根土微环境对早实核桃细根时空分布、养分特征的影响

以长势基本一致且处于稳产期的‘新新2号’早实核桃(Juglans regia L.)后代为研究对象,按照小格子法将根土连续体划分为144个采样小区。于2022年每月采集根、土样品,测定细根生物量并构建二维空间分布图,研究细根形态指标、养分特征以及土壤水、养质量分数并分析其对早实核桃细根时空分布、养分特征的影响。结果表明:早实核桃细根主要分布在垂直方向的0~0.4 m土层和距树干水平方向1.5 m范围内,占细根分布总量的80%。细根形态参数值(生物量、根长密度、根表面积密度、根体积密度)和养分质量分数均随土层加深呈下降趋势,细根在微环境水平变异时差异不明显。夏、秋季细根形态参数值均显著高于春、冬季。土壤全氮、全磷质量分数随土层加深逐渐减少,土壤全钾质量分数在整个空间分布上无明显差异。土壤含水率随土层加深而增加,距树干距离越远含水率越低。土壤各养分质量分数的季节性差异较大,全氮质量分数在夏、秋季较高,在春季最低;全磷质量分数在春季最高;全钾质量分数在冬季最高;土壤含水率在秋、冬季最高。细根形态、养分质量分数与土壤全氮、全磷、含水率的关系更密切,相关性存在一定季节差异。细根生长在细微变异的环境下仍具有一定的趋水趋肥性。对早实核桃进行肥水精细化管理时,可根据根土的时空关系,在根区适时灌溉,季节性调整肥料养分,施肥则以氮、磷肥为主。

青海高寒区4种人工林细根生物量及其养分储量变化特征

【目的】研究青海高寒区4种人工林的细根生物量及其养分储量时空变化特征,为该地区植被恢复和人工林经营提供理论依据。【方法】在青海高寒区选择白桦、青杨、华北落叶松和青海云杉4种典型人工纯林,2019年5—10月采集0~60 cm土层细根样品,测定细根生物量及其C、N、P含量,通过方差分析探究季节、树种和土层对细根生物量及其养分储量的影响。【结果】白桦、青杨、华北落叶松和青海云杉4种人工林0~60 cm土层的细根生物量分别为7.63、6.89、6.11和19.31 t·hm^(-2),青海云杉林细根生物量显著高于其他林分(P<0.05)。各林分细根生物量季节差异显著(P<0.05),均表现为秋季>夏季>春季。细根生物量主要分布在表层土壤,0~20 cm土层占比超过68%,随土层加深呈指数型降低。阔叶林细根的养分含量高于针叶林,阔叶林生长表现出较高的养分需求。各林分细根C含量表现为秋季>夏季>春季,N、P含量总体表现为夏季显著低于春季和秋季(P<0.05)。细根C、N和P含量总体上随土层加深而减小。青海云杉林细根C、N、P储量在各季节均显著高于其他树种;秋季细根C、N和P储量显著高于春季和夏季(P<0.05)。【结论】青海高寒区4种人工林细根生物量和C、N、P含量及储量存在明显的季节变化和垂直分布特征,秋季细根生物量最高,细根主要分布在表层土壤并随土层加深呈指数型减少趋势;细根的C、N、P储量时空变化规律与细根生物量一致,在4种人工林中以青海云杉林最高。青海高寒区人工林经营应结合季节特征,在生长季初期通过合理经营措施促进细根生长发育,并注重保护表层细根资源以提高植被恢复力。

喀斯特林地细根碳氮磷生态化学计量特征的季节变化及其影响因子

植物细根养分生态化学计量特征是植被适应土壤环境的一种策略。为了解喀斯特地区不同林地类型细根碳(C)氮(N)磷(P)的生态化学计量比值的季节变化及其影响因素,该文研究了喀斯特地区灌木林和乔木林活细根和死细根的C、N、P含量和比值及其与环境因子的关系。结果表明:(1)总体上乔木林两类细根C、N、P含量高于灌木林,表明乔木物种细根对养分的吸收和储存比灌木物种更强。另外,两种林地类型活细根C含量显著高于死细根(P<0.05),而活细根N、P含量则低于死细根。(2)两种林地类型的两类细根C含量在雨季均低于旱季;灌木林活细根N、P含量在雨季高于旱季,而乔木林相反。灌木林活细根C∶N、C∶P和N∶P比值在雨季均低于旱季;乔木林两类细根的C∶N和C∶P比值在雨季高于旱季,而N∶P比值则是雨季低于旱季。雨季较低的活细根N∶P比值,表明灌木林和乔木林的植物在雨季的P限制程度较低。(3)两种林地类型上坡两类细根的C含量均高于中坡和下坡,而灌木林下坡N、P含量相对较高,乔木林中坡N、P含量相对较高;灌木林上坡两类细根C∶N、C∶P、N∶P比值相对较高,乔木林下坡两类细根的C∶N比值高于其他坡位而C∶P和N∶P比值是上坡高于其他坡位,表明两种林地中的植物在上坡受P限制影响较强,在中下坡受影响较弱。(4)冗余分析表明,林地类型、有效磷、季节是细根C、N、P养分含量及比值的主要影响因子,它们的单独解释量分别为18.8%、6.6%、6.5%。上述结果表明,在人工促进植被恢复时应考虑适当的林地类型、季节以及坡位差异造成的N∶P比值变化的影响,以便加快喀斯特生态系统的恢复。

柏木根系分泌物对栾树细根形态及N、P含量的影响

为研究混交过程中柏木根系分泌物对栾树细根生长的影响,以一年生栾树盆栽幼苗为研究对象,通过施加1株、2株、4株、8株4个浓度柏木根系分泌物(分别记为G1、G2、G4、G8)于栾树盆栽中,探讨柏木根系分泌物对栾树幼苗1~5级细根形态及N、P含量的影响。结果表明:(1)栾树细根直径随根序的增加而增大,施加根系分泌物显著减小了1~2级细根的直径(P<0.05);细根比根长、比表面积均随根序的增加而减小,施加根系分泌物显著增大了1~2级细根的比根长及比表面积(P<0.05);随根系分泌物施加浓度的提高,栾树比根长及比表面积先增大,而直径先减小,然后均趋于平缓波动的态势。(2)栾树细根N、P含量均随根序的增加而减小,而N/P在根序间的变化不显著;施加柏木根系分泌物显著增大了栾树1~2级细根的N、P含量(P<0.05),但减小了1~5级细根的N/P;随根系分泌物施加浓度的提高,栾树细根P含量增大,N/P减小,而N含量先增加后呈现平缓变化的趋势。(3)栾树细根N、P含量均与其比根长、比表面积和直径等形态特征之间呈显著的相关关系(P<0.05)。研究发现,柏木根系分泌物可改善土壤养分的有效性,从而缓解栾树植株的缺P症状,细根通过调整其形态以提高养分利用效率;柏木根系分泌物主要影响栾树1~2级细根的形态及N、P含量;4株柏木根系分泌物的剂量更有利于栾树根系的生长。

氮磷配施对刨花楠幼林细根性状的影响

氮磷是陆地生态系统植物生长的主要限制性元素,细根对植物生长具有重要影响。为了解氮磷配施对刨花楠人工幼林细根性状的影响,以3年生刨花楠人工幼林为对象,于2016年和2017年每年4-9月的每月中旬进行氮磷配施(添加比例分别为8∶1、10∶1、12∶1、15∶1),测定比根长、比表面积、平均直径、根组织密度、总碳、总氮含量及碳氮比等细根表型和养分性状指标,分析氮磷配施对细根性状的影响。结果表明:氮磷配施对细根性状的影响在不同季节表现不同。6月,氮磷配施显著提高细根比表面积、总氮含量及0~1 mm的细根比根长,降低细根组织密度、碳氮比及0~1 mm细根直径,以氮磷比为12∶1处理最为明显,但在12月,氮磷配施则会显著提高细根组织密度、总氮含量、碳氮比及0~1 mm细根生物量。主成分分析发现,不同氮磷比添加对细根性状间关系影响不同,其中氮磷比为12∶1处理的细根性状分布在第1轴的两端,其他处理后的细根性状分布在第1轴和第2轴2个轴。细根平均直径变化量与全株生物量相对生长速率呈显著负相关,以氮磷比为12∶1的配施处理最有利于协调细根性状间关系,以及细根性状与全株生物量相对生长速率间的关系。

Isolation of Six Phosphate Dissolving Rhizosphere Bacteria （Bacillus subtilis） and Their Effects on the Growth, Phosphorus Nutrition and Yield of Maize （Zea mays L.） in Mali

The disadvantages of the long term application of Tilemsi natural phosphate （TNP） on maize （Zea mays L.） production has come out because of its low P availability. Some functional soil microbes, such as phosphate dissolving bacteria, have great potential in improvement of P solubility from TNP and P uptake by plants. The present study aimed to isolate and characterize typical phosphate dissolving bacterial strains （Bacillus subtilis） from Malian soils, and investigate their role in P uptake by maize grown in soils amended with TNP. The experimental design was a split plot with three main plots of fertilizers sources, i.e., natural phosphate, commercial fertilizer and without fertilizer, and with seven sub-plots of six microorganisms plus the control. The field experiment results have shown that the maize inoculated with the phosphate dissolving bacteria was improved in seed germination, plant growth, plant production （increase yield by 42%）, grain and aerial dry biomass （P） content of 34% and 64%, respectively. They have also shown that the locally available TNP can be used by the Malians farmers in maize culture and have comparable production to the one obtained with the costly imported commercial phosphate fertilizer, like the complex cereal. The project has provided information for the combined use of the Mali TNP and phosphate dissolving bacteria Bacillus subtilis subsp, subtilis （T）： DSM 10 in improvement of maize production in the country.

Contribution of Root Proliferation in Nutrient-Rich Soil Patches to Nutrient Uptake and Growth of Maize

Root proliferation can be stimulated in a heterogeneous nutrient patch; however, the functions of the root proliferation in the nutrient-rich soil patches are not fully understood. In the present study, a two-year field experiment was conducted to examine the comparative effects of localized application of ammonium and phosphorus (P) at early or late stages on root growth, nutrient uptake, and biomass of maize (Zea mays L.) on a calcareous soil in an intensive farming system. Localized supply of ammonium and P had a more evident effect on shoot and root growth, and especially stimulated fine root development at the early seedling stage, with most of the maize roots being allocated to the nutrient-rich patch in the topsoil. Although localized ammonium and P supply at the late stage also enhanced the fine root growth, the plant roots in the patch accounted for a low proportion of the whole maize roots in the topsoil at the flowering stage. Compared with the early stage, fine root length in the short-lived nutrient patch decreased by 44%-62% and the shoot dry weight was not different between heterogeneous and homogeneous nutrient supply at the late growth stage. Localized supply of ammonium and P significantly increased N and P accumulation by maize at 35 and 47 days after sowing (DAS); however, no significant difference was found among the treatments at 82 DAS and the later growth stages. The increased nutrient uptake and plant growth was related to the higher proportion of root length in the localized nutrient-enriched patch. The results indicated that root proliferation in nutrient patches contributed more to maize growth and nutrient uptake at the early than late stages.