Dicalcium phosphate dihydrate (DCPD) and octacalcium phosphate (OCP) are important P solid phases is soil systems. They both have been recognized as precursor phases to the formation of thermodynamically more stable hydroxyapatite (HAP). Their metastability with respect to HAP may be explained by precipitation kinetics and the influence of dissolved organic C (DOC) on crystal growth. Precipitation rates of DCPD and OCP were measured at respective pHs of 5.7 and 6.0, and 25{dollar}spcirc{dollar}C in the absence and presence of organic acids common to soil solutions using a seeded crystal growth method. Initial total soluble (TS) C levels added as humic, fulvic, tannic, and citric acids ranged from 0.26 to 9.0 mM C for DCPD experiments and 20 uM to 2 mM C for OCP experiments. Precipitation of DCPD and OCP was inhibited by adsorption of these organic acids onto crystal seed surfaces blocking sites that act as nuclei for new crystal growth. The efficiency of adsorbed organic acids at inhibiting DCPD and OCP crystal growth is related to their functional group content, size, hydrophobicity, geometry, and orientation on the crystal surface. Of the three Ca phosphate minerals considered, precipitation inhibition increased in the order DCPD {dollar}<{dollar} OCP {dollar}<{dollar} HAP.; Soil incubation and plant available P experiments were conducted to examine the influence of organic acids on P status of soil systems. For the incubation study, a soil was treated with solutions containing 6 to 8 mM Ca{dollar}sb{lcub}rm TS{rcub}{dollar} and PO{dollar}sb{lcub}rm 4TS{rcub}{dollar}, with and without 2 mM C as humic acid. Studies examining bioavailability of P to spring wheat (Triticum aestivum L.) and sorghum-sudan grass (Sorghum sudanese L.) were carried out in controlled environment chambers on soils treated with organic acids. These experiments demonstrated that organic acids were able to increase P solubility and plant availability in soils.; Fulvic acid isolated from a water soluble wheat straw extract was chemically characterized and was most similar to fulvic acids isolated from aquatic systems. It was representative of the hydrophobic, nonhumified fraction of the initial leachate of plant residues and found to inhibit Ca phosphate precipitation. Thus, plant residue breakdown products can enhance P fertilizer efficiency by increasing P bioavailability in soils.
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机译:磷酸二钙二水合物(DCPD)和磷酸八钙(OCP)是土壤系统中重要的P固相。它们都被认为是热力学上更稳定的羟基磷灰石(HAP)形成的前体相。它们相对于HAP的亚稳定性可以用沉淀动力学和溶解的有机碳(DOC)对晶体生长的影响来解释。使用晶种生长方法,在不存在和存在土壤溶液所共有的有机酸的条件下,分别在5.7和6.0的pH值和25℃下测量DCPD和OCP的沉淀率。作为腐殖酸,黄腐酸,单宁酸和柠檬酸添加的初始总可溶性(TS)C水平在DCPD实验中为0.26至9.0 mM C,在OCP实验中为20 uM至2 mMC。这些有机酸在晶种表面的吸附会阻止DCPD和OCP的沉淀,而这些晶种会阻塞充当新晶体生长核的位点。吸附的有机酸抑制DCPD和OCP晶体生长的效率与其在晶体表面的官能团含量,大小,疏水性,几何形状和取向有关。在考虑的三种磷酸钙矿物中,降水抑制以DCPD HAP的顺序增加。进行了土壤培养和植物有效磷试验,以检验有机酸对土壤系统磷状况的影响。对于孵化研究,用含有6至8 mM Ca {dollar} sb {lcub} rm TS {rcub} {dollar}和PO {dollar} sb {lcub} rm 4TS {rcub} {dollar}的溶液处理土壤,有和没有2 mM C的腐殖酸。在有机酸处理过的土壤中,在可控环境室内对磷对春小麦(Triticum aestivum L.)和高粱-苏丹草(Sorghum sudanese L.)的生物利用度进行了研究。这些实验证明有机酸能够增加土壤中磷的溶解度和植物利用率。从水溶性小麦秸秆提取物中分离出的富里酸具有化学特征,与从水生系统中分离出的富里酸最相似。它代表了植物残液初始浸出液的疏水性,非腐殖化部分,并能抑制磷酸钙的沉淀。因此,植物残渣分解产物可以通过增加土壤中磷的生物利用度来提高磷肥的利用率。
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