Pesq. agropec. bras., Brasília, v.54, e00266, 2019
DOI: 10.1590/S1678-3921.pab2019.v54.00266

This is an open-access article distributed under the 
Creative Commons Attribution 4.0 International License

Juliano Corulli Corrêa(1 ) , 
Lauri Caetano Ródio(2), 
Amanda Zolet Rigo(3), 
Marco André Grohskopf(4) , 
Agostinho Rebellatto(2) and 
Álvaro Luiz Mafra(3)

(1) Embrapa Suínos e Aves, BR-153, Km 110, 
Caixa Postal 321, CEP 89715-899 
Concórdia, SC, Brazil.  
E-mail: juliano.correa@embrapa.br

(2) Instituto Federal Catarinense, SC-283, 
Km 08, no 1.481, CEP 89703-720 Concórdia, 
SC, Brazil.  
E-mail: lauri.rodio@ifc-concordia.edu.br, 
agostinho.rebelatto@ifc-concordia.edu.br

(3) Universidade do Estado de Santa Catarina, 
Avenida Luiz de Camões, no 2.090, 
CEP 88520-000 Lages, SC, Brazil.  
E-mail: amanda.z.rigo@gmail.com,  
alvaro.mafra@udesc.br

(4) Universidade Estadual Paulista, Rua José 
Barbosa de Barros, no 1.780,  
CEP 18160-307 Botucatu, SP, Brazil.  
E-mail: marcogrohskopf@gmail.com

 Corresponding author

Received
October 27, 2017

Accepted
March 20, 2019

How to cite
CORRêA, J.C.; RódIO, L.C.; RIGO, A.Z.; 
GROhSKOPF, M.A.; REBELLAttO, A.; 
MAFRA, Á.L. Carbon fractions and stock in 
response to solid and fluid organomineral 
fertilizers in highly fertile soils. Pesquisa 
Agropecuária Brasileira, v.54, e00266, 2019. 
dOI: https://doi.org/10.1590/S1678-3921.
pab2019.v54.00266.

ISSN 1678-3921
Journal homepage: www.embrapa.br/pab

For manuscript submission and journal contents, 
access: www.scielo.br/pab

Soil Science/ Original Article

Carbon fractions and stock 
in response to solid and fluid 
organomineral fertilizers 
in highly fertile soils
Abstract − The objective of this work was to evaluate the effect of the application 
of organomineral and mineral fertilizers to highly fertile soils on the carbon 
management index (CMI) and carbon fractions and stock. The experiment was 
carried out on an Oxisol and Inceptisol, under no-tillage, in three crop seasons. 
The treatments consisted of two organomineral fertilizers and of two mineral 
fertilizers in solid and fluid forms, besides a control without fertilization. The 
application of organomineral and mineral fertilizers, in solid and fluid forms, 
to the different soil classes with high fertility promoted changes in total organic 
carbon, particulate organic carbon, and carbon associated with minerals, as well 
as in carbon stocks and the CMI. In the treatments with fluid mineral fertilizer 
and solid organomineral fertilizer, such changes occurred only in the Inceptisol 
due to the lower degree of weathering of this soil. The higher values of the 
CMI, with the fluid mineral fertilizer in the Inceptisol, allow inferring on which 
would be the best management practice aiming at the increase and maintenance 
of carbon in the soil-plant system, based on the yield results of wheat, sorghum, 
and corn, which were similar to those obtained with the other fertilizers.

Index terms: fluid fertilizer, no-tillage, organomineral fertilizer.

Frações e estoque de carbono em resposta 
a fertilizantes organominerais sólido e fluido 
em solos com fertilidade construída
Resumo − O objetivo deste trabalho foi avaliar o efeito da aplicação de 
fertilizantes organominerais e minerais em solos com fertilidade construída 
sobre o índice de manejo de carbono (IMC) e as frações e o estoque de carbono. 
O experimento foi realizado em um Cambissolo e em um Nitossolo sob 
sistema plantio direto, por três anos agrícolas. Os tratamentos consistiram de 
dois fertilizantes organominerais e de dois fertilizantes minerais nas formas 
sólidas e fluídas, além do controle sem adubação. A aplicação de fertilizantes 
organominerais e minerais, nas formas sólidas e fluídas, às diferentes classes 
de solo com fertilidade construída, promoveu alterações no carbono orgânico 
total, particulado e associado aos minerais, bem como nos estoques de carbono 
e no IMC. Nos tratamentos com fertilizante mineral fluído e fertilizante 
organomineral sólido, houve alterações apenas no Cambissolo, em razão do 
menor grau de intemperização deste solo. Os maiores valores do IMC, com 
fertilizante mineral fluido no Cambissolo, permitem inferir sobre qual seria a 
melhor prática de manejo para o aumento e a manutenção de carbono no sistema 
solo-planta, justificada pelos resultados de produtividade de trigo, sorgo e 
milho, que foram semelhantes aos obtidos com os outros fertilizantes.

Termos para indexação: fertilizante fluido, plantio direto, fertilizante 
organomineral.

https://orcid.org/0000-0001-5517-5199
https://orcid.org/0000-0002-6962-3359
mailto:juliano.correa@embrapa.br
mailto:agostinho.rebelatto@ifc-concordia.edu.br
mailto:amanda.z.rigo@gmail.com
mailto:marcogrohskopf@gmail.com


2 J.C. Corrêa et al.

Pesq. agropec. bras., Brasília, v.54, e00266, 2019
DOI: 10.1590/S1678-3921.pab2019.v54.00266

Introduction

Soil organic matter (SOM) participates in various 
biological, chemical, and physical soil processes that 
determine the productive potential of the soil (Mafra et 
al., 2014). Organic carbon (OC) is the main constituent of 
SOM which is influenced by the soil class characteristics 
and soil management system (McCarthy et al., 2008), 
including the fertilization practice, with both inorganic 
and organic fertilizers (Corrêa et al., 2018a).

The choice of how, when, and at what dose fertilizers 
should be applied to soils allows of variations in the 
OC accumulation (Mafra et al., 2015). Criteria for the 
method of fertilization should therefore be adopted, in 
order to enable an increased OC, and a reduced OC 
decomposition rates in the soil (Sá et al., 2014). The 
application of fertilizers promotes changes in the OC 
fractions in the soil in medium and long-term tillage 
systems (Karhu et al., 2012), whereas, in short-term 
ones, such increases may or may not occur (Wu et al., 
2004; Šimon, 2008).

Methodologies for the evaluation of fertilizer 
efficiency on OC alteration in a short-term include the 
analysis of particulate organic carbon (POC), carbon 
associated with minerals (CAM), and subsequent 
calculation of the carbon management index (CMI) 
(Conceição et al., 2014; Mafra et al., 2015). 

Criteria supporting the clarification of this assertion 
consistently state that: POC is present for the shortest 
length of time in the soil, and it is characterized by labile 
carbon, being the first fraction to reflect changes in the 
C content in the soil (Conceição et al., 2013). CAM, 
meanwhile, is the fraction that interacts with mineral 
particle surfaces, forming clay-metal-humus complexes 
and representing the SOM in an advanced state of 
stability and greater recalcitrance (Christensen, 2001).

Among the parameters used to determine the soil 
quality, CMI allows of one to ascertain whether good 
fertilization practices increase the admission of OC in 
the system. CMI is a useful tool to subsidize information 
on the best soil management systems (Nicoloso et 
al., 2008), as it takes into account the lability, and the 
quantitative and qualitative characteristics of the SOM 
(Schiavo et al., 2011).

Changes in the fractions of carbon in the soil (POC 
and CAM) and, consequently, their quality (CMI) and 
stock depend on the quantity and quality of the fertilizer 
to be applied, which is intrinsically related to the soil 

class and production system used. The region of western 
Santa Catarina is characterized by clayey soils (Oxisol 
and Inceptisol) of high-aggregate stability, with high 
levels of nutrients as a result of the intense and frequent 
use of fertilizers (Correa et al., 2018b).

The knowledge about fractions and carbon stock in a 
no-tillage system, with the application of organomineral 
fertilizers, would allow of the recommendation of good 
practices for the type and physical form of the fertilizer, 
and dose, location, and timing of the application, 
focusing on the accumulation of OC in different sized 
aggregates in soils with constructed fertility.

The objective of this work was to evaluate the effect of 
the application of organomineral and mineral fertilizers 
to highly fertile soils on the carbon management index 
and carbon fractions and stock.

Materials and Methods

The experiment was carried out in field conditions, 
during the agricultural years of 2010/2011, 2011/2012, 
and 2012/2013, in the municipality of Concórdia 
(27º14'2"S and 52º1'40"W, at 569 m altitude), in the 
state of Santa Catarina, Brazil. The climate is humid 
subtropical (Cfa), according to the Köppen-Geiger’s 
classification, with an annual mean rainfall of over 
1,500 mm, which is well distributed throughout the 
year, and an annual mean temperature of 15°C. 

The soils of the experimental area were described as 
a Rhodic Kandiudox (Nitossolo Vermelho distroférrico) 
and a Lithic Distrochrept (Cambissolo Háplico Tb 
distroférrico léptico); their chemical and physical 
characteristics are presented in Table 1. Previously, 
the experimental areas of both soils had been farmed 
with commercial corn crops in the summer, and oat 
crops in the winter, from 1994 until 2009. During this 
period, two limings with 5 Mg ha-1 dolomitic limestone 
were applied and incorporated into the 0.0 to 0.2 m soil 
layer, and the area was fertilized with swine manure to 
supply 80 kg ha-1 N and about 2 Mg ha-1 C, always in 
the summer cultivations; these practices promoted the 
construction of the high fertility of these soils.

During the installation of the experiment, the 
topsoil vegetation was desiccated by the application 
of glyphosate herbicide (2,2 kg ha-1 a.i.), after which 
corn was sown in both soils, for which the agricultural 
practice was repeated with the same active principle 
and dose, always with 14-day lead time prior to the 



Carbon fractions and stock in response to organomineral fertilizers 3

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DOI: 10.1590/S1678-3921.pab2019.v54.00266

sowing of the summer crops of 2010/2011, 2011/2012 
and 2012/2013 and the winter crops of 2011, 2012, and 
2013 crop seasons.

The work was conducted in experiment groups in a 
randomized complete block design. Each soil class was 
considered as an individual experiment, involving five 
treatments of fertilizers and four replicates. Following 
individual analysis, each experiment were grouped for 
joint analysis, for which the effect of the fertilizers was 
tested by the mean square of fertilizer-soil interactions, 
and the latter effect was tested by the residual mean 
square of the joint analysis. 

The treatments consisted of one control without 
fertilizer, and four fertilizers, two of which were 
organomineral, and the other two were mineral fertilizers 
in solid and fluid form, all in the formulation 03-12-06. 
The solid mineral fertilizer (MS) was composed of urea, 
monoammonium phosphate (MAP) and potassium 
chloride (KC1); the solid organomineral (OS) fertilizer 
was formulated on a poultry litter basis supplemented 
with urea, KC1, and natural phosphorous from the 
municipality of Registro, in the state of São Paulo. The 

fluid mineral fertilizer (MF) was composed of water, 
urea, MAP, and KC1; and the fluid organomineral 
fertilizer (OF) was formulated on a pig slurry basis with 
added urea, MAP, and KC1. 

Pig slurry used to form the OF fertilizer was obtained 
from finishing swine, via collection from a biodigestor 
discharge tubing. The chemical properties of swine 
manure were determined according to Rice et al. (2012) 
(Table 2). The OS fertilizer consisted of poultry litter, 
collected after six batches,  composed of 20, 40, and 22 g 
kg-1 total N, P2O5, and K2O, respectively. For granulation, 
the poultry litter was micronized and received 0.5% 
manioc starch as an aggregation conditioner, and 0.5% 
calcium silicate to increase the hardness of the granule. 

The fertilizers were applied to the surface and, 
subsequently, they were incorporated manually into the 
corn and fodder sorghum crops to attain a 10 Mg ha-1 
grain yield, and 8 Mg ha-1 dry mass, respectively, as 
described by Silva et al. (2016). The N dose was defined 
at 150 kg ha-1, from which 50 kg N were applied to the 
base with the fertilizers under evaluation (mineral and 
organomineral), corresponding to an application of 

Table 1. Chemical properties and clay content at 0.0-0.2 m soil depths of the Rhodic Kandiudox (Oxisol) and Lithic 
Distrochrept (Inceptisol) of the selected area prior to installation of the experiment.

Soil Treatment Clay pH CO P K Ca Mg
(g dm-3) H2O (g dm-3) (mg dm-3) --------------(mmolc dm-3)------------

Inceptisol

Control (C) 690 5.7 24.5 66.9 8.3 73.8 30.3
Solid mineral (MS) 660 5.7 25.5 79.5 9.4 95.9 44.7

Solid organomineral (OS) 660 5.6 24.9 63.7 8.6 83.1 31.7
Fluid mineral (MF) 690 5.6 23.0 63.8 7.1 97.5 40.8

Fluid organomineral (OF) 690 5.8 24.7 78.5 7.4 99.1 42.5

Oxisol

Control (C) 700 5.4 25.4 83.0 8.7 64.0 32.0
Solid mineral (MS) 700 5.3 25.9 78.0 8.8 59.9 32.2

Solid organomineral (OS) 700 5.3 24.2 84.0 9.1 64.3 35.5
Fluid mineral (MF) 700 5.2 23.4 61.0 8.5 56.0 31.3

Fluid organomineral (OF) 700 5.3 25.4 89.7 8.3 61.8 34.2
(1)Determined as described by Tedesco et al. (1995). Means of four replicates.

Table 2. Chemical properties of swine manure used to develop the fluid organomineral fertilizer.

Sample Date N P K Cu Zn ST SS SD
-----------------------------------------------------------------(kg m-3)---------------------------------------------------------------

Manure 2010 7.2 1.7 3.2 0.02 0.12 88.0 21.3 66.6
Manure 2011 5.0 1.1 2.8 0.04 0.17 77.7 19.0 52.6
Manure 2012 2.1 1.3 1.1 0.04 0.12 70.0 19.0 51.3

ST, total solids; SS, suspended solids; and SD, dissolved solids. 



4 J.C. Corrêa et al.

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1,667 kg ha-1 of the 03-12-06 formulation, and 100 kg N 
with urea applied to the topsoil. The doses of P2O5 and 
K2O applied with the different fertilizers were 200 and 
100 kg ha-1, respectively. 

The choice of the 03-12-06 (N-P2O5-K2O) formula 
sought to add a greater P concentration to achieve a 
possible residual effect on the black oat and wheat crops, 
aiming to fertilize the production system both in the two 
years of corn/oat cultivations and the year of sorghum/
wheat cultivations.

High yield, early cycle single hybrids were used for 
the corn (Zea mays L.) cultivation, for which the DKB 
240 Yieldgard hybrid was used for the 2010/2011 crop 
season, and the Celeron LT hybrid for the 2011/2012 crop 
season, both of which are considered highly demanding 
for soil fertility. In the two black oat (Avena strigosa 
Schreb) plantations in the winters of 2011 and 2012, 
the common cultivar was used. In the 2012/2013 crop 
season, the fodder sorghum (Sorghum vulgare) cultivar 
BRS 802 was used in the summer period, and in the 
winter of 2013, the wheat (Triticum aestivum L.) cultivar 
BRS Parrudo was cultivated. 

In the three agricultural years, the corn and wheat 
grain yields were determined, as well as the shoot dry 
mass of oat and sorghum. Corn and wheat ears were 
harvested manually, from 2.0 m long rows, with a 
total harvested area per portion of 3.2 m2. A manual 
threshing, weighing, and drying of the grain were 
conducted subsequently, with a 13% moisture correction 
value considered for yield calculation. 

The yields of shoot dry matter of black oat and 
sorghum crops were determined by weighing of the 
plants harvested from three 0.25 m2 microportions 
per experiment unit, which were dried in a forced-
air circulation oven at 65°C until constant mass was 
achieved.

For the analyses of carbon in the soil, deformed 
samples were taken from 0.0–0.05, 0.05–0.1, 0.1–0.2 and 
0.0–0.2 m soil depths. OC levels were ascertained in two 
granulometric fractions corresponding to the particulate 
organic carbon (POC), characterized by particles with 
dimensions greater than 53 μm, and to organic carbon 
associated to minerals (CAM) characterized by particles 
with dimensions smaller than 53 μm, and stock in total 
organic carbon (TOC) fraction. 

POC was determined according to the method 
described by Cambardella & Elliot (1992), and CAM 
was estimated by the difference between TOC and POC. 

The TOC of the soil and of the particulate fraction was 
quantified by the Walkley-Black method, as described 
by Tedesco et al. (1995), after the samples had been 
dried at 60oC and ground with porcelain pestle and 
mortar. The stocks of the TOC fraction were estimated 
by the equivalent soil mass and layer method. 

The equivalent layer method takes into consideration 
the thickness of the layer, soil bulk density, reference 
soil-equivalent mass and soil mass of a treatment, which 
is taken as the basis for the calculation of the stock in 
all other treatments (Ellert & Bettany, 1995; Bayer et 
al., 2000). For the present study, the soil masses of the 
layers corresponding to the native vegetation, which 
represents the original condition of the soil, were 
considered as reference. To determine the soil bulk 
density, undeformed samples were collected in the same 
layers.

The effect of fertilizations on the OC forms was 
evaluated in a relative manner by calculating the carbon 
management index (CMI), represented by the formula: 
CMI = CSI × LI × 100, in which CSI stands for the 
carbon stock index, and LI, the lability index, calculated 
by the formulae: CSI = TOCtreatment/TOCnative vegetation; 
and LI = Ltreatment/Lnative vegetation, as described by Blair et 
al. (1995). The term L represents the SOM lability in 
the treatment (Ltreatment) in relation to the SOM of the 
reference system (Lnative vegetation). Lability is represented 
by the POC (Vieira et al., 2007).

Data were subjected to the homogeneity of variances 
and normality tests, the analysis of variance was 
performed by the F test, following an experimental group 
design. The treatment means were, then, compared by 
Tukey’s test, protected by the significance of a global 
F-test. A 5% probability was adopted as the rate of error 
for decision-making purposes. 

Results and Discussion

Little change occurred in the total organic carbon 
(TOC) content in the soil, as a result of the application of 
organomineral and mineral fertilizers in solid and fluid 
forms, in the Inceptisol and Oxisol with “constructed 
fertility” (highly fertile soils) (Table 3), except for 
the Inceptisol where the fluid mineral fertilizer (MF) 
increased the TOC content in comparison to the other 
treatments at 0.0–0.05 and 0.0–0.2 m soil depths.

In both experiments (Inceptisol and Oxisol), the 
highest TOC levels were found at the surface layer 0.0-



Carbon fractions and stock in response to organomineral fertilizers 5

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0.05 m (Table 3). These results can be explained by the 
no-tillage system adopted, which promotes a greater 
accumulation of TOC in the surface layers due to less 
turning of the soil (Andrade et al., 2012; Mafra et al., 
2014).

In the adjacent cross-section layers at 0.05–0.1 and 
0.1–0.2 m, both the Inceptisol and Oxisol showed no 
difference between treatments (Table 3). In soils with a 
long history of fertilizer application and, consequently, 
the construction of high-fertility of such soils, 
fertilization by organomineral and mineral fertilizers in 
solid and fluid forms did not enable further deep soil 
increases of TOC content. 

In soils with high fertility, a large proportion of 
the chemical and physical attributes are stable, and 
significant responses caused by the use of fertilizers can 
be difficult to perceive in the short- and medium terms, 
with the greatest responses expected in the long-term 
(Andrade et al., 2010; Costa et al., 2011; Corrêa et al., 
2018b). 

The total organic carbon stock (TOCs) followed the 
same behavior of the TOC content, with little change by 
virtue of the application of organomineral and mineral 
fertilizers in solid and fluid forms (Table 4). However, 
the MF and OS treatments were similar for these stocks, 
and showed – in the Inceptisol only – the highest values 
at 0.0–0.05 and 0.0–0.2 m soil depths. 

Applications of mineral fertilizers plus swine 
manure have proven to elevate the TOCs in soils with 
medium or low-fertility conditions, which allows of 

the characterization of a sustainable practice for soil 
fertility (Zhang et al., 2012; Mafra et al., 2015). Each 
soil has a TOC capacity limit that can be reached for the 
adoption of fertilizers and correctives, as they increase 
the mass yield of crop shoots and roots (Kätterer et al., 
2011; Quanyinga et al., 2014; Castro et al., 2015). 

For the particulate organic carbon (POC) fraction, a 
difference was observed in the Inceptisol only, at the 
0.05–0.10 m soil depths, where the MF treatment resulted 
in higher results than the other treatments (Table 5). 
There are similarity levels of POC content at the 0.1–0.2 
and 0.0–0.2 m soil depths in the Inceptisol and Oxisol, 
allow us to infer that fertilization by organomineral 
and mineral fertilizers in solid and fluid form for three 
years of the experiment. The significant POC response 
in the Inceptisol could be due to the conditions of better-
preserved clay minerals, thanks to the limited effects of 
weathering in this soil class, favouring the formation of 
the clay-metal-humus complex. 

In the conditions of this experiment, the POC 
contents of the treatments with fertilizers were lower 
than the reference levels of the native vegetation at 0.0-
0.20 m soil depths, which are 7.9 g kg-1 in both soils 
(Inceptisol and Oxisol). The disturbance caused to the 
soil as a result of agricultural activity brings about the 
reduction of different compartments of organic carbon, 
in comparison to the native vegetation, that is considered 
as a stable system (Sá et al., 2017).

POC is the organic carbon fraction with a low degree 
of humification, it is considered labile and readily 

Table 3. Total organic carbon contents in Rhodic Kandiudox (Oxisol) and Lithic Distrochrept (Inceptisol), in response to the 
application of mineral and organomineral fertilizers in solid (MS and OS) and fluid (MF and OF) forms.(1)

Soil Total organic carbon (TOC) (g kg -1) Pr>F
Control MF MS OF OS

0.0–0.05 m soil depths
Inceptisol 28±0.96c 38±0.66a 32±2.43bc 29±1.52c 33±0.96b 0.0004
Oxisol 32±1.40 34±0.97 35±1.47 33±0.89 32±1.85 0.46

0.05–0.1 m soil depths
Inceptisol 22±0.69 26±2.87 23±0.22 24±1.03 24±0.61 0.26
Oxisol 26±1.67 28±1.74 27±0.82 28±1.47 26±0.68 0.63

0.1–0.2 m soil depths
Inceptisol 22±1.16 23±0.68 22±0.12 21±0.80 24±0.91 0.27
Oxisol 24±1.97 24±1.21 23±0.73 23±0.34 24±1.21 0.94

0.0–0.2 m soil depths(2)

Inceptisol 24±1.91c 27±1.52a 25±1.66bc 24±1.44c 26±0.76ab 0.007
Oxisol 27±1.70 28±1.23 27±1.04 27±0.99 26±1.58 0.79

(1)Means followed by equal letters, uppercase represent the difference between soils and lowercase ones represent the difference between treatments, do 
not differ by the Student’s t-test, at 5% probability. Soil collection at 0.0–0.2 m soil depths was carried out separately from the other samples. 



6 J.C. Corrêa et al.

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influenced by management practices such as fertilization 
in the soil-plant system (Mafra et al., 2014), which 
characterizes it as a sensitive and effective indicator 
in the study of SOM dynamics (Conceição et al., 2013) 
and allows of the short-term effect of the management 
to be verified (Bayer et al., 2002). However, the only 
treatment to represent this modification was the MF in 
the Inceptisol, that shows an improved soil quality and 
supports its description as good farming practices.

For carbon contents associated to minerals (CAM), 
there was a change in both MF and OS fertilizers 
only in the Inceptisol, which showed higher MF 
at 0.0–0.5 m soil depth, and higher MF and OS at  
0.0–0.2 m soil depth (Table 2). CAM contents in both 
soils (Oxisol and Inceptisol), for all the treatments, were 
lower than the reference levels of the native vegetation, 
with 26.5 g kg-1 at 0.0–0.2 m depth, showing the CAM 
loss in this tillage system. 

Table 4. Total organic carbon stock in Rhodic Kandiudox (Oxisol) and Lithic Distrochrept (Inceptisol), in response to the 
application of mineral and organomineral fertilizers in solid (MS and OS) and fluid (MF and OF) forms(1).

Soil Total organic carbon stock (TOCs) (g kg -1) Pr>F
Control MF MS OF OS

0.0–0.05 m soil depth
Inceptisol 14.8±0.50c 20.0±0.35a 16.7±1.27b 12.5±0.48ab 17.6±0.37a 0.001
Oxisol 17.5±0.76 18.7±0.53 19.3±0.80 18.1±0.48 17.7±1.00 0.22

0.05–0.1 m soil depth
Inceptisol 11.1±0.35 13.4±1.45 11.8±0.11 12.2±0.52 12.1±0.31 0.14
Oxisol 13.5±0.85 14.3±0.89 13.5±0.42 14.4±0.75 13.1±0.35 0.59

0.1–0.2 m soil depth
Inceptisol 20.4±1.08 21.1±0.63 20.0±0.11 19.2±0.74 22.1±0.84 0.44
Oxisol 21.7±1.77 21.9±1.09 21.0±0.66 21.0±0.30 21.3±1.09 0.32

0.0–0.2 m soil depth(2)

Inceptisol 46.4±1.93Bc 54.4±1.66a 48.5±1.56bc 46.6±1.57bc 51.8±1.81ab 0.001
Oxisol 52.6±1.81A 54.9±1.79 53.8±1.71 53.5±1.49 52±1.93 0.21

(1)Means followed by equal letters, uppercase in the column (Control) and lowercase in the rows, do not differ by Tukey’s test, at 5% probability. (2)Stock 
values represent the calculation for equivalent mass of soil at 0.0–0.20 m depths.

Table 5. Particulate organic carbon content and particulate organic carbon stock, in Rhodic Kandiudox (Oxisol) and Lithic 
Distrochrept Distrochrept (Inceptisol), in response to the application of mineral and organomineral fertilizers in solid (MS 
and OS) and fluid (MF and OF) forms.(1)

Soil Particulate organic carbon (POC) (g kg -1) Pr>F
Control MF MS OF OS

0.0–0.05 m soil depth
Inceptisol 6.2±0.79A 6.9±0.88 5.6±0.28 4.7±0.75 6.1±0.48 0.17
Oxisol 4.1±0.32B 6.6±0.73 5.6±0.60 6.0±0.59 5.2±0.43 0.10

0.05–0.1 m soil depth
Inceptisol 2.4±0.19b 2.9±0.21a 2.4±0.4Bbc 2.3±0.33Bc 2.6±0.12b 0.26
Oxisol 2.6±0.06 3.0±0.19 3.0±0.16A 2.6±0.15A 2.9±0.17 0.32

0.1–0.2 m soil depth
Inceptisol 1.6±0.24 1.6±0.09 1.6±0.24 1.5±0.22 2.1±0.26 0.16
Oxisol 1.8±0.11 1.7±0.16 2.1±0.21 1.7±0.18 2.0±0.10 0.41

0.0–0.2 m soil depth(2)

Inceptisol 3.0±0.43 3.3±0.57 2.8±1.29 2.4±0.47 3.2±0.24 0.07
Oxisol 2.6±0.16 3.2±0.36 3.2±0.51 3.0±0.29 3.0±0.22 0.29

(1)Means followed by equal letters, uppercase in the columns and lowercase in the rows, do not differ by Tukey’s test, at 5% probability. (2)Soil collection 
at 0.0–0.2 m soil depths was carried out separately from the other samples.



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DOI: 10.1590/S1678-3921.pab2019.v54.00266

The reduced CAM of the treatments in comparison 
to the native vegetation is associated to the break of 
the aggregates in the cultivated areas, by which carbon 
was exposed to microbial action (Mafra et al., 2015), 
thus hindering the accumulation of organic carbon in 
the soil from the application of fertilizers and from the 
vegetable mass. 

Small changes in the CAM of treatments can be 
explained by the little alterations to which CAM 
is subjected, which result from different forms of 
management, as CAM stability is related to interaction 
with the mineral phase and with the physical protection 
inside the microaggregates of the soil (Bayer et al., 
2004). 

The effect of the fertilizers applied to the soil on 
CAM was similar to that found in the POC, with a 
greater significance in the surface layer of the Inceptisol 
(Table 6). POC is considered the best indication of the 
SOM quality, in comparison to CAM because of the 
short-term management alterations, as it due to it being 
less recalcitrant and complex. 

In the carbon management index (CMI) there were 
differences between the treatments only at 0.05-0.1 m 
soil depth, in the Inceptisol condition, for which the 
fertilization with MF and OS were greater than the 
other treatments (Table 7). These results are similar to 
those found in the POC for the same cross-section layer 
of Inceptisol (Table 5).

These CMI results for MF and OS, with values of 
52.1 and 42.8 g kg-1 for Inceptisol, allows us to infer that 
these fertilizers promote smaller C losses in comparison 
to the other treatments (Table 7). The CMI seems to 
be a useful information on the best soil management 
systems, as it integrates, in the same measurement, the 
variations that occur in the different SOM fractions 
(Nicoloso et al., 2008).

After three years of applying mineral and 
organomineral fertilizers in solid and fluid forms in 
Inceptisol and Oxisol, with “constructed fertility”, 
the CMI values were below 100 at all evaluated soil 
depths (Table 7). CMI values lower than 100 indicate 
detrimental practices to TOC maintenance (Blair & 
Crocker, 2000), since it represents changes in the OC 
stocks considered labile in the soil; however they indicate 
favorable management practices for the maintenance of 
soil organic matter (Schiavo et al., 2011). 

Both in Inceptisol and Oxisol, the fodder sorghum 
yield of shoot dry matter (DM) responded to mineral 
and organomineral fertilizers in solid and fluid forms 
(Table 8). In the Inceptisol, the treatments with OF and 
OS fertilizers were superior to the other treatments, and 
in the Oxisol, the DM yield with MF was superior.

For DM yield of black oat, there was a difference 
between the soils only in 2011, when the Oxisol values 
were greater than those of the Inceptisol (Table 8). In 
2011 and 2012 the highest-DM yield of oat occurred in 

Table 6. Organic carbon associated to minerals and organic carbon stock associated to minerals in Rhodic Kandiudox 
(Oxisol) and Lithic Distrochrept (Inceptisol), in response to the application of mineral and organomineral fertilizers in solid 
(MS and OS) and fluid (MF and OF) forms(1).

Soil
Organic carbon associated to minerals (CAM) (g kg -1) Pr>F

Control MF MS OF OS
0.0–0.05 m soil depth

Inceptisol 22±1.11c 30±1.55a 26±2.55b 26±1.12Bbc 27±0.61b 0.001
Oxisol 28±1.51 28±0.89 30±1.02 27±0.76 27±1.42 0.63

0.05–0.1 m soil depth
Inceptisol 20±0.85B 23±2.82 22±0.24 22±1.11 21±0.57 0.45
Oxisol 24±1.62A 25±1.89 24±0.91 25±1.59 23±0.58 0.63

0.1–0.2 m soil depth
Inceptisol 20±0.96 21±0.60 20±0.14 19±0.90 22±0.74 0.39
Oxisol 22±1.93 23±1.12 21±0.74 22±0.40 22±1.13 0.84

0.0–0.2 m soil depth(2)

Inceptisol 21±1.02c 24±1.88a 22±1.42bc 21±1.09bc 23±0.71ab 0.01
Oxisol 24±1.66 25±1.23 24±0.93 24±0.88 23±1.35 0.84

(1)Means followed by equal letters, uppercase in the column (Control) and lowercase in the rows, do not differ by Tukey’s test, at 5% probability. (2)Soil 
collection at 0.0–0.2 m soil depths was carried out separately from the other samples. 



8 J.C. Corrêa et al.

Pesq. agropec. bras., Brasília, v.54, e00266, 2019
DOI: 10.1590/S1678-3921.pab2019.v54.00266

the treatment with the OF fertilizer, which was superior 
to the other treatments both in Oxisol and in Inceptisol. 
In general, the DM yield for black oats showed a greater 
residual effect where the OF fertilizer was applied, 
proving that this fertilizer is superior to the traditional 

soluble solid form and to the mineral fertilizers in 
this aspect, in both soil types, and in both years of oat 
cultivation.

For wheat grain yield in 2013, the use of fertilizers in 
the mineral form of MF and MS produced a greater yield 

Table 7. Carbon management index (CMI) in Rhodic Kandiudox (Oxisol) and Lithic Distrochrept (Inceptisol), in response 
to the application of mineral and organomineral fertilizers in solid (MS and OS) and fluid (MF and OF) forms(1).

Soil Carbon management index (g kg -1) Pr>F
Control MF MS OF OS

0.0–0.05 m soil depth
Inceptisol 26.8±1.22A 28.1±0.65 22.8±2.43 18.5±1.72 24.6±1.14 0.23
Oxisol 15.6±1.49B 27.2±0.99 22.3±1.62 24.5±1.52 20.7±2.06 0.12

0.05–0.1 m soil depth
Inceptisol 39.5±1.37b 52.1±0.91a 38.6±2.69Bbc 29.8±1.88Bc 42.8±1.29ab 0.001
Oxisol 42.5±1.64 49.2±1.15 49.3±1.80A 41.5±1.66A 47.5±2.21 0.30

0.1–0.2 m soil depth
Inceptisol 39.7±1.68 38.9±1.31 40.6±2.28 36.4±2.06 53.2±1.37 0.17
Oxisol 44.8±1.88 40.9±1.45 53.1±1.93 41.7±1.82 48.6±2.09 0.39

0.0–0.2 m soil depth(2)

Inceptisol 33.2±1.42 36.7±1.37 31.2±1.81 25.7±1.49 36.1±1.55 0.06
Oxisol 28.1±1.96 35.9±1.33 35.8±1.54 33.0±1.56 33.3±1.46 0.30

(1)Means followed by equal letters, uppercase in the columns and lowercase in the rows, do not differ by Tukey’s test, at 5% probability. (2)Soil collection 
at 0.0–0.2 m soil depths was carried out separately from the other samples.

Table 8. Estimated yield of corn and wheat grains and shoot dry matter of black oat and fodder sorghum, in response to 
the application of organomineral and mineral fertilizers, in solid and fluid forms, to Rhodic Kandiudox (Oxisol) and Lithic 
Distrochrept (Inceptisol)(1).

Soil Yield and shoot dry matter (Mg ha-1) Pr>F
Control MF MS OF OS

Corn - 2010/2011
Inceptisol 10.7±0.56b 14.4±1.12a 14.3±1.04a 13.6±0.89a 12.9±0.77ab 0.001
Oxisol 10.5±0.55 11.80.99 12.3±1.16 12.3±1.08 12.5±0.69 0.12

Corn - 2011/2012
Inceptisol 10.0±1.15b 10.5±1.82Bb 13.1±1.77a 13.9±1.73a 11.0±1.56Bb 0.001
Oxisol 10.5±1.21b 12.9±1.58Aa 13.0±1.96a 13.4±1.88a 13.1±1.31Aa 0.001

Sorghum - 2012/2013
Inceptisol 5.9±0.28c 6.1±0.47Bbc 6.5±0.49Bb 8.6±0.37a 8.0±0.49a 0.003
Oxisol 5.7c±0.27 9.7±0.38Aa 8.6±0.26Ab 8.5±0.31b 8.2±0.21b 0.001

Oat - 2011
Inceptisol 2.4±0.25Bc 4.1±0.28Bab 3.1±0.33Bbc 4.7±0.72Ba 3.1±0.18Bbc 0.002
Oxisol 3.7±0.16Ac 6.6±0.31Ab 5.0±0.34Ab 6.5±0.33Aa 5.0±0.46Ab 0.001

Oat - 2012
Inceptisol 5.5±0.18b 5.7±0.23b 6.0±0.35b 7.1±0.44a 5.5±0.22b 0.003
Oxisol 4.8±0.21b 5.8±0.24b 5.7±0.29b 6.8±0.36a 5.50.37b 0.001

Wheat - 2013
Inceptisol 2.5±0.24c 4.6±0.45a 4.0±0.22ab 3.5±0.46bc 3.5±0.46bc 0.001
Oxisol 3.7±0.50 4.0±0.83 4.2±0.43 4.5±0.37 4.4±0.31 0.21

(1) Means followed by equal letters, uppercase in the columns and lowercase in the rows, do not differ by Tukey’s test, at 5% probability.



Carbon fractions and stock in response to organomineral fertilizers 9

Pesq. agropec. bras., Brasília, v.54, e00266, 2019
DOI: 10.1590/S1678-3921.pab2019.v54.00266

than in the other treatments, in the Inceptisol condition, 
whereas, in the Oxisol there was no difference between 
treatments (Table 8). 

For corn grain yield in 2010/2011, there were 
differences only in the Inceptisol, where the MF, MS, 
OF, and OS fertilizers were superior to the control 
(Table 8). In the 2011/2012 crop season, the OF and 
MS fertilizers resulted in greater yields than the 
other treatments in Inceptisol, while in the Oxisol all 
fertilizers were superior to the control.

The results obtained for corn and wheat yield and for 
sorghum and black oat shoot DM (Table 8) are correlated 
to the variables TOC, POC, CAM, and CMI (Tables 3, 
5, 6, and 7). This justifies the higher yields obtained 
with the MF for corn, in 2010/2011, in the Inceptisol and 
Oxisol and, in 2011/2012, in the Oxisol, as well as for 
wheat, in 2013, in the Inceptisol. In these types of soils, 
the MF proved to be superior to the other fertilizers 
regarding soil carbon forms.

Conclusions 

1. Organomineral and mineral fertilizers in solid 
and fluid forms applied to different soil classes with 
constructed fertility promote changes in the total 
organic carbon, carbon stock, particulate organic 
carbon, carbon associate with minerals, and carbon 
management index, in the treatments with fluid mineral 
and fluid organomineral only in Inceptisol condition 
due to the lower degree of weathering. 

2. The higher values of carbon management index 
resulting from fluid mineral in the Lithic Distrochrept 
allows of the inference to be made about the best 
management practice for increasing and maintaining 
carbon in the soil system, justified by the wheat, 
sorghum, and corn yield results, which were similar to 
those of the other fertilizers.

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