Environmental risk indicators for soil phosphorus status

Biologically available phosphorus (P) is divided operationally into two sources, dissolved reactive P (DRP) and bioavailable particulate P (BPP). Dilute CaCl2-extractable soil P (CaCl2-P) is considered to be the benchmark method for estimating DRP in soils, whereas P desorbed to iron-oxide impregnated filter paper (FeO-P) is the benchmark method for BPP in soils and sediments. Neither of these methods is in routine use in Australia. Selected soil P analyses were carried out on 31 diverse surface soils to develop relationships between the environmental benchmark methods and the routine soil P tests of Colwell-P, Olsen-P, and the single-point P buffer index (PBI). The index (Colwell-P/PBI) was highly correlated with CaCl2-P (r = 0.925, P < 0.001), and both Olsen-P and Colwell-P were highly correlated with FeO-P (r = 0.955 and 0.828, respectively; P < 0.001). It is suggested that these measures can be used as environmental risk indicators for soil P status. The critical values of these measures for optimum productivity were compared to the values of these measures corresponding to threshold values of currently used environmental risk indicators.

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Soil phosphorus and relationship to phosphorus balance under long-term fertilization

Plant Soil and Environment ◽

10.17221/709/2017-pse ◽

2018 ◽

Vol 64 (No. 5) ◽

pp. 214-220 ◽

Cited By ~ 3

Author(s):

Sun Benhua ◽

Cui Quanhong ◽

Guo Yun ◽

Yang Xueyun ◽

Zhang Shulan ◽

...

Keyword(s):

Inorganic Nitrogen ◽

Soil Phosphorus ◽

Organic Fertilizers ◽

Available Phosphorus ◽

Soil P ◽

Olsen P ◽

P Fertilizer ◽

P Balance ◽

Activation Coefficient ◽

Phosphorus And Potassium

Temporal changes in the concentrations of plant-available phosphorus (P) in soil (Olsen-P), total soil-P and P activation coefficient (the ratio of Olsen-P to residual-P (i.e. an approximation to total-P)) were measured in plots that received consistent inorganic nitrogen, phosphorus and potassium plus organic fertilizers annually. Maize and winter wheat crops were grown in rotation for 24 years. Olsen-P and P activation coefficient declined significantly in the earlier years (< 12 years) for treatments that did not include any P fertilizer, and increased over the same period for the P-fertilized treatments. The rates of change in the Olsen-P and P activation coefficient values were positively related to P balance. In the later years, the Olsen-P and P activation coefficient plateau values were positively related to the P balance.

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Response by sugar beet to superphosphate, particularly in relation to soils containing little available phosphorus

The Journal of Agricultural Science ◽

10.1017/s0021859600065138 ◽

1976 ◽

Vol 86 (1) ◽

pp. 181-187 ◽

Cited By ~ 1

Author(s):

A. P. Draycott ◽

M. J. Durrant

Keyword(s):

Sugar Beet ◽

Soil Phosphorus ◽

Maximum Yield ◽

P Uptake ◽

Available Phosphorus ◽

Triple Superphosphate ◽

Phosphorus Fertilizer ◽

Average Yield ◽

Soil P ◽

The Cost

SUMMARYTwenty experiments between 1970 and 1974 tested the effect of five amounts of triple superphosphate (0–110 kg P/ha) on sugar-beet yield in fields where soil contained little sodium bicarbonate-soluble phosphorus. The average yield without phosphorus fertilizer was 6·69 t/ha sugar and the increase from the optimum dressing 0·46 t/ha; the average soil concentration was 12 mg P/l. The fertilizer increased yield by 0·77 t/ha sugar on fields with 0–9 mg/l soil phosphorus, by 0·31 t/ha when soil phosphorus was 10–15 mg/l and had little effect on soils containing larger amounts.The concentration of phosphorus in plants harvested in mid-summer contained on average 0·29% P in dried tops and 0·13% in roots when given no phosphorus fertilizer, representing a total of 19·3 kg/ha P uptake. Giving superphosphate increased the phosphorus in both dried tops and roots by up to 0·03% and there was 3·7 and 1·7 kg/ha more phosphorus in tops and roots respectively. On the most responsive fields (0–9 mg/l soil P), the fertilizer increased the phosphorus in tops and roots by 0·05% and total uptake by 7 kg P/ha. The increase in uptake (or recovery) of fertilizer varied from 15% when 14 kg P/ha was given to less than 5% when 110 kg P/ha was used.A dressing of 27 kg P/ha was adequate for maximum yield on 19 of the 20 fields. When fields were grouped, 0–9, 10–15, 16–25 and > 26 mg/l NaHCO3-soluble soil phosphorus, and taking into account the value of the increased sugar yield, the cost of the fertilizer and its residual value, 60, 30, 20 and 10 kg P/ha respectively were the most profitable dressings. These experiments provide evidence, however, that the fertilizer would be used more efficiently if fields containing 0–9 mg soil phosphorus were subdivided into those with 0–4·5 and those with 4·6–9·0 mg/l and the groups given 80 and 40 kg P/ha respectively. These recommendations are substantially less than those used at present; they are adequate for sugar beet but other crops in the rotation would need similar close examination to ensure maximum yield and maintain adequate soil reserves of phosphorus.

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Interpretation of a single-point P buffering index for adjusting critical levels of the Colwell soil P test

Soil Research ◽

10.1071/sr06056 ◽

2007 ◽

Vol 45 (1) ◽

pp. 55 ◽

Cited By ~ 70

Author(s):

P. W. Moody

Keyword(s):

Buffer Capacity ◽

Soil Phosphorus ◽

Single Point ◽

Maximum Yield ◽

P Value ◽

P Availability ◽

Soil P ◽

P Concentration ◽

Soil P Test ◽

Rate Of Increase

Soil phosphorus (P) buffer capacity is the change in the quantity of sorbed P required per unit change in solution P concentration. Because P availability to crops is mainly determined by solution P concentration, as P buffer capacity increases, so does the quantity of P required to maintain a solution P concentration that is adequate for crop demand. Bicarbonate-extractable P using the Colwell method is the most common soil P test used in Australia, and Colwell-P can be considered to estimate P quantity. Therefore, as P buffer capacity increases, the Colwell-P concentration required for maximum yield also increases. Data from several published and unpublished studies are used to derive relationships between the ‘critical’ Colwell-P value (Colwell-P at 90% maximum yield) and the single-point P buffer index (PBI) for annual medics, soybean, potato, wheat, and temperate pasture. The rate of increase in critical Colwell-P with increasing PBI increases in the order: temperate pasture < medics < wheat < potato. Indicative critical Colwell-P values are given for the 5 crops at each of the PBI categories used to describe soil P buffer capacity as it increases from extremely low to very high.

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Comparison of Mehlich 3, AL and artificial root exudates containing extractants for soil phosphorus analysis

10.5194/egusphere-egu2020-20904 ◽

2020 ◽

Author(s):

Tonu Tonutare ◽

Gert Kaldmae ◽

Tiina Köster ◽

Kadri Krebstein ◽

Ako Rodima

Keyword(s):

Root Exudates ◽

Soil Phosphorus ◽

Extraction Methods ◽

Solution Chemistry ◽

Soil Science ◽

Available Phosphorus ◽

Plant Analysis ◽

Soil P ◽

Fertilizer Recommendations

Due to increase of fertilizers prices and tightening of environmental protection requirements the need for efficient use of fertilizers has increased. At moment over the word huge number of different methods for determination of soil plant available phosphorus (PAP) are in use. Due to unequal extraction ability of extractants have each method own specific gradation to evaluate the soil P class. Allmost all widely used PAP extraction methods are developed in last century, mostly more than fifty years ago and often there is not possible to found information how the P status classes and fertilizer recommendations are determined for each method is determined.The content of PAP in soil is difficult to estimate because soil pH has a strong effect to soil&#160; - solution chemistry. Therefore extracting&#160; soils with higly buffered solutions as for example Mehlich 3 can give overestimated results. The acidic Mehlich&#160; 3 extactant can solubilize relatively insoluble Ca- Fe- and Al phosphates. Also the AL (acetate-lactate) method uses the buffered extraction solution and may influence the amount of extracted PAP. The most realistic conditions for PAP extraction can give the extraction solution which mimic the soil environment that has actively growing roots.&#160;The aim of our research was to investigate the extraction of PAP with extragent similar by chemical composition to soil solution with root exudates proposed by Haney et al (2010).&#160; The obtained results were compared with Mehlich 3 and AL methods results.&#160; &#160;&#160;Ref.: Haney, R.L., Haney, E.B., Hossner, L.R., Arnold, J,G. 2010. Modification to the New Soil Extractant H3A-1: A Multinutrient Extractant. Communications in Soil Science and Plant Analysis, 41:1513-1523.

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Responses of herbage yield and soil phosphorus fractions to phosphorus fertilisation on a degraded arid steppe

Crop and Pasture Science ◽

10.1071/cp18217 ◽

2018 ◽

Vol 69 (8) ◽

pp. 846 ◽

Cited By ~ 1

Author(s):

Dangjun Wang ◽

Zhibin He ◽

Zhen Zhang ◽

Qingfeng Du ◽

Yong Zhang ◽

...

Keyword(s):

Soil Phosphorus ◽

Pot Experiment ◽

Available Phosphorus ◽

P Availability ◽

Organic P ◽

Soil P ◽

Sheep Manure ◽

Arid Steppe ◽

Plant Yields ◽

Phosphorus Fertilisation

Low plant-available phosphorus (P) in degraded arid steppes greatly limits plant yields. However, whether exterior P addition will improve the soil P availability and thus increase plant yield in these degraded arid steppes is still not certain. In the current study, a severely degraded arid steppe in Inner Mongolia, China, with soil-available P <5 mg/kg, was fertilised annually with chemical or manure P for two years (2014, dry year; 2015, wet year). There were six fertilisation treatments: 0, 30 kg P/ha, 60 kg P/ha, 90 kg P/ha, 4000 kg sheep manure/ha (equalling 16.4 kg P/ha) and 8000 kg sheep manure/ha (32.8 kg P/ha). A pot experiment with Stipa krylovii (the dominant plant species in the tested steppe) and five P application rates (0, 30, 60, 90 and 120 kg P/ha) was also conducted, under well-watered and nitrogen-fertilised conditions, using surface soils from unfertilised plots in the field. Results indicated that the tested soils had strong P adsorption capacity and weaker desorption capacity, and that the labile P fractions were quickly transformed into less labile fractions, reducing P availabilities. Overall, chemical P fertiliser resulted in the accumulation of Ca10-P and occluded P, whereas sheep manure resulted in the accumulation of moderately resistant organic P and highly resistant organic P. Phosphorus fertilisation was associated with an increase in plant P concentrations in both 2014 and 2015, and a low P rate (30 kg P/ha in the current study) was able to improve the aboveground biomass in both the field experiment in the wet year and the pot experiment under well-watered conditions. Thus, in degraded arid steppes, P fertilisation may be unnecessary in dry years. A low rate of P fertilisation is recommended in wet years to improve soil P status and steppe plant productivity.

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Depletion, accumulation and availability of soil phosphorus in the Askov long-term field experiment

Soil Research ◽

10.1071/sr19203 ◽

2020 ◽

Vol 58 (2) ◽

pp. 117 ◽

Cited By ~ 1

Author(s):

Musibau O. Azeez ◽

Gitte Holton Rubæk ◽

Ingeborg Frøsig Pedersen ◽

Bent T. Christensen

Keyword(s):

Rock Phosphate ◽

Soil Phosphorus ◽

Available P ◽

Soil P ◽

Olsen P ◽

Extractable P ◽

P Application ◽

Plant Available P ◽

Water Extractable

Soil phosphorus (P) reserves, built up over decades of intensive agriculture, may account for most of the crop P uptake, provided adequate supply of other plant nutrients. Whether crops grown on soils with reduced supply of other nutrients obtain similar use-efficiency of soil P reserves remains unclear. In treatments of the Askov Long-Term Experiment (initiated in 1894 on light sandy loam), we quantified changes in soil total P and in plant-available P (Olsen P, water extractable P and P offtake in wheat grains) when P-depleted soil started receiving P in rock phosphate and when P application to soil with moderate P levels ceased during 1997–2017. Additionally we studied treatments with soil kept unfertilised for >100 years and with soil first being P depleted and then exposed to surplus dressings of P, nitrogen (N) and potassium in cattle manure. For soil kept unfertilised for >100 years, average grain P offtake was 6 kg ha–1 and Olsen P averaged 4.6 mg kg–1, representing the lower asymptotic level of plant-available P. Adding igneous rock phosphate to severely P-depleted soil with no N fertilisation had little effect on Olsen P, water extractable P (Pw), grain yields and P offtake. For soils with moderate levels of available P, withholding P application for 20 years reduced contents of Olsen P by 56% (from 16 to 7 mg P kg–1) and of Pw by 63% (from 4.5 to 1.7 mg P kg–1). However, the level of plant-available P was still above that of unfertilised soil. Application of animal manure to P-depleted soil gradually raised soil P availability, grain yield and P offtake, but it took 20 years to restore levels of plant-available P. Our study suggests symmetry between rates of depletion and accumulation of plant-available P in soil.

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Comparison of bicarbonate-extractable soil phosphorus measured by ICP-AES and colourimetry in soils of south-eastern New South Wales

Soil Research ◽

10.1071/sr09034 ◽

2009 ◽

Vol 47 (7) ◽

pp. 742 ◽

Cited By ~ 7

Author(s):

M. R. Hart ◽

P. S. Cornish

Keyword(s):

Inductively Coupled Plasma ◽

New South ◽

Soil Phosphorus ◽

New South Wales ◽

Soil Samples ◽

Available Phosphorus ◽

Soil P ◽

Inductively Coupled ◽

South Wales ◽

The Difference

Soil testing for plant-available phosphorus (P) in Australia is most commonly conducted using alkaline sodium bicarbonate extraction (Olsen or Colwell tests), followed by a colourimetric assay to measure the concentration of P in solution. Analysis by inductively coupled plasma (ICP) spectroscopy has become increasingly popular internationally for other soil P tests, especially Mehlich 3, due to its efficiency and ability to measure multiple elements in the one extract. The use of ICP in place of colourimetry has been used in some Australian laboratories for bicarbonate-extractable P. However, the method is known to measure forms of P (organic) that are not measured by the colourimetric assay. This study presents data comparing soil Colwell P measured by the 2 methods for 714 soil samples from pastoral sites in south-east New South Wales. Measurement by ICP consistently yielded significantly higher P concentrations than the colourimetric method (ICP-P = 1.122Col-P + 57.0, r2 = 0.95, P < 0.001). Differences between the 2 techniques were more marked in 0–20 mm than 0–100 mm depth soil samples, and in soils with greater clay contents, suggesting that the difference was related to soil organic matter, and thereby organic P contents. Relative differences were greatest in soils with lower P concentrations, i.e. within the agronomic optimum range of most interest to farmers. ICP analysis cannot be directly correlated with colourimetrically measured P in bicarbonate extracts, and would need to be developed and calibrated as a separate, new soil P test.

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Changes in soil phosphorus availability and potential phosphorus loss following cessation of phosphorus fertiliser inputs

Soil Research ◽

10.1071/sr13168 ◽

2013 ◽

Vol 51 (5) ◽

pp. 427 ◽

Cited By ~ 12

Author(s):

R. J. Dodd ◽

R. W. McDowell ◽

L. M. Condron

Keyword(s):

Agricultural Soils ◽

Soil Phosphorus ◽

Pasture Production ◽

Soil P ◽

Olsen P ◽

P Loss ◽

P Concentration ◽

Rate Of Decline ◽

P Retention

Long-term application of phosphorus (P) fertilisers to agricultural soils can lead to in the accumulation of P in soil. Determining the rate of decline in soil P following the cessation of P fertiliser inputs is critical to evaluating the potential for reducing P loss to surface waters. The aim of this study was to use isotope exchange kinetics to investigate the rate of decline in soil P pools and the distribution of P within these pools in grazed grassland soils following a halt to P fertiliser application. Soils were sourced from three long-term grassland trials in New Zealand, two of which were managed as sheep-grazed pasture and one where the grass was regularly cut and removed. There was no significant change in total soil P over the duration of each trial between any of the treatments, although there was a significant decrease in total inorganic P on two of the sites accompanied by an increase in the organic P pool, suggesting that over time P was becoming occluded within organic matter, reducing the plant availability. An equation was generated using the soil-P concentration exchangeable within 1 min (E1 min) and P retention of the soil to predict the time it would take for the water-extractable P (WEP) concentration to decline to a target value protective of water quality. This was compared with a similar equation generated in the previous study, which used the initial Olsen-P concentration and P retention as a predictor. The use of E1 min in place of Olsen-P did not greatly improve the fit of the model, and we suggest that the use of Olsen-P is sufficient to predict the rate of decline in WEP. Conversely, pasture production data, available for one of the trial sites, suggest that E1 min may be a better predictor of dry matter yield than Olsen-P.

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EFFECT OF AVAILABLE SOIL PHOSPHORUS ON YIELDS AND RESPONSE OF BRUSSELS SPROUTS TO FERTILIZER PHOSPHORUS IN THE FIELD

Canadian Journal of Plant Science ◽

10.4141/cjps71-023 ◽

1971 ◽

Vol 51 (2) ◽

pp. 109-114 ◽

Cited By ~ 1

Author(s):

D. C. MUNRO ◽

J. A. CUTCLIFFE

Keyword(s):

Phosphorus Deficiency ◽

Soil Phosphorus ◽

Leaf Tissue ◽

Control Plot ◽

Brussels Sprouts ◽

Soil P ◽

Available Soil Phosphorus ◽

Highly Correlated ◽

Total P ◽

Tissue Phosphorus

The Morgan method, of the four methods studied, gave the best indication of availability of soil phosphorus for Brussels sprouts (Brassica oleracea var. gemmifera DC, Jade Cross). Control plot yields were highly correlated with available soil phosphorus by the Morgan method (r = 0.55, [Formula: see text]) and increased by about 1.3 metric tons of sprouts/ha for each 1 ppm increase in available soil phosphorus. Maximum yields were obtained by the application of 117 kg P/ha on soils testing less than 1.5 ppm P. No response to applied phosphorus occurred at soil-P levels greater than 5.0 ppm. Leaf-tissue phosphorus concentrations generally increased with increasing rates of applied phosphorus. Tissue phosphorus concentrations of control plot leaf samples were not related to control plot yields, but were significantly related to available soil phosphorus. Phosphorus deficiency was indicated when leaf tissue from unfertilized plants contained less than 0.35% total P, but some responses to applied phosphorus did occur when unfertilized plants contained up to 0.60% total P in the tissue.

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Estimating Soil Available Phosphorus Content through Coupled Wavelet–Data-Driven Models

Sustainability ◽

10.3390/su12052150 ◽

2020 ◽

Vol 12 (5) ◽

pp. 2150 ◽

Cited By ~ 1

Author(s):

Jalal Shiri ◽

Ali Keshavarzi ◽

Ozgur Kisi ◽

Sahar Mohsenzadeh Karimi ◽

Sepideh Karimi ◽

...

Keyword(s):

Gene Expression Programming ◽

Soil Phosphorus ◽

Clay Content ◽

The Other ◽

Data Driven ◽

Support Vector ◽

Available Phosphorus ◽

Discrete Wavelet ◽

Soil P ◽

Soil Available Phosphorus

Soil phosphorus (P) is a vital but limited element which is usually leached from the soil via the drainage process. Soil phosphorus as a soluble substance can be delivered through agricultural fields by runoff or soil loss. It is one of the most essential nutrients that affect the sustainability of crops as well as the energy transfer for living organisms. Therefore, an accurate simulation of soil phosphorus, which is considered as a point source pollutant in elevated contents, must be performed. Considering a crucial issue for a sustainable soil and water management, an effective soil phosphorus assessment in the current research was conducted with the aim of examining the capability of five different wavelet-based data-driven models: gene expression programming (GEP), neural networks (NN), random forest (RF), multivariate adaptive regression spline (MARS), and support vector machine (SVM) in modeling soil phosphorus (P). In order to achieve this goal, several parameters, including soil pH, organic carbon (OC), clay content, and soil P data, were collected from different regions of the Neyshabur plain, Khorasan-e-Razavi Province (Northeast Iran). First, a discrete wavelet transform (DWT) was applied to the pH, OC, and clay as the inputs and their subcomponents were utilized in the applied data-driven techniques. Statistical Gamma test was also used for identifying which effective soil parameter is able to influence soil P. The applied methods were assessed through 10-fold cross-validation scenarios. Our results demonstrated that the wavelet–GEP (WGEP) model outperformed the other models with respect to various validations, such as correlation coefficient (R), scatter index (SI), and Nash–Sutcliffe coefficient (NS) criteria. The GEP model improved the accuracy of the MARS, RF, SVM, and NN models with respect to SI-NS (By comparing the SI values of the GEP model with other models namely MARS, RF, SVM, and NN, the outputs of GEP showed more accuracy by 35%, 30%, 40%, 50%, respectively. Similarly, the results of the GEP outperformed the other models by 3.1%, 2.3%, 4.3%, and 7.6%, comparing their NS values.) by 35%-3.1%, 30%-2.3%, 40%-4.3%, and 50%-7.6%, respectively.

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