Evaluation of Phosphorus Pools and Fractions in an Acid Tropical Soil Recapitalized with Different Phosphorus Sources

Abstract

Bray 1 phosphorus (B1P) and sequential phosphorus (P) fractions were determined on soils treated with triple superphosphate (TSP), Gafsa (GPR), and Christmas Island phosphate rocks (CIPR), respectively, with and without manure. The fractions extracted in decreasing lability were iron oxide–impregnated paper strip P (Pi‐strip P), inorganic (Pi), and organic (Po) bicarbonate (NaHCO3‐Pi and ‐Po), hydroxide [sodium hydroxide (NaOH)‐Pi and ‐Po], hydrochloric acid (HCl) P, and residual (residue P). The magnitude of B1P was in the order TSP>GPR=CIPR. Average B1P from PRs was two‐fold the amount in TSP, whereas that of the fractions was NaOH‐P>Residue P<sodium bicarbonate (NaHCO₃) P<Pi‐strip P <HCl. Bray 1 extracted mainly the most labile fractions (Pi‐strip P and NaHCO3‐Pi), and plant P uptake was correlated mainly to NaOH‐Po and NaHCO₃‐Pi. Magnitude of various fractions differed between TSP and PRs. Both B1P and the fractions were equally correlated to P uptake (R²=0.38**). Nevertheless, sequential fractionation appears to be a powerful tool to identify the P status and availability in soil.     

Changes in organic and inorganic phosphorus composition of two grassland soils and their particle size fractions during 60–90 years of cultivation

Changes are reported in the chemical and biological composition of soil phosphorus (P) in a Black Chernozemic silt loam (Blaine Lake Association) and a Dark Brown Chernozemic sandy loam (Bradwell Association) during 60–90 years of cultivation. Cultivated and adjacent uncultivated soils were sampled, separated into particle size fractions by physical dispersion and the fractions subjected to a sequential chemical extraction to remove several forms of inorganic phosphorus (Pi) and organic phosphorus (Po). In the uncultivated Bradwell soil significant amounts (7%) of secondary (NaOH extractable) Pi forms were associated with high levels of labile (bicarbonate and resin extractable) Pi. These secondary Pi forms, which were concentrated in the finer particle size fractions (<2μm), contributed to the P loss during cultivation of the coarse textured Bradwell soil, whereas all P loss in the Blaine Lake soils was due to Po losses alone. Sulphuric acid extractable P (thought to be mainly apatites) accumulated in both soils under cultivation, particularly in the coarse silt (50–5 μm) fraction. Labile P fractions were greatly reduced during cultivation, indicating a significant reduction in available P and P fertility of cultivated soils. This reduction in P fertility was closely tied to soil organic matter losses.     

Characterization of organic and inorganic phosphorus in the highland plateau soils of Ethiopia

Abstract

Surface horizon samples from two Vertisols, an Andisol, and an Alfisol were collected from farmers’ fields, research station farms, and from uncultivated/ nonfertilized areas to characterize the organic and inorganic forms of phosphorus (P) in the highland plateau soils of Ethiopia using the Hedley soil P fractionation scheme. The total P values ranged from 226 mg‐kg^‐1 in the Akaki Vertisol samples developed on alluvial deposits to 1570 mgkg^‐1 in the Andisol samples, where the HCl fraction dominates the inorganic soil P pool. The Alfisol samples contained 400 mg‐kg^‐1 of total P, with the NaOHand residual P being the dominant P fractions. The resin inorganic phosphorus (Pi) and bicarbonate Pi fractions generally accounted for less than 15% of the total P in all soils, and were positively correlated with organic C. The NaOH P fraction, which was most prominent in the surface horizon samples of the Alfisols, accounted for 4–15% of total P. The HCl P fraction, ranged from 1% in the Alfisols to 46% in the Andisols, and positively correlated with pH. All of the P fractions were negatively correlated with clay and extractable Al contents. The organic P (Po) fractions were positively related to organic carbon (C) and dithionate extractable iron (Fe). All samples collected from farmers’ fields showed a loss of P from the residual, and HCl fractions as compared to the uncultivated/nonfertilized samples. There is also a decrease in the labile P (resin Pi, bicarbonate Pi, and Po) fractions, except for the Akaki Vertisol samples. However, under research station management, the amount of labile P fractions either increased or remained at the same level as the uncultivated/nonfertilized samples, except for the Andisol. Addition of P fertilizer at the recommended rates to the Debre Zeit research station Vertisol appears to have resulted in a slight increase in the labile P and prevented loss of P from the HClP and residual P fractions.     

农牧交错带土壤磷素动态研究

对海拔2600～3000m农牧交替带不同退化程度的草原、草原开垦后土壤磷素变化进行了系统研究。退化草原包括:轻度(LDP),中度(MDP)和重度(HDP)3种类型,耕种土壤开垦年限从1至50年不等,土壤样品取自甘肃省7县市18个地点,主要土壤类型为黑钙土。通过进行磷的分级发现,草原开垦后土壤有机磷组分明显下降。种植8、16、41年后土壤有机磷分别下降8%、20%和36%;区域性土壤分析结果亦表明,耕种30年以上的土壤有机磷平均下降35%。有机质矿化,土壤侵蚀后由于耕作措施造成的底土与表土混合,以及无机磷肥的施用使得耕种土壤中Ca-P明显增加。NaOH浸提的潜在活性有机磷,随着草原退化程度的增加和耕作年限的延长有递减的趋势。活性有机磷与总有机磷显著相关(R2=0.63),而活性有机磷的多寡与耕种和施肥明显相关。     

Phosphorus Fractionation of Composted Crop Residues and Forms of Soil Phosphorus after 22 Years of Compost Application to Andosols

Phosphorus (P) fractionation of composted crop residues and Andosols amended with composted crop residues was conducted. Inorganic P (Pi) comprised 85% of total P in the composts. The distribution of inorganic P forms was in the following order: sodium hydroxide (NaOH) Pi > hydrochloric acid (HCl) Pi > sodium bicarbonate (NaHCO₃) Pi > water (H₂O) Pi. After 22 years of the compost application to two Andosols, total Pi concentration significantly increased. However, total organic P (Po) concentration in the composted soil was not significantly different from that in noncomposted soil. Among of Pi fractions, compost application distinctly increased Al-Pi concentration, followed by Fe-Pi. The ratio of Fe-Po to total P concentrations significantly decreased by compost application.     

Plant Availability of Soil Phosphorus Forms accumulated from Long‐Term Superphosphate Applications to Irrigated Pastures

Abstract: In recent years, many pastoral farmers in New Zealand reduced or withheld phosphorus (P) fertilizer application to their pasture in response to rising fertilizer costs and falling prices in farm produce. When P fertilizer application is withheld, pasture and animal production relies on the P reserves accumulated in the soil from the previous P fertilizer applications. A field‐plot experiment superimposed on irrigated pastures that had received long‐term annual superphosphate (SP) fertilizer applications for 25 years was conducted to examine the forms of P accumulated from the previous SP applications contributing to plant‐available P. The long‐term SP applications were withheld, and the soil was subjected to treatments of no fertilizer (nil), P only, sulphur (S) only, or both P and S, each with P and S at two rates in a split‐plot design with four replicates that ran for 6 years. Soil samples (0–75 mm deep) collected from the trial each year were subjected to a sequential P fractionation scheme. Results showed that most of the P forms extracted by the different extractants showed no significant differences between treatments. Only the inorganic P (Pi) extracted by sodium bicarbonate (NaHCO₃), sodium hydroxide (NaOH) I, and hydrochloric acid (HCl) showed significant differences, and these were related to plant‐available P. However, it was not possible to isolate an individual P form as the dominant P form accumulated from previous SP applications as the plant‐available P form.     

Relationship of Soil Phosphorus Pools with Bray 1 Phosphorus in Some Acid Soils of Central Southern Cameroon

We measured phosphorus (P) chemical pools of genetic horizons of five representative pedons from central southern Cameroon. Our objectives were to assess the relative abundance of P pools and to empirically model their interrelations and contributions to a P availability index. The fractionation scheme followed a modified Hedley sequential procedure with anion exchange resin, 0.5 M sodium bicarbonate (NaHCO₃; Pi and Po), 0.1 M sodium hydroxide (NaOH; Pi and Po), 0.5 M hydrochloric acid (HCl; Pi), and 2 M sulfuric acid (H₂SO₄) after soil ignition at 550 ^oC. Resin P, sodium bicarbonate (NaHCO₃-P; Pi and Po), and HCl-Pi–extractable pools accounted for 1.0, 5.7 and 0.7 % of total P (TP) respectively. The NaOH-P and residual P pools measured through 2 M H₂SO₄ emerged as the largest and most variable pools, accounting for 86.2% of TP. The relative abundance of extracted P pools decreased in the order resin P < NaHCO₃-P ≤ HCl-P < NaOH-P < H₂SO₄-P. Bray 1 P was significantly correlated with all P pools except NaHCO₃-Pi, NaOH-Pi, and residual pools.     

Inorganic and organic phosphorus pools in earthworm casts (Glossoscolecidae) and a Brazilian rainforest Oxisol

We compared differences in soil phosphorus fractions between large earthworm casts (Family Glossoscolecidae) and surrounding soils, i.e., Oxisols in 10 year-old upland agroforestry system (AGR), pasture (PAS), and secondary forest (SEC) in the Central Brazilian Amazon. AGR and PAS both received low-input fertilization and SEC received no fertilization. We found that earthworm casts had higher levels of organic hydroxide P than surrounding soils, whereas fertilization increased inorganic hydroxide P. Inorganic P was increased by fertilization, and organic P was increased by earthworm gut passage and/or selection of ingested materials, which increased available P (sum of resin and bicarbonate fractions) and moderately available P (sum of hydroxide and dilute acid fractions), and P fertilizer application and land-use increased available P. The use of a modified sequential P fractionation produced fewer differences between earthworm casts and soils than were expected. We suggest the use of a condensed extraction procedure with three fractions (Available P, Moderately Available P, and Resistant P) that provide an ecologically based understanding of the P availability in soil. Earthworm casts were estimated to constitute 41.0, 38.2, and 26.0 kg ha⁻¹ of total available P stocks (sum of resin and bicarbonate fractions) in the agroforestry system, pasture, and secondary forest, respectively.     

长期定位施肥对潮土磷素形态和有效性的影响

研究长期定位施肥对潮土各形态磷含量变化及磷有效性的影响,为潮土合理施用磷肥提供理论依据.长期定位施肥试验开始于1990年,设CK(不施肥)、N2(单施尿素)、N2P(不施钾肥)、N2K(不施磷肥)、N1PK(低量氮肥和磷钾肥)、N2PK(平衡施肥)、N3PK(中高量施肥)、N4PK(高量氮肥和磷钾肥)、N2PKM(化肥...     

Moderately resistant phosphorus forms in subtropical ultisol of Argentina

Abstract

The efficiency of phosphorus (P) fertilization may be improved through knowledge of soil P fraction changes with time. This study examined: i) the distribution of P fractions according to Hedley's fractionation scheme and ii) the sequential changes in soil organic P (OP) and inorganic P (IP) in a typical Kandihumult, under favorable conditions for mineralization and under depletion conditions, with and without P fertilization. Soil P fractions considered were IP‐resin, IP‐ and OP‐bicarbonate, and IP‐ and OP‐hydroxide. The soil is characterized by the predominance of moderately resistant P, in organic and inorganic fractions. In the presence of favorable conditions for mineralization, a substantial decrease in moderately resistant organic P was observed, enhanced even more by fertilizer incorporation. The decrease of total extracted P (TPe) before depletion situations was mainly produced in the moderately resistant fraction, that registered a decrease of 23% (of this value 65% were due to OP). The main fate of the fertilization, in both situations (active mineralization as well as depletion) was moderately resistant inorganic phosphate.     

Anion‐exchange membrane,water, and sodium bicarbonate extractions as soil tests for phosphorus

Abstract

Three techniques were evaluated as soil P tests for western Canadian soils: anion‐exchange membrane (AEM), water, and bicarbonate extraction. The AEM, water, and bicarbonate‐extractable total P represented novel approaches to compare to the widely used bicarbonate‐extractable inorganic P (traditional Olsen) soil test. In a range of Saskatchewan soils, similar trends in predicted relative P availability were observed for AEM, water extraction, bicarbonate‐extractable total P, and bicarbonate‐extractable organic P. Correlations between soil test values revealed AEM and water‐extractable P to be most closely correlated, consistent with the similar manner of P removal in the two tests.

Phosphorus availability, as predicted by the tests, was compared to actual P uptake by canola and wheat grown on 14 soils in a growth chamber experiment. P uptake by canola was highly correlated with AEM (r² = 0.86–0.90), water (0.87 ‐0.94), and bicarbonate‐extractable total (0.91) and inorganic (0.92) P. Uptake of P by wheat was not quite as highly correlated with test‐predicted values: AEM (r² = ‐0.73–0.78), water (0.72–0.77), bicarbonate total (0.82), bicarbonate‐inorganic P (0.75).

The similarity in coefficients of determination among test methods indicated nearly identical abilities of the tests to predict soil P availability in the range of soils examined. The AEM and water extractions, unlike bicarbonate, are largely independent of soil type and may prove superior when a wider range of soils is being tested. Bicarbonate‐extractable total P and water‐extractable P suffer limitations in analytical simplicity and cost. In testing for P alone, AEM was considered superior to the other methods due to low cost, simplicity, independence of soil type, and high correlation with plant uptake.     

Evaluation of anion exchange membranes to estimate bioavailable phosphorus in native grasslands of semi‐arid Northwestern Australia

Abstract

Anion exchange membranes (AEMs) were used to assess the P status of semi‐arid sub‐tropical soils of high P sorption capacity from the Pilbara region in northwestern Australia. We determined the most appropriate procedure for using AEMs in these soils using a factorial of extraction ratios and shaking times and compared the method with extraction by water. Significantly more inorganic P (Pi) was extracted by the membranes (AEM‐Pi) than by water, and the amount extracted increased with extraction time but was generally independent of the extraction ratio. Maximum AEM‐Pi was 3.61 μg g^‐1 after eight hour extraction. The AEM procedure was compared with traditional extraction procedures using 0.5 M sodium bicarbonate (NaHCO₃) and 0.1 M sodium hydroxide (NaOH) to assess ability to detect spatial heterogeneity. The amount of Pi extracted decreased in the order: AEM>NaOH>NaHCO_3* The AEM method detected a significant effect of depth on Pi (P=0.0001), while the NaOH method detected both site and treatment effects (P<0.05). Inorganic P extracted by NaHCO₃ did not vary by site, treatment, or depth. Coefficients of variation were generally least using the AEM method. We recommend that studies of spatial and temporal dynamics of P on highly‐weathered soils in semi‐arid regions include measurement of both AEM‐Pi and NaOH‐extractable Pi.     

Faba bean (Vicia faba L.) varieties reveal substantial and contrasting organic phosphorus use efficiencies (PoUE) under symbiotic conditions

Background

The excessive use of inorganic P (Pi) in soils is alarming as it is causing numerous environmental problems and may lead to the depletion of rock phosphate reserves earlier than expected. Hence, to limit the over-dependence on Pi, there is the need to investigate organic phosphorus (Po), which is the dominant P form of soil P pool, as an alternate P source for plant growth.

Aim

The present study seeks to investigate organic P use efficiency of eight varieties of faba bean grown symbiotically.

Methods

The plants were grown in pots (6 kg soil) under greenhouse condition with three P source, namely, phytic acid (organic P, Po), KH₂PO₄ (inorganic P, Pi), and no-P. The P was applied at the rate of 1.79 g kg⁻¹ soil.

Results

The plants grown with Po and Pi produced similar amounts of root, shoot, and total dry matters. Despite producing statistically similar dry matters, P uptake by Pi-fertilized plants was twofold higher than by Po-fertilized plants. Meanwhile, Pi differed significantly from Po in terms of nodulation characteristics such as nodule dry biomass and individual nodule dry biomass. However, Po varied significantly from Pi in P utilization and acquisition efficiencies. Principal component analysis of Pi and Po revealed no significant variation and close association, confirming the nonsignificant differences between the two P treatments. Among the varieties tested, Tiffany tended to accumulate more dry matter, coupled with highest organic P utilization efficiency (0.48 g mg⁻¹) as well as the highest organic P beneficiary factor (80%).

Conclusion

These results provide a solid basis for further comparisons at physiological, biochemical, and molecular levels between Tiffany (Po-efficient) and Fuego (Po-inefficient) varieties, offering deep insights into and making it easier to understand the mechanisms that allow soil Po to be utilized under symbiotic conditions.     

The chemical nature of organic phosphorus that accumulates in fertilized soils of a temperate pasture as determined by solution 31P NMR spectroscopy

Inefficiency of fertilizer phosphorus (P) use in grazing systems is often associated with the accumulation of inorganic and organic P in fertilized soil. However, the chemical nature of the accumulated organic P remains poorly understood. The aim of this study was to use solution ³¹P nuclear magnetic resonance (NMR) spectroscopy on sodium hydroxide–ethylenediaminetetraacetic acid (NaOH‐EDTA) extracts to identify the chemical nature of organic P in soils from a medium‐term (13 years) permanent pasture field experiment. This included an unfertilized pasture (P0), and treatments designed to maintain soil P fertility at near ‘optimum' (P1) and ‘supra‐optimum' (P2) levels for pasture growth; pastures at all levels of soil P fertility were continuously grazed with either a moderate or high stocking rate (SR09 and SR18). Approximately 20% of the fertilizer P added to pastures was recovered as organic P in NaOH‐EDTA extracts at the P1 level of soil P fertility in the 0–10 cm soil layer, and the majority (≈ 65%) of this was detected as the broad phosphomonoester signal. In addition, several specific forms of phosphomonoesters (myo‐ and scyllo‐inositol hexakisphosphate, α‐ and β‐glycerophosphate, and RNA mononucleotides) and phosphodiesters were detected across all soils but at low concentrations. This study shows that phosphate fertilization of pastures primarily results in the accumulation of complex forms of phosphomonoesters rather than that of specific forms of recognizable biomolecules (e.g ., myo‐inositol hexakisphosphate).     

Organic phosphorus utilization by wheat plants under sterile conditions

An experiment was set up to make a critical assessment of the role of organic P (Po) in soil solution in the nutrition of wheat plants under sterile conditions. Three concentration gradients of Po (17.08, 27.31 and 37.61 M l^-1) were created in a sterilized Oxisol by fertilization with a soil solution prepared by a dry freezing technique and containing antibiotics to minimize microbial growth. Due to the high P fixing capacity of the Oxisol and high buffering capacity of inorganic P (Pi), as compared to Po, a negligible change in Pi concentration occurred, due to fertilization after equilibrium in soil solution. Phosphorus supply had a positive effect on dry matter and P concentration of the plants. Acid phosphatase secretion by plant roots was 5–11 times higher in Po treatments than in the respective Pi treatments. No alkaline phosphatase activity was detected, confirming the absence of microbial activity in our system. Net P inflow into plants was significantly higher in the Pi + Po treatments at all three Po concentrations than in the respective Pi (control) treatment, providing evidence for the role of Po in the P nutrition of plants. It was hypothesized that plants secrete phosphatases in response to the presence of Po in soil solution and Po might be responsible for the increase in P influx to wheat plants.     

Effect of Drying on Phosphorus Distribution in Poultry Manure

Abstract

Laboratory drying may alter manure phosphorus (P) distribution. The effects of freeze, air (22°C), and oven (65°C) drying on sequentially fractioned poultry manure P were examined. Higher drying temperatures resulted in lower percentage of dry matter. Increased H₂O‐ and decreased sodium bicarbonate (NaHCO₃)‐extractable P with drying provided evidence that drying increases poultry manure P solubility. Labile fractions were predominantly inorganic P (P_i), whereas sodium hydroxide (NaOH) and hydrochloric acid (HCl) fractions had significant amounts of organic P (P_o). Drying altered H₂O‐ and NaHCO₃‐extractable P_i but had no consistent effect on P_o in these fractions. This work suggests that variations due to drying should be taken into consideration when evaluating manures for P availability or when comparing data in which different drying methods have been utilized.     

Effect of organic,inorganic, and combined organic and inorganic P fertilization on plant P uptake and soil P pools

Phosphorus (P) is a limited resource, and its efficient use is a main task in sustainable agriculture. In a 6‐year field experiment on a loamy‐sand soil poor in P, the effects of organic, inorganic, and combined organic‐inorganic fertilization on crop yield, P uptake into grain, and soil properties (organic matter [OM] content, pH, water‐extractable P [P_w], double lactate–extractable P [P_dl], oxalate‐extractable P [P_ox], P‐sorption capacity [PSC], and degree of P saturation [DPS]) were investigated for the maritime climate in northeast Germany. Nine treatments were compared: a control treatment without fertilizer application, two organic fertilizers (cattle manure [CM] and biowaste compost [BC]; applied at a rate of 30 t ha^–1 in autumn 1998 and 2001), application of triple‐superphosphate (TSP; applied once a year either in autumn or in spring to evaluate the effects of application date), and combinations of organic and inorganic fertilizations. Several winter and spring crops (oilseed rape, barley, wheat) were cultivated according to good agricultural practice. The 6 year–average yield and P uptake were significantly higher for fertilized plots than for nonfertilized plots. Although the combination of organic × inorganic fertilizers resulted in higher soil P contents, significant yield increases were only found when organic fertilization was combined with TSP in spring. Small effects of P supply on yield in some years indicate that plant‐available soil P (despite of low P_dl values) was sufficient for crop growth. Phosphorus supply affected soil P_dl and P_w more than the parameters measured in the oxalate extract (P_ox, PSC, DPS). In general, periodically applied cattle manure and biowaste compost had the same effect on yield, P uptake, and soil P status as annually applied soluble mineral P.     

提取剂和土水比对旱耕地土壤无机和有机磷的提取效应

比较了O lsen(0.5 mol L-1NaHCO3)和B ray-1(0.03 mol L-1NH4F-0.025 mol L-1HC l)提取剂土水比1∶4和1∶20(W/V),对我国5种类型旱耕地土壤(pHKC l3.3~7.4)无机磷(Pi)和有机磷(Po)及外加正磷酸盐态无机磷的提取效应。结果表明,以O lsen提取剂土水比1∶20对土壤Pi和Po的提取效果最佳,其测定结果是评价土壤磷素供应能力(有效磷)和活性有机磷含量较为适宜的指标。测定的土壤大多数(占60%)磷素供应能力较差(O lsen-Pi为4.2~14.0mg kg-1),应适当加强其磷素的投入。测定的土壤活性有机磷(O lsen-PO)含量为1.4~37.9 mg kg-1,占土壤全磷的0.2%~15.8%,大多数(75%)土壤占1%~6%。采用O lsen提取剂时土壤外加Pi的固定率随土水比减小而增高,当土水比1∶4提取时,酸性和强酸性(pHKC l3.3~5.5)土壤对外加Pi的固定率达40%~86%,据此推测实际田间条件下土壤对外加Pi的固定率更大。表明酸性和强酸性旱耕地土壤对外加Pi具有强烈的固定作用。     

Influence of aggregate size on phosphorus loss and ryegrass yield in a soil cultivated intermittently

Intermittent cultivation for forage cropping and subsequent grazing by dairy cattle during winter is practiced in southern New Zealand to protect remaining pastures from poaching damage by cattle. However, this practice may degrade soil aggregate structure affecting pasture yield and nutrient loss. A study was conducted to determine the ability of different aggregate sizes to supply phosphorus (P) to ryegrass in a soil used for winter forage cropping and grazed by dairy cattle 2 out of 7 years. Over 35 weeks ryegrass was grown in pots containing one of six wet‐sieved soil aggregate size classes and leached every 2 weeks. Soil analyses included water soluble P, inorganic and organic P fractions, and P in leachate. Results showed that organic P was preferentially lost in leachate or mineralized and used by ryegrass with decreasing aggregate size, although this did not affect yield. Ryegrass yield was best correlated with bicarbonate extractable P in aggregates, and P loss with water soluble inorganic P after minimum disturbance. These findings suggest that although intermittent cultivation did not affect yield, if this practice decreases aggregate size in the future, it may increase the risk of P loss.     

Phosphorus solubility changes with time in organically amended soil in a mediterranean environment

Abstract

As in other areas of the world, in the Middle East, phosphorus (P) is also a vital element in agricultural production. Laboratory studies have shown how inorganic P changes with time after application. With increased interest in the use of organic wastes, the extent to which seasonal change, characteristic of the Mediterranean climate, affects transformation of organic P alone and in combination with fertilizer P has been given attention. This preliminary pot experiment, conducted under outdoor conditions, examined changes in sodium bicarbonate (NaHCO₃)‐extractable P over a 19‐month period in soil amended with organic matter as farmyard manure (5%) and superphosphate (100 mg/kg P). During the initial cool winter season's incubation, there was no change in available P. With the onset of the warmer dry season, NaHCO₃‐extractable P declined rapidly. The rate of decrease was greater, and the onset earlier with inorganic P alone. Organic matter reduced the P Sorption maxima and increased desorption. Thus, organic matter, whether added or as accumulated root biomass, enhances the longevity and potential plant availability of P in soils of a xeric moisture regime. Future field research should focus on monitoring, with time, the various organic and inorganic P fractions as well as detailed moisture and temperature measurements.