusty Rusty to 0, 70, 140, 280 and 420 mg·L^?1 nitrogen (N), and Henna, Mint Mocha, Red Head, and Trusty Rusty to 0, 6.2, 12.4, 24.8, or 49.6 mg·L^?1 phosphorus (P) to determine optimum constant liquid feed rates to produce marketable size plants from rooted cuttings. Positive growth responses in terms of biomass were found with increasing N rates but not P rates. For medium-sized cultivars such as Henna, Indian Summer, and New Orleans Red, quadratic responses were found in aboveground biomass, and N at 280 mg·L^?1 resulted in similar plant size and dry weight as those fertilized at 140 and 420 mg·L^?1 N. For large-sized cultivars such as Mint Mocha, Red Head and Trusty Rusty, plant dry weight responded linearly within the N range tested and were greatest at 420 mg·L^?1. However, plant visual quality was negatively affected by N rates at 280 and 420 mg·L^?1 in that, leaf color became less intense at these high N rates. Plants fertilized at 70 mg·L^?1 were smaller than those fertilized at 140 mg·L^?1, however, they received similar visual quality ratings because of more intense leaf color. Therefore, N at 70 to 140 mg·L^?1 can be used to grow most vegetative coleus for similar marketable quality. Mint Mocha and Henna were the only cultivars responded to P treatments that, 12.4 mg·L^?1 P rate resulted in greater biomass than the no-P control. All other cultivars had no response to supplemental P except a linear response in tissue P%. Therefore, supplemental P is not required during the 8 week production period when there is an initial P charge in the substrate. We found that substrate pH decreases with higher P rates, therefore supplemental P fertilizer can be used for adjusting pH. Both N and P rates found optimum in this study are lower than current industry practices (N at 150 to 250 mg·L^?1 and P at 24 mg·L^?1) and can significantly lower production cost and potential leaching of excessive nutrient into waterway. Nutrient treatments in further study on postharvest performance of vegetative coleus will be selected based on this study.     

Time course of N<Subscript>2</Subscript> fixation and growth of chickpea

The ¹⁵N isotopic dilution technique was used to assess N₂ fixation in desi chickpea (Cicer arientinum L.) cv. Myles at different growth stages as influenced by inoculation method. In this growth chamber study, no significant differences in nodule dry weight, amount of N₂ fixed and plant dry matter were observed between seed inoculation with seed-applied peat inoculant and soil-applied granular inoculant placed 2.5 cm below the seed. However, seed inoculation with liquid inoculant was inferior to the seed-applied peat or the granular inoculant for all parameters measured at all sampling dates. The seed-applied peat and granular inoculant treatments fixed 4.8 and 4.1 mg N plant^-1, respectively, by the late vegetative stage, and reached a maximum of 20.6 and 25.6 mg N plant^-1, respectively, by the late pod-filling stage. These values accounted for 30.5% and 34.9% of the total plant N for the peat and granular inoculant, respectively, by late pod-filling. For the liquid inoculant treatment, the amount of N₂ fixed increased from 2.3 mg N plant^-1 by the late vegetative stage to a maximum of 9.6 mg N plant^-1 which was 22.2% of total plant N by the mid pod-filling stage. The highest daily N₂ fixation rate for the peat and granular inoculant was 0.9 mg N plant^-1 and occurred between flowering and early pod-filling, whereas that for the liquid occurred between early and mid pod-filling stages (0.23 mg N plant^-1). After the mid pod-filling stage, little or no N₂ was fixed in all treatments. Plant dry matter increased from the late vegetative stage to physiological maturity but the greatest dry matter accumulation occurred between the late vegetative and early pod-filling stages in all treatments.     

Influence of Nitrogen and Sulfur Fertilization on the Mineral Composition of Broccoli Sprouts

ABSTRACT

Broccoli sprouts (Brassica oleraceae var. italica) have been attributed health protective effects based on their glucosinolate content, and thus, are recommended in diets. However, no information is available on the mineral content of this novel product and how fertilization might influence it. The influence of nitrogen (N) and sulfur (S) applications (0, 14, and 28 mg· N dish^?1 and 0, 4.5, and 9 mg· S dish^?1) on the mineral content [N, S, potassium (K), calcium (Ca), magnesium (Mg), sodium (Na), chloride (Cl), and silicon (Si)] of broccoli sprouts (Brassica oleraceae var. italica cv. ‘Marathon’) was determined 11 d after sowing. It was found that N and S fertilization significantly (P < 0.001) influenced the uptake of all elements except phosphorus (P). Sulfur concentrations in broccoli sprouts varied between 11.4 and 15.2 mg· g^?1 (dw), while the Ca, Mg, P, K, and Na concentrations were below 10 mg· g^?1 (dw). The Cl contents ranged from 13.6 to 23.1 mg· g^?1 (dw). The highest S concentration was found when 9 mg· dish^?1 S and 14 mg· dish^?1 N was applied. A higher N rates of 28 mg· dish^?1, N yielded no higher S uptake. The significantly (P < 0.05) highest Ca, Mg, and Na concentrations were found in the control treatments, while this effect proved to be not consistent for P. The results clearly revealed that N and S fertilization increased biomass production even in the early growth stages. With view to maintaining high Ca concentrations an application in the form of ammonium sulfate would be preferable.     

氟 对玉米产量品质及土壤性质的影响

适量氟对动物和人类健康有益, 而过量氟对动物和人类健康有害。为研究氟对玉米产量品质及土壤性质的影响, 采用盆栽试验研究了添加0、100 mg·kg^-1、200 mg·kg^-1、500 mg·kg^-1、1 000 mg·kg^-1 和1 500 mg·kg^-1 氟(NaF)对玉米产量、粗蛋白和淀粉含量及土壤pH、水溶性钙和微生物数量的影响。结果表明: 随氟处理浓度的增加玉米产量显著降低, 减产9.9%~85.4%; 玉米籽粒蛋白质含量显著增加, 从91.8 g·kg^-1 增加到108.8 g·kg^-1。加入氟100 mg·kg^-1 和200 mg·kg^-1 时, 淀粉含量表现为下降趋势,而当加入氟500 mg·kg^-1、1 000 mg·kg^-1 和1 500 mg·kg^-1 时, 淀粉含量表现为上升趋势。玉米不同部位氟含量基本上随氟浓度的增加而增加, 玉米根部和籽粒含氟量与氟添加量的相关性达极显著水平, 相关系数分别为r_根=0.998^**和r_粒=0.915^**; 叶含氟量与氟添加量的相关性达显著水平, r_叶=0.852^*; 玉米不同部位氟含量的大小顺序为根>叶>叶鞘>茎>籽粒。氟浓度在200 mg·kg^-1 时, 籽粒含氟量已超过无公害农产品标准1.0 mg·kg^-1。石灰性土壤添加氟后, 可使土壤pH 增加,从8.05 增加到8.70; 水溶性钙含量显著下降, 由2.71 g·kg^-1 下降到1.02 g·kg^-1。随氟浓度的增加土壤放线菌数量显著降低, 与对照相比, 降低0.92%~65.22%; 低浓度的氟可以促进土壤细菌、真菌的生长, 而高浓度的氟可以抑制细菌、真菌的生长。