Changes in Phosphorus Fractions in Soils under Intensive Plant Growth

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DIVISION S-4-SOIL FERTILITY & PLANT NUTRITION

Changes in Phosphorus Fractions in Soils under Intensive Plant Growth

F. Guo, R.S. Yost, N.V. Hue, C.I. Evensen and J.A. Silva

Dep. of Tropical Plant and Soil Science, Univ. of Hawaii, 1910 East West Rd., Honolulu, HI 96822 USA

rsyost{at}hawaii.edu

ABSTRACT

TOP
NOTES
ABSTRACT
INTRODUCTION
Materials and methods
Results and discussion
Conclusions
REFERENCES

The total quantity of P and plant-available P often differ greatlyin soils of the tropics, which typically range in weatheringintensity. Assessing available P is fundamental to managingP in many of these soils. Phosphorus availability in some soilshas been inferred from the Hedley sequential extraction assumingthat each P fraction reflects similar plant availability indifferent soils. However, experimental measurements of plantP availability were either of short duration or involved multipleP applications, which complicates assessment of the plant availabilityof P fractions. The objectives of this study were to examinethe changes in P fractions under exhaustive cropping on diversesoils and to discern the differences in plant availability amongP fractions. Eight soils ranging in weathering from Vertisolsand Mollisols to Ultisols and Oxisols were amended with Ca(H₂PO₄)·H₂Oto raise soil solution P to 0.2 mg L^-1 and planted for 14 cropsto remove available P. The results indicated that the Fe-impregnatedstrip–P and inorganic NaHCO₃–P (NaHCO₃–P_i)decreased the most in response to plant P withdrawal in allsoils. The inorganic NaOH-P (NaOH-P_i) also declined with plantP uptake in all soils. The HCl-P and residual P seemed to actas a buffer for the strip-P and the NaHCO₃–P_i in the slightlyweathered soils, whereas NaOH-P_i seemed to act as a bufferingpool for strip-P and NaHCO₃–P_i in the highly weatheredsoils. Residual P in the slightly weathered soils was plant-availableon a relatively short time scale. In contrast, residual P inthe highly weathered soils accumulated in the presence of intensiveplant P removal, indicating that it was unavailable to plants.Organic P (NaHCO₃- and NaOH-P_o) fractions were not significantcontributors to available P in these soils that received highlevels of inorganic P. Phosphorus fractions separated by thesame sequential method were not of equal availability to plantsin all soils.

Abbreviations: DAE, days after emergence • i (subscript), inorganic • o (subscript), organic • T (subscript), total

INTRODUCTION

TOP
NOTES
ABSTRACT
INTRODUCTION
Materials and methods
Results and discussion
Conclusions
REFERENCES

THE COMPLEX CHEMISTRY and spatial variability of P in soilsmake direct identification of P compounds and assessment ofplant availability difficult (Hsu, 1965; Sawhney, 1973; Webber,1978; Pierzynski et al., 1990a, 1990b, 1990c). The Hedley fractionationmethod has been widely used to characterize soil P availability.The procedure, in its original (Hedley et al., 1982) or modifiedforms (Tiessen et al., 1983, 1984; Sharpley et al., 1987; Tiessenand Moir, 1993; Beck and Sanchez, 1994), removes the readilyavailable P from the soil first with mild extractants, thenthe more stable P forms with stronger extractants. The basicassumption of the procedure is that extractants of varying strengthestimate P fractions of differing availability (Hedley et al., 1982),and that a specific fraction is of similar availabilityin different soils. This assumption needs to be verified inorder to improve P management models such as the PDSS2 (PhosphorusDecision Support System; Yost et al., 1992).

Soil P was fractionated by the original Hedley procedure intoeight fractions, which included a microbial P fraction usingchloroform and dilute NaHCO₃ (pH 8.5). Although Hedley et al. (1982)indicated that microbial P may be estimated in theirMollisol (Udic Haploboroll) with an empirical recovery factor(Hedley et al., 1982), a later study suggested that Hedley'soriginal scheme underestimated microbial P in tropical soilswhen soils are allowed to dry (Potter et al., 1991). MicrobialP is highly variable and one of the smaller fractions in mostsoils. Thus, many later procedures omitted the chloroform-bicarbonateextraction for estimating microbial P, and only seven fractionswere estimated (Tiessen et al., 1983, 1984; Tiessen and Moir,1993; Beck and Sanchez, 1994; Schmidt et al., 1996).

The Hedley procedure has been used to study P fractions in bothslightly weathered (Hedley et al., 1982; Tiessen et al., 1983;O'Halloran et al., 1987; Richards et al., 1995) and highly weatheredsoils (Ball-Coelho et al., 1993; Agbenin and Tiessen, 1994;Beck and Sanchez, 1994; Schmidt et al., 1996). Phosphorus fractionchanges due to organic amendments have also been reported (Hedleyet al., 1982; Iyamuremye et al., 1996; Leinweber, 1996). Mostauthors seemed to agree that the P extracted by the anion exchangeresin or Fe-impregnated strips and the NaHCO₃–P_i are plantavailable. However, the availability of the other fractionsis less certain. Various interpretations, reflecting tremendousuncertainty in the availability of these fractions, suggestedby different authors have been summarized by Cross and Schlesinger (1995).The focus of previous work was on measuring P fractionsunder different P treatments or cultural practices; less attentionwas given to the dynamic changes of P fractions during an extendedperiod of time. A few recent studies measured P fraction changesunder extended plant P removal (Ball-Coelho et al., 1993; Beckand Sanchez, 1994; Richards et al., 1995; Schmidt et al., 1996),but changes of P fractions were masked by repeated P additions,which resulted in a complex storing and removal of P fractionsand in altered patterns of P fraction change that complicateassigning P availability on the basis of plant P removal. Hypothesestested were (i) that the soil P continuum could be separatedinto discrete fractions of differing availability and (ii) thatthe availability of the fractions would be consistent in soilsof differing degrees of weathering. Therefore, the objectivesof this study were to examine the changes in P fractions underexhaustive cropping on diverse soils and to compare the plantavailability of the Hedley P fractions in eight soils underintensive plant growth.

Materials and methods

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NOTES
ABSTRACT
INTRODUCTION
Materials and methods
Results and discussion
Conclusions
REFERENCES

Soil Characterization
Eight soils, representing a wide range in weathering (Tables 1–3)and P sorption (Table 4) , were sampled from 0to 15 cm in depth except for the Kapaa soil, for which bothsurface and subsurface horizons were sampled and mixed. Thesoil samples were composited from three subsamples. The soilswere ground to pass a 0.84-mm sieve, and the following measurementswere taken: pH in 1:1 soil/water suspension, organic C (Nelson and Sommers, 1982),particle size (Gee and Bauder, 1986), andcalcium carbonates (Nelson, 1982). Water content at -0.03 and-1.5 MPa was measured using pressure plates by presoaking thesoil materials in water overnight. Soil available water capacitywas calculated as the difference between the matrix potentialsof -0.03 and -1.5 MPa. Clay mineral contents were estimatedby the Rietveld refinement using the SIROQUANT computer program(Sietronics Pty. Ltd., 1993). X-ray amorphous content of theclay was determined by the Rietveld refinement method in thesame manner as in measuring minerals after spiking the claywith alumina powder (Jones et al., 2000).

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Table 1 Taxonomy and selected physical properties of the soils used in this study

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Table 2 Selected chemical properties of the soils used in this study

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Table 3 Mineralogical composition of soil clay (<2 µm) fraction of the soils used in this study

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Table 4 Phosphorus application rates for the greenhouse experiment

Soil Incubation
Soils were air-dried and ground to pass a 4-mm sieve using amechanical grinder. Acidic soils were limed to pH 6.5 by addinglaboratory-grade, powdered CaCO₃. After liming, the soils weremoistened to their available water capacity (soil water betweenmatrix potential of -0.03 and -1.5 MPa) and incubated for 4wk in plastic bags. Five-kilogram (dry basis) portions of eachsoil were weighed onto clean brown paper. The prescribed amountof P as Ca(H₂PO₄)₂·H₂O (Table 4) was thoroughly mixedwith the soil. The treated soils were then placed into plasticpots (18 cm in diameter, 30 cm deep), and watered weekly withdeionized water to available water capacity and allowed to dryduring the week in the greenhouse for 4 wk. At 60 d after Papplication, 50 mg N kg^-1 as urea, 60 mg K kg^-1 as KCl, 25 mgkg^-1 Mg as MgSO₄·7H₂O, and 5 mg kg^-1 Zn as ZnSO₄·7H₂O,were added into each pot and mixed. The experimental designwas a randomized complete block with three replicates of eachsoil.

Soil Fractionation
Soil samples were sequentially extracted for P using a modifiedHedley procedure. Triplicate 0.5000-g samples were weighed into40-mL screw-capped centrifuge tubes, and 30.0 mL of extractantwere added and the tubes were shaken for 45 min of each hourfor 16 h. The extractants, in sequential order, were: (i) 30mL of deionized water and one 2 by 10 cm Fe-impregnated stripas prepared according to Guo et al. (1996), (ii) 0.5 M NaHCO₃at pH 8.5, (iii) 0.1 M NaOH. (iv) 1 M HCl, and (v) 5.0 mL ofconcentrated H₂SO₄ ( ${approx}$ 18 M) and 2 to 3 mL of H₂O₂ (300 g kg^-1)in 0.5-mL increments. Inorganic P (P_i) in the extracts was determinedby the method of Murphy and Riley (1962) after pH adjustmentusing nitrophenol as an indicator. Total P (P_T) was also measuredin both the NaHCO₃ and the NaOH extracts for calculating organicP (P_o). P_T was determined with the Murphy and Riley (1962) methodafter autoclave digestion to convert P_o to P_i with acid ammoniumperoxysulfate as described in the Standard Methods (AmericanPublic Health Association, American Water Works Association,and Water Environment Federation, 1995). Organic P was calculatedas the difference between P_T and P_i in the extracts. Total soilP was determined by the Na₂CO₃ fusion method (Olsen and Sommers, 1982).

Cropping
Corn (Zea mays L.) was grown for Crops 1 to 10, 13, and 14.Crops 11 and 12 were soybean [Glycine max (L.) Merr.]. Whencorn was grown, each pot received 12 pregerminated corn seeds(Hybrid X304CF15, Pioneer Hi-Bred Int., Johnston, IA), whichwere placed ${approx}$ 1 to 2 cm below the soil surface. At 3 d after emergence(DAE), each pot was thinned to 10 seedlings. Two additionaldoses of N at 50 mg kg^-1 were applied at 10 and 20 DAE. Plantswere grown for 4 wk. For the two soybean crops, five healthy,noninoculated, and presoaked seeds were placed 1 to 2 cm belowthe soil surface in each pot, and thinned to three seedlingsin each pot 3 DAE. Nitrogen was applied at 56 mg kg^-1 and equallysplit between 0 and 15 DAE. Boron (as sodium borate) and molybdenum(as ammonium molybdate) were applied both at 0.9 mg kg^-1 inthe first soybean crop. Other supplemental nutrients were addedin amounts similar to those of corn. Soybean plants were grownfor 45 d. The pots were watered daily with deionized H₂O, andmoisture was maintained near soil available water capacity throughoutthe growth period.

A 2-g soil sample was taken from each pot after Harvests 2,4, 6, 8, 10, 12, and 14. Roots were removed, and samples weredried and ground to pass a 0.25-mm sieve for sequential extraction.

F protected Fisher's LSDs at were calculated at each harvest with SAS for Windows, version 6.11, using thePROC MEANS statement (SAS Institute, 1996).

Results and discussion

TOP
NOTES
ABSTRACT
INTRODUCTION
Materials and methods
Results and discussion
Conclusions
REFERENCES

The eight soils were divided into three groups according totheir P sorption capacity (Table 4): (i) low P sorption soilsthat are slightly weathered alkaline soils (Table 2) with layersilicates as their dominant mineralogy (Table 3), (ii) mediumP sorption soils that are acidic soils (Table 2) with a mixtureof layer silicates and Fe and Al oxides, and (iii) high P sorptionsoils having very low pH and Fe and Al oxides as their dominantmineralogy (Tables 2 and 3). The sequential extraction methodseparates soil P into four inorganic, two organic, and a residualfraction that is perhaps a mixture of both inorganic and organicP.

Strip-Phosphorus and Inorganic NaHCO₃–Phosphorus
Neither the strips nor the 0.5 M NaHCO₃ solution sharply altersthe soil, and their extraction power better mimics the extractionpower of plant roots than other reagents used during fractionation.Estimated P from these two extractants was highly correlatedwith plant P uptake in previous studies (Bowman et al., 1978;van der Zee et al., 1987; Menon et al., 1989; Sharpley, 1991).The strip-P and the NaHCO₃–P_i are thus usually assumedto be plant available (Mattingly, 1975; Hedley et al., 1982;Tiessen et al., 1984; Cross and Schlesinger, 1995). The strip-Pand the NaHCO₃–P_i in our soils were purposely elevatedby adding a large dose of P to allow for extended cropping andalso represent soils with high P buildup. Both strip-P and NaHCO₃–P_ideclined with cropping in all soils, but the slopes of declinewere different between strip-P and NaHCO₃–P_i for the samesoil, and among soils with either extractant (Fig.1) . The declinein strip-P and NaHCO₃–P_i in the three slightly weatheredsoils (Fig. 1a and 1d) appeared to follow the same pattern,although the magnitude of decline was significantly differentin the Nohili as compared with the other two soils, suggestingthat strips and NaHCO₃ measured a similar P fraction in thesesoils (Fig. 1). The decline of strip-P and NaHCO₃–P_i inthe highly weathered soils (Fig. 1b, 1c, 1e, and 1f) was differentfrom that in the slightly weathered soils. Under intensive plantgrowth, strip-P in the highly weathered soils demonstrated aninitial fast decline followed by a slower gradual decline (Fig. 1).The fast initial decline was not observed in the slightlyweathered soils. The Paaloa and the Wahiawa soils had identicalP sorption capacity (both requiring 500 mg kg^-1 to attain 0.2mg P L^-1 solution P), but the Wahiawa soil contained significantlymore strip-P and NaHCO₃–P_i than the Paaloa soil (Fig. 1b and 1e).Mineralogical analysis indicated that the Paaloahad higher goethite and hematite content and fewer secondarylayer silicates than the Wahiawa soil (Table 3). The paralleldecline curves of the Paaloa and the Wahiawa soils seemed tosuggest that both the strip-P and the NaHCO₃–P_i in thesetwo soils responded similarly to plant-available P removal.Among the three high P sorption soils (Fig. 1c and 1f), thedecrease in both strip-P and NaHCO₃–P_i was similar tothat of the Paaloa and the Wahiawa (Fig. 1). Both the strip-Pand NaHCO₃–P_i were significantly different among the threesoils after all harvests (Fig. 1c and 1f), with the Leilehuasoil having the highest combined strip-P and NaHCO₃–P_i,and the Kapaa soil having the least. The strips and the NaHCO₃extracted similar fractions in the three high P sorption soils(Fig. 1c and 1f). In all soils, both strip-P and NaHCO₃–P_iappeared to strongly reflect plant P removal.

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Fig. 1 Changes in inorganic strip- and NaHCO₃–P in eight soils under exhaustive cropping. Phosphorus was added in each soil to raise soil solution P to 0.2 mg L^-1. Honouliuli, Lualualei, and Nohili were considered low P sorption soils and Paaloa and Wahiawa were medium P sorption soils, while the Kapaa, Leilehua, and Mahana soils were characterized by high P sorption

Inorganic Hydroxide-Extractable Phosphorus
The P_i extracted by 0.1 M NaOH is considered as P associatedwith Fe and Al (Hedley et al., 1982; Tiessen et al., 1984; Wageret al., 1986) through chemisorption to surfaces of Fe and Alcomponents (Ryden et al., 1977; McLaughlin et al., 1977). Williams et al. (1971)indicated that some Ca-P may also be extractedby NaOH. Although long-term measurements of its decline arerarely made, NaOH-P_i is often assumed to be moderately available(Hedley et al., 1982, Schmidt et al., 1996; Ivarsson, 1990).Changes of NaOH-P_i during the growth of the 14 crops are summarizedin Fig. 2 . Significant differences were found among soils ofsimilar P sorption capacities (Fig. 2). In the slightly weatheredsoils (Fig. 2a), NaOH-P_i seemed to be associated with soil Feoxides. The Nohili soil had the lowest content of Fe oxidesand the least NaOH-P_i (Fig. 2a, Table 3). In the highly weatheredsoils (Fig. 2b and 2c), the amount of NaOH-P_i within each groupseemed to be the opposite in ranking the soils with respectto the strip-P or the NaHCO₃–P_i. The Wahiawa soil containedmore strip-P and NaHCO₃–P_i, but lower NaOH-P_i than thePaaloa soil. Among the three high P sorption soils (Fig. 2c),the Leilehua had the highest strip-P and NaHCO₃–P_i, butits NaOH-P_i was the lowest. The NaOH-P_i in the highly weatheredsoils was directly related to the soil amorphous content andto the sum of Fe oxides (Table 3). Inorganic NaOH-P was nota static fraction in any of the soils. Instead, it declinedunder cropping (Fig. 2). In the highly weathered soils (Fig. 2b and 2c),readily available soil P (strip-P and NaHCO₃–P_i)and NaOH-P_i appeared to be in equilibrium. When readily availableP in soils was high, NaOH-P_i seemed to accumulate in soils withhigh Fe and Al oxides, as indicated by the increases in NaOH-P_ifor the first two harvests (Fig. 2, Table 3). When strip-P andNaHCO₃–P_i began to level off (Fig. 1 and 2), NaOH-P_i startedto decline at a faster rate than in previous harvests (Fig. 2).Although NaOH-P_i may not be as available as strip-P or NaHCO₃–P_i,there is no clear-cut separation between NaHCO₃- and NaOH-P_i.

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Fig. 2 Changes in NaOH-P_i in eight soils under exhaustive cropping. Phosphorus was added in each soil to raise soil solution P to 0.2 mg L^-1. Honouliuli, Lualualei, and Nohili were considered low P sorption soils and Paaloa and Wahiawa were medium P sorption soils, while the Kapaa, Leilehua, and Mahana soils were characterized by high P sorption

Organic Phosphorus
The NaHCO₃- and NaOH-P_o are usually estimated by the Hedleyprocedure. Although Hedley's procedure was found useful in characterizingthe availability of soil P_o (Tiessen and Moir, 1993), the contributionof P_o to plant P absorption relative to P_i fractions in P-amendedsoils remains to be determined. Changes of P_o due to the 14exhaustive crops grown in the eight soils were observed (Fig. 3). When P was added to raise soil solution P to 0.2 mg L^-1,the highly weathered soils (Fig. 3b and 3c) contained more NaHCO₃–P_othan the slightly weathered soils (Fig. 3a). This was consistentwith the findings of Cross and Schlesinger (1995), who foundthat within the labile P fraction (strip-P and NaHCO₃–P_i),the percentage held in organic form (NaHCO₃–P_o) increasedwith soil weathering. Significant differences in NaHCO₃–P_owere found in soils within each P sorption group for some harvestsbut not in others, indicating that this fraction fluctuatedamong harvests (Fig. 3). The NaOH-P_o fraction was greater thanthe NaHCO₃–P_o fraction in all soils (Fig. 3). The NaOH-P_oalso seemed to be higher in the highly weathered soils (Fig. 3e and 3f)than in the slightly weathered soils (Fig. 3d), exceptin the Honouliuli soil, which was the most weathered among thethree slightly weathered soils, as indicated by the absenceof smectite and the presence of high hematite content (Table 3).The Wahiawa soil generally contained significantly higherNaOH-P_o than the Paaloa soil, but the trend seemed to be reversedafter Harvest 10. Among the three high P sorption soils, theKapaa soil contained the most NaOH-P_o, while NaOH-P_o in theLeilehua and the Mahana soils was indistinguishable and fluctuated(Fig. 3). Neither NaHCO₃- nor NaOH-P_o appeared to change withplant P removal; they fluctuated irregularly. These fluctuationsmay be due to differences in microbial activities among harvests,or perhaps soil preparation before analysis (Potter et al., 1991).However, when soil available P was greatly depleted bycropping, NaHCO₃–P_o appeared to decline with subsequentcrop P withdrawal. This was indicated by the decline in NaHCO₃–P_oof the Paaloa, Wahiawa, Kapaa, and the Mahana soils after Harvest10 (Fig. 3). However, no such decline was observed for the NaOH-P_oin those soils. We conclude that P_o was not a significant contributorto soil available P when available P_i was high. When soil P_iwas low, such as in the Paaloa and Wahiawa soils after Harvest10, NaHCO₃–P_o began to contribute to available P. Beck and Sanchez (1994)found that P_o did not significantly contributeto plant-available P_i in their Ultisol that received repeatedP applications. They suggested that P_i was the major P sourcefor plant growth. In a study involving a toposequence of Lithosolsand Cambisols from semiarid northeastern Brazil where nativesoil P was high, Agbenin and Tiessen (1994) also demonstratedthat only 5% of the total P was in organic forms, mostly instable forms of low availability with little contribution toP fertility. Organic P may be important in P fertility in unfertilizedsoils or soils with high organic matter, but it does not appearto affect P availability significantly in high-P mineral soils.

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Fig. 3 Changes in organic P in eight soils under exhaustive cropping. Phosphorus was added in each soil to raise soil solution P to 0.2 mg L^-1. Honouliuli, Lualualei, and Nohili were considered low P sorption soils and Paaloa and Wahiawa were medium P sorption soils, while the Kapaa, Leilehua, and Mahana soils were characterized by high P sorption

Dilute Hydrochloric Acid Extractable Phosphorus
The HCl-P is thought to represent primary mineral P such asapatite (Williams et al., 1980; Tiessen et al., 1984; Tiessenand Moir, 1993) since the Fe- or Al-P that remains unextractedafter the NaOH extraction is not soluble in acid (Tiessen and Moir, 1993).The HCl-P is generally assumed to be of low availabilityto plants, although it was found to decrease in greenhouse studies(Ivarsson, 1990) and in long-term field trials (McKenzie et al., 1992a).McKenzie et al. (1992b) also reported that HCl-Pwas increased by fertilizer-P during long-term crop production.However, O'Halloran et al. (1987) observed that P applicationhad no effect on HCl-P in a Brazilian Ultisol (Oxic Haplustult).Laboratory incubation results indicated that HCl-P in the highlyweathered soils treated with high P was negligible (Fig. 4c) .Changes of HCl-P under exhaustive cropping in soils indicated,as expected, that the slightly weathered soils (Fig. 4a) hadhigh HCl-P, and the highly weathered soils had little (Fig. 4b and 4c),despite the fact that much higher amounts of P wereadded to the highly weathered soils (1400 mg P kg^-1) than tothe slightly weathered soils (100 mg P kg^-1; Table 4). Amongthe three slightly weathered soils (Fig. 4a), the Lualualeisoil had the most HCl-P, probably because the soil had the highestcalcite content (Table 3), followed by the Nohili soil. TheHonouliuli soil, which contained no calcite, had the least HCl-P.The HCl-P in the Honouliuli soil may be due to its high exchangeableCa²⁺ content. The HCl-P declined under exhaustive cropping,especially in the Lualualei soil, which had very high HCl-P(Fig. 4a). This suggested that Ca-P formed with added P wasplant available even when available P in soils was high. Inthe five highly weathered soils, HCl-P was generally <10mg kg^-1 (Fig. 4b and 4c), probably due to the absence of Ca-containingminerals and their low exchangeable Ca²⁺ (data not shown). Thedetected HCl-P increase in the highly weathered soils afterHarvest 10 (Fig. 4b and 4c) was attributable to Ca-P formedwith lime, because prior to planting Crop 11, soils were retestedfor pH and additional CaCO₃ was added to correct the acidity.Beck and Sanchez (1994) also observed a rapid increase in Ca-P(HCl-P) coinciding with the change in lime source from fastreacting Ca(OH)₂ to slower reacting CaCO₃ in a Paleudult. Theyfound that the Ca-P associated with liming and fertilizer Pwas among the least stable P compounds in their soil. The subsequentdrop in HCl-P after Crop 12 observed in our highly weatheredsoils (Fig. 4b and 4c) agreed with their findings. In the slightlyweathered soils (Fig. 4a), the decline in HCl-P may be causedby the conversion from HCl-P to readily available P (strip-Pand NaHCO₃–P_i). The HCl-P may act as a buffer for theavailable P in the slightly weathered soils similar to the apparentbuffering by NaOH-P_i in the highly weathered soils.

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Fig. 4 Changes in HCl-P in eight soils under exhaustive cropping. Phosphorus was added in each soil to raise soil solution P to 0.2 mg L^-1. Honouliuli, Lualualei, and Nohili were considered low P sorption soils, Paaloa and Wahiawa were medium P sorption soils, while the Kapaa, Leilehua, and Mahana soils were characterized by high P sorption

Residual Phosphorus Fraction
Changes in residual P under cropping showed two contrastingpatterns (Fig. 5) . Residual P declined with exhaustive croppingin the three slightly weathered soils (Fig. 5a), but seemedto build up gradually in the highly weathered soils (Fig. 5b and 5c).The slopes of increase were significant at P < 0.05.The decline in residual P in slightly weathered soils has beenreported in soils similar to ours (Hedley et al., 1982; McKenzieet al., 1992a, 1992b). Higher residual P was observed in theslightly weathered soils than in the highly weathered soilswhen the same amount of P was added. We postulated that someresidual P in the slightly weathered soils was Ca-P, which wasnot removed because all extractants prior to the 1 M HCl solutionwere alkaline. However, this Ca-P may act as a buffer for readilyavailable P. When the readily available P is withdrawn, Ca-Pin the residual fraction may be mobilized to replenish the availableP. This may explain the gradual decline in residual P in thethree slightly weathered soils (Fig. 5a). This explanation wasfurther strengthened by the relatively faster decline of theresidual P in the Lualualei soil (Fig. 5a), which has a highercalcite content and thus probably more Ca-P.

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Fig. 5 Changes in residual P in eight soils under exhaustive cropping. Phosphorus was added in each soil to raise soil solution P to 0.2 mg L^-1. Honouliuli, Lualualei, and Nohili were considered low P sorption soils and Paaloa and Wahiawa were medium P sorption soils, while the Kapaa, Leilehua, and Mahana soils were characterized by high P sorption

However, in the highly weathered soils, the residual P fractionnot only failed to decrease during plant P withdrawal, but itcontinued to increase with time (Fig. 5b and 5c). Similar resultshave not been reported. Previous experiments either lacked thetime required to observe the change or were complicated by repeatedP applications. However, a lack of accumulation in the residualP fraction has been reported by Beck and Sanchez (1994) on aPaleudult. Their Ultisol, nonetheless, was not a typical highlyweathered soil. It had low P sorption capacity and needed only24 mg P kg^-1 to raise solution P to 0.2 mg L^-1. In addition,the clay fraction of that soil contained 90% layer silicatesand 10% Fe and Al oxides (Beck and Sanchez, 1994). The "slowreaction"(Barrow, 1980) in Beck and Sanchez's soil may be negligible,and conversion of available P to residual P may not be a majorprocess. In contrast, the mineralogy of our highly weatheredsoils was dominated by high P-affinitive Fe and Al oxides andamorphous materials (Table 3). Therefore, the continued buildupin residual P in the highly weathered soils was not surprising.

Conclusions

TOP
NOTES
ABSTRACT
INTRODUCTION
Materials and methods
Results and discussion
Conclusions
REFERENCES

The results indicated that strip-P and NaHCO₃–P_i weremost sensitive to plant P withdrawal in all soils. The NaOH-P_ialso declined with plant P removal in all soils. The HCl-P andresidual P in the slightly weathered soils declined under croppingand were major P fractions in the slightly weathered soils possiblyacting as a buffer for the strip-P and NaHCO₃–P_i in thesesoils. The NaOH-P_i was the dominant P fraction in the highlyweathered soils, and declined in response to plant P removal.The NaOH-P_i and strip-P and NaHCO₃–P_i appeared to be inequilibrium. When strip-P and NaHCO₃–P_i were high, NaOH-P_iaccumulated or remained stable despite plant P removal; whenstrip-P and NaHCO₃–P_i were reduced by plant removal, NaOH-P_idecreased, and then further declines in strip-P and NaHCO₃–P_ioccurred. The NaOH-P_i appeared to act as a buffer for strip-Pand NaHCO₃–P_i in the highly weathered soils. In the slightlyweathered soils, residual P declined in response to plant Premoval, suggesting that in such soils residual P may containplant-available P. In contrast, residual P in the highly weatheredsoils accumulated with plant P removal, suggesting that it wasunavailable to plants. Organic P was not critical to P availabilityin our soils that received high P inputs. The same P fraction,therefore, differed in availability in different soils.AmericanPublic Health Association 1995; Guo Yost Jones 1996; SietronicsPty 1993

ACKNOWLEDGMENTS

We gratefully acknowledge the Soil Management CollaborativeResearch Support Program of the US Agency for InternationalDevelopment for partial support of this work under Grant no.DAN-1311-G-00-1049-00.

NOTES

TOP
NOTES
ABSTRACT
INTRODUCTION
Materials and methods
Results and discussion
Conclusions
REFERENCES

Journal Series no. 4470, Hawaii Institute for Tropical Agricultureand Human Resources.

Received for publication December 20, 1998.

REFERENCES

TOP
NOTES
ABSTRACT
INTRODUCTION
Materials and methods
Results and discussion
Conclusions
REFERENCES

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