Chemical speciation and fate of tripolyphosphate after application to a calcareous soil
Tóm tắt
Adsorption and precipitation reactions often dictate the availability of phosphorus in soil environments. Tripolyphosphate (TPP) is considered a form of slow release P fertilizer in P limited soils, however, investigations of the chemical fate of TPP in soils are limited. It has been proposed that TPP rapidly hydrolyzes in the soil solution before adsorbing or precipitating with soil surfaces, but in model systems, TPP also adsorbs rapidly onto mineral surfaces. To study the adsorption behavior of TPP in calcareous soils, a short-term (48 h) TPP spike was performed under laboratory conditions. To determine the fate of TPP under field conditions, two different liquid TPP amendments were applied to a P limited subsurface field site via an in-ground injection system. Phosphorus speciation was assessed using X-ray absorption spectroscopy, total and labile extractable P, and X-ray diffraction. Adsorption of TPP to soil mineral surfaces was rapid (< 48 h) and persisted without fully hydrolyzing to ortho-P. Linear combination fitting of XAS data indicated that the distribution of adsorbed P was highest (~ 30–40%) throughout the site after the first TPP amendment application (high water volume and low TPP concentrations). In contrast, lower water volumes with more concentrated TPP resulted in lower relative fractions of adsorbed P (15–25%), but a significant increase in total P concentrations (~ 3000 mg P kg soil) and adsorbed P (60%) directly adjacent to the injection system. This demonstrates that TPP application increases the adsorbed P fraction of calcareous soils through rapid adsorption reactions with soil mineral surfaces.
Tài liệu tham khảo
Dick R, Tabatabai M (1986) Hydrolysis of polyphosphates by corn roots. Soil Sci 142(3):132–140
Kulakovskaya TV, Vagabov VM, Kulaev IS (2012) Inorganic polyphosphate in industry, agriculture and medicine: modern state and outlook. Process Biochem 47(1):1–10
McBeath TM, Lombi E, McLaughlin MJ, Bünemann EK (2007) Polyphosphate-fertilizer solution stability with time, temperature, and pH. J Plant Nutr Soil Sci 170(3):387–391
Khasawneh FE, Hashimoto I, Sample EC (1979) Reactions of ammonium ortho- and polyphosphate fertilisers in soil: III. Effects of associated cations. Soil Sci Soc Am J 43:58–65
Blanchar RW, Hossner LR (1969) Hydrolysis and sorption of ortho-, pryo-, tripoly-, and trimetaphosphate in 32 midwestern soils. Soil Sci Soc Am J 33(4):622–625
Torres-Dorante LO, Claassen N, Steingrobe B, Olfs HW (2005) Hydrolysis rates of inorganic polyphosphates in aqueous solution as well as in soils and effects on P availability. J Plant Nutr Soil Sci 168(3):352–358
Hamilton JG, Hilger D, Peak D (2017) Mechanisms of tripolyphosphate adsorption and hydrolysis on goethite. J Colloid Interface Sci 491:190–198
Guan XH, Liu Q, Chen GH, Shang C (2005) Surface complexation of condensed phosphate to aluminum hydroxide: an ATR-FTIR spectroscopic investigation. J Colloid Interface Sci 289(2):319–327
Guan XH, Chen GH, Shang C (2007) Adsorption behavior of condensed phosphate on aluminum hydroxide. J Environ Sci 19(3):312–318
Gong W (2001) A real time in situ ATR-FTIR spectroscopic study of linear phosphate adsorption on titania surfaces. Int J Miner Process 63(3):147–165
Michelmore A, Gong W, Jenkins P, Ralston J (2000) The interaction of linear polyphosphates with titanium dioxide surfaces. Phys Chem Chem Phys 2(13):2985–2992
Jansson M, Olsson H, Pettersson K (1988) Phosphatases; origin, characteristics and function in lakes. Hydrobiologia 170(1):157–175
Tarafdar JC, Jungk A (1987) Phosphatase activity in the rhizosphere and its relation to the depletion of soil organic phosphorus. Biol Fertil Soils 3:199–204
Journal AI, Volume PF (2001) The acquisition of phosphorus by plants. Int J 28
Torres-Dorante LO, Claasen N, Steingrobe B, Olfs HW (2005) Hydrolysis rates of inorganic polyphosphates in aqueous solution as well as in soils and effects on P availability. J Plant Nutr Soil Sci 168(3):352–358
Racz GJ, Savant NK (1972) Pyrophosphate hydrolysis in soil as influenced by flooding and fixation. Soil Sci Soc Am J 36:678
Chang C, Racz JG (1977) Effects of temperature and phosphate concentration on rate of sodium pyrophosphate and sodium tripolyphosphate hydrolysis in soil. Can J Soil Sci 57:1278
Zinder B, Hertz J, Oswald H (1984) Kinetic studies on the hydrolysis of sodium tripolyphosphate in sterile solution. Water Res 18(5):509–512
Kizewski F, Liu Y-T, Morris A, Hesterberg D (2011) Spectroscopic approaches for phosphorus speciation in soils and other environmental systems. J Environ Qual 40(3):751–766
Peak D, Sims JT, Sparks DL (2002) Solid-state speciation of natural and alum-amended poultry litter using XANES spectroscopy. Environ Sci Technol 36(20):4253–4261
Cao X, Harris W (2008) Carbonate and magnesium interactive effect on calcium phosphate precipitation. Environ Sci Technol 42(2):436–442
Tunesi S, Poggi V, Gessa C, Scienze UCI, Agroindustriali T, Agraria C (1999) Phosphate adsorption and precipitation in calcareous soils: the role of calcium ions in solution and carbonate minerals. Nutr Cycl Agroecosystems 53:219–227
Raynaud S, Champion E, Bernache-Assollant D, Thomas P (2002) Calcium phosphate apatites with variable Ca/P atomic ratio I. Synthesis, characterisation and thermal stability of powders. Biomaterials 23(4):1065–1072
Hesterberg D (2010) Macroscale chemical properties and X-ray absorption spectroscopy of soil phosphorus. Dev Soil Sci 34:313–356
Cao X, Harris WG, Josan MS, Nair VD (2007) Inhibition of calcium phosphate precipitation under environmentally-relevant conditions. Sci Total Environ 383(1–3):205–215
Liu J, Hu Y, Yang J, Abdi D, Cade-menun BJ (2015) Investigation of soil legacy phosphorus transformation in long- term agricultural fields using sequential fractionation, P K‑edge XANES and solution P NMR spectroscopy
Prietzel J, Harrington G, Hausler W, Heister K, Werner F, Klysubun W (2016) Reference spectra of important adsorbed organic and inorganic phosphate binding forms for soil P speciation using synchrotron-based K-edge XANES spectroscopy. J Synchrotron Radiat 23(2):532–544
Ajiboye B, Akinremi OO, Jürgensen A (2007) Experimental validation of quantitative XANES analysis for phosphorus speciation. Soil Sci Soc Am J 71(4):1288
Siciliano SD, Chen T, Phillips CL, Hamilton JG, Hilger DM, Chartrand B et al (2016) Total phosphate influences the rate of hydrocarbon degradation but phosphate mineralogy shapes microbial community composition in cold-region calcareous soils. Environ Sci Technol 50:5197–5206
Werner F, Prietzel J (2015) Standard protocol and quality assessment of soil phosphorus speciation by P K-edge XANES spectroscopy. Environ Sci Technol 49(17):10521–10528
Peak D, Kar G, Hundal L, Schoenau J (2012) Kinetics and mechanisms of phosphorus release in a soil amended with biosolids or inorganic fertilizer. Soil Sci 177(3):183–187
Hilger DM, Hamilton JG, Peak D (2017) XANES investigation of the influence of magnesium in the formation of calcium phosphate minerals. Unpublished
Ravel B, Newville M, ATHENA, ARTEMIS, HEPHAESTUS (2005) Data analysis for X-ray absorption spectroscopy using IFEFFIT. J Synchrotron Radiat 12(4):537–541 (International Union of Crystallography)
Toby BH, Von Dreele RB (2013) GSAS-II: the genesis of a modern open-source all purpose crystallography software package. J Appl Crystallogr 46(2):544–549
Toby BH (2001) EXPGUI, a graphical user interface for GSAS. J Appl Crystallogr 34(2):210–213
Kar G, Hundal LS, Schoenau JJ, Peak D (2011) Direct chemical speciation of P in sequential chemical extraction residues using P K-edge X-ray absorption near-edge structure spectroscopy. Soil Sci 176(11):589–595
Nachtegaal M, Marcus MA, Sonke JE, Vangronsveld J, Livi KJT, van Der Lelie D et al (2005) Effects of in situ remediation on the speciation and bioavailability of zinc in a smelter contaminated soil. Geochim Cosmochim Acta 69(19):4649–4664
Jacquat O, Voegelin A, Kretzschmar R (2009) Soil properties controlling Zn speciation and fractionation in contaminated soils. Geochim Cosmochim Acta 73(18):5256–5272
Hamilton JG, Farrell RE, Chen N, Feng R, Reid J, Peak D (2016) Characterizing zinc speciation in soils from a smelter-affected Boreal Forest ecosystem. J Environ Qual 45(2):684–692
George TS, Simpson RJ, Hadobas PA, Marshall DJ, Richardson AE (2007) Accumulation and phosphatase-lability of organic phosphorus in fertilised pasture soils. Aust J Agric Res 58(1):47–55