Appraisal of the Snap Model for Predicting Nitrogen Mineralization in Tropical Soils Under Eucalyptus

Smethurst, P. J.; Gonçalves, José Leonardo de Moraes; Pulito, Ana Paula; Gomes, Simone da Silva Ribeiro; Paul, Keryn I.; Álvares, Clayton Alcarde; Júnior, José Carlos Arthur

doi:10.1590/01000683rbcs20140379

Cited by 5 publications

(8 citation statements)

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“…The volume of rhizosphere soil is determined by root length and rhizosphere thickness (Finzi et al, 2015). As root length here was based on field measurements (Mello et al, 1998;Neves, 2000;Leles et al, 2001;Teixeira et al, 2002;Gatto et al, 2003;Maquere, 2008), greater remaining uncertainty about the volume of the rhizosphere would be related to its thickness. This, in turn, depends on the amount and nature of rhizosphere deposits and on the physical, chemical, and biological properties of the soil that limit the distribution of those deposits beyond the root surface (Finzi et al, 2015).…”

Section: Modeling Fine-root Growth and Rhizodepositionmentioning

confidence: 98%

“…In the logic of ForPRAN, rhizo- sphere volume is related to the length of fine roots and their diameter and also to the thickness of the rhizosphere. Root length is strongly related to shoot biomass as the source of stored and newly fixed C (Mello et al, 1998;Neves, 2000;Leles et al, 2001;Teixeira et al, 2002;Gatto et al, 2003;Maquere, 2008). Root length is also related to soil clay concentration in association with its effects on available water and nutrients.…”

Section: Rhizosphere Dimensionsmentioning

confidence: 99%

“…Root biomass and depth are estimated in 3-PG but not root length density of fine roots. To represent the growth of fine roots (including root length density), we used a nonlinear model fitted to the data of Mello et al (1998), Neves (2000), Leles et al (2001), Teixeira et al (2002), Gatto et al (2003), and Maquere (2008). Then the rate of C and N release processes from roots are calculated according to Personeni et al (2007) and Farrar et al (2003).…”

Section: Mathematical Model Overviewmentioning

confidence: 99%

“…Most of the parameters present in ForPRAN were based on values observed in previous studies. For instance, parameters used for modeling fine-root growth and rhizodeposition were based on several studies: Mello et al (1998), Neves (2000), Leles et al (2001), Teixeira et al (2002), Gatto et al (2003), Maquere (2008), and Personeni et al (2007). Other parameters used for simulating C and N cycling in rhizosphere soil were based mainly on the studies of Schimel and Wein-traub (2003), Allison et al (2010), and Drake et al (2013).…”

Section: Parameter Estimationmentioning

confidence: 99%

“…. (2001)Teixeira et al (2002) Mello et al (1998 Regression of fine-root biomass reported in the literature against values predicted using the ForPRAN model. The dotted line is the mean regression, with neither intercept nor slope significantly different from 0 or 1, respectively.…”

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Modeling rhizosphere carbon and nitrogen cycling in <i>Eucalyptus</i> plantation soil

et al. 2018

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Abstract. Vigorous Eucalyptus plantations produce 105 to 106 km ha−1 of fine roots that probably increase carbon (C) and nitrogen (N) cycling in rhizosphere soil. However, the quantitative importance of rhizosphere priming is still unknown for most ecosystems, including these plantations. Therefore, the objective of this work was to propose and evaluate a mechanistic model for the prediction of rhizosphere C and N cycling in Eucalyptus plantations. The potential importance of the priming effect was estimated for a typical Eucalyptus plantation in Brazil. The process-based model (ForPRAN – Forest Plantation Rhizosphere Available Nitrogen) predicts the change in rhizosphere C and N cycling resulting from root growth and consists of two modules: (1) fine-root growth and (2) C and N rhizosphere cycling. The model describes a series of soil biological processes: root growth, rhizodeposition, microbial uptake, enzymatic synthesis, depolymerization of soil organic matter, microbial respiration, N mineralization, N immobilization, microbial death, microbial emigration and immigration, and soil organic matter (SOM) formation. Model performance was quantitatively and qualitatively satisfactory when compared to observed data in the literature. Input variables with the most influence on rhizosphere N mineralization were (in order of decreasing importance) root diameter > rhizosphere thickness > soil temperature > clay concentration. The priming effect in a typical Eucalyptus plantation producing 42 m3 ha−1 yr−1 of shoot biomass, with assumed losses of 40 % of total N mineralized, was estimated to be 24.6 % of plantation N demand (shoot + roots + litter). The rhizosphere cycling model should be considered for adaptation to other forestry and agricultural production models where the inclusion of such processes offers the potential for improved model performance.

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Section: Modeling Fine-root Growth and Rhizodepositionmentioning

confidence: 98%

Section: Rhizosphere Dimensionsmentioning

confidence: 99%

Section: Mathematical Model Overviewmentioning

confidence: 99%

Section: Parameter Estimationmentioning

confidence: 99%

mentioning

confidence: 99%

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Modeling rhizosphere carbon and nitrogen cycling in <i>Eucalyptus</i> plantation soil

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Modelling soil nitrogen mineralisation in semi-mature pine stands of South Africa to identify nutritional limitations and to predict potential responses to fertilisation

Toit

Scheepers

2020

Annals of Forest Science

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& Key Message Estimates of available nitrogen (based on topsoil nitrogen mineralisation rates) in semi-mature stands of Pinus radiata (D Don.) as well as pure species and hybrids of Pinus elliottii (Engelm.) in South Africa display a strong, significant, negative relationship with growth response to applied fertilisers in field experiments. This inexpensive technique can be incorporated in a fertiliser decision support system to minimise wasteful fertiliser applications. & Context South African mid-rotation pine stands respond with high variability to nitrogen fertiliser supplements in the presence of phosphorus. & Aims We aimed to find a screening tool for stands that are responsive to fertilisation. & Methods The volume growth response relative to control plots (3 years after fertilisation with 200 kg ha −1 N in the presence of 100 kg ha −1 P) was determined across 14 pine fertiliser experiments in South Africa. These values were correlated to soil and other properties for each site and also to estimates of N availability and N mineralisation rates using the Soil Nitrogen Availability Predictor (SNAP) model. & Results The relative volume growth response to fertilisation ranged with a factor from 0.05 to 0.96. No single result from standard soil analyses showed a strong positive or negative correlation with this growth response. However, highly significant negative correlations were observed between an estimate of N availability based on topsoil aerobic nitrogen mineralisation rates and the relative volume growth responses to fertilisation. & Conclusion The estimate of N availability derived from incubation studies may assist us to predict the magnitude of the response to N fertilisation (in the presence of P) with a fair degree of accuracy. The accuracy can be improved if the N availability estimate from aerobic incubation is used with other variables (pH and soil C content) in a multivariate regression to predict relative yield response to fertilisation.

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Carbon and nitrogen dynamics in soil organic matter fractions following eucalypt afforestation in southern Brazilian grasslands (Pampas)

Santos

Oliveira

Ferreira

et al. 2020

Agriculture, Ecosystems & Environment

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Appraisal of the Snap Model for Predicting Nitrogen Mineralization in Tropical Soils Under Eucalyptus

Cited by 5 publications

References 34 publications

Modeling rhizosphere carbon and nitrogen cycling in <i>Eucalyptus</i> plantation soil

Modeling rhizosphere carbon and nitrogen cycling in <i>Eucalyptus</i> plantation soil

Modelling soil nitrogen mineralisation in semi-mature pine stands of South Africa to identify nutritional limitations and to predict potential responses to fertilisation

Carbon and nitrogen dynamics in soil organic matter fractions following eucalypt afforestation in southern Brazilian grasslands (Pampas)

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Appraisal of the Snap Model for Predicting Nitrogen Mineralization in Tropical Soils Under Eucalyptus

Cited by 5 publications

References 34 publications

Modeling rhizosphere carbon and nitrogen cycling in &lt;i&gt;Eucalyptus&lt;/i&gt; plantation soil

Modeling rhizosphere carbon and nitrogen cycling in &lt;i&gt;Eucalyptus&lt;/i&gt; plantation soil

Modelling soil nitrogen mineralisation in semi-mature pine stands of South Africa to identify nutritional limitations and to predict potential responses to fertilisation

Carbon and nitrogen dynamics in soil organic matter fractions following eucalypt afforestation in southern Brazilian grasslands (Pampas)

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Modeling rhizosphere carbon and nitrogen cycling in <i>Eucalyptus</i> plantation soil

Modeling rhizosphere carbon and nitrogen cycling in <i>Eucalyptus</i> plantation soil