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eISSN: 2576-4462

Horticulture International Journal

Research Article Volume 3 Issue 6

Carbon stability and biochar aging process after soil application

Flavia Vosgrau De Negri Tozzi,1 Aline Renee Coscione,1 Aline Peregrina Puga,,2 Cristina Silva Carvalho,3 Carlos Eduardo Pellegrino Cerri,4 Cristiano Alberto de Andrade2

1Soil and Environmental Resources Center, Agronomic Institute, Brazil
2Brazilian Agricultural Research Corporation (Embrapa), Embrapa Environment Unit, Brazil
3Graduate Program in Agroecology, State University of Maranhão, Brazil
4Soil Science Department, Luiz de Queiroz College of Agriculture, University of São Paulo, Brazil

Correspondence: Cristiano Alberto de Andrade, Embrapa, Environment, Rodovia SP-340, Km 127,5; Tanquinho Velho CEP:13918-110, Jaguariúna, Estado de São Paulo, Brazi

Received: December 19, 2019 | Published: December 30, 2019

Citation: Tozzi FVDN, Coscione AR, Puga AP, et al. Carbon stability and biochar aging process after soil application. Horticult Int J. 2019;3(6):320?329. DOI: 10.15406/hij.2019.03.00147

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Abstract

During the pyrolysis process for biochar production there is the stabilization of C in aromatic compounds, which accredits biochar to function as an input for C sequestration in the soil. The aim of this study was assessing of C sequestration potential through pyrolyzed biochar in low temperature (350-400oC), checking the possible deleterious effect in soil organic matter (SOM) and assessing the cation exchange capacity (CEC) alteration, as the biochar is aging.

The research strategy involved, besides the materials characterization, the installation and conduction of two incubations under controlled laboratory conditions.

The evaluation of the biochar stability of C carbon, the effects on SOM and, therefore, the potential for the use of biochar in soil C sequestration was carried out in a respirometric experiment, with four typical tropical soil samples mixed with eucalyptus biochar dose (0.0, 2.5, 5.0, 10.0 and 20.0 g Ckg-1). After 120 days of incubation under non-limiting temperature and moisture conditions, the results showed C mineralization rates between 0,4 and 9,3%, which demonstrates the high carbon stability in the biochar. Through the 13C technique in soil analysis at the end of the incubation was observed small reductions of original C in SOM for two of the evaluated soils, although gains from biochar application represented more than double the original C content of soils.

The 360-day incubation experiment to evaluate biochar aging, focusing on the generation of negative charges, considered the variation in the presence or absence of soil; moisture and temperature (25 or 32°C). Among the factors tested, there was only effect of time on CEC. The increase in CEC was practically 100 mmolc kg-1 in one year, which represented a 50% increase in surface charges due to the biochar aging process.

The research led to the conclusion that biochar must be considered an input to soil C sequestration, in the reason of its high stability after application, recommending the use of the conservative value of 90% of the total C applied via biochar rate to environmental accounting related to C sequestration. In addition, increases in CEC in biochar treated soils are expected due to biochar surface charges as well as the aging process after application.

Keywords: soil carbon sequestration, biochar mineralization, priming effect, cation exchange capacity, biochar aging.

Introduction

The biochar is obtained through biomass pyrolysis in an environment with absence or restriction of O2 availability, which there is a thermochemical transformation of composts in sense of carbon concentration in stable structures similar to charcoal.1

The pyrolysis process can be applied in different situations such as the recycling of huge volumes of agricultural and forestry residues,2 decreasing the mass to disposal in the environment and eventually eliminating pathogens.3

In Brazil there is the availability of charcoal fines, a byproduct of the low temperature pyrolysis process (350 to 400oC) for the charcoal production used in the Brazilian steel industry, as a source of heat and carbon monoxide in the blast furnace to steel production,4 replacing coal coke, mainly in the production of pig iron.5 The charcoal fines are generated at a rate of 150 kg per ton of charcoal produced,6 where part of them (20-40%) is redirected to the fines injection process or it sold as briquette (CGEE, 2014); and the rest has no specific purpose.

The pyrolysis process stabilizes the biomass C in compounds more recalcitrant to decomposition, with aromatic structure,7,8 different from the compounds originally present.9,10 The biochar carbon decomposition half-life is estimated to range from 102 to 107 years11 and the average residence time of the most recalcitrant biochar fraction is 556 years.12

Thus, the application of charcoal fines in soil, denominated from here as biochar, can assist on global climate changes mitigation, through the C sequestration in agricultural soil.1,13,10

Pyrolysis temperature is recognized as a key factor for the stability of biochar C compounds after soil application,14,15 what makes it fundamental to evaluate the potential of biochar C sequestration from the charcoal manufacturing process for the Brazilian steel industry, where temperatures do not exceed 400oC.

An important aspect related to carbon balance by the use of biochar concerns the possibility of a "positive priming effect", in which the substantial increase in microbial activity leads to the loss of C from soil organic matter.12,16 This increase in microbial activity over relatively short periods is caused by bio-oil condensates that remain in solid matter.17

In summary, although the application of biochar potentially represents a stable soil C input, on the other hand there may be partial C output from soil organic matter due to the priming effect. The final carbon balance can be estimated with relative certainty based on knowledge of the mentioned processes. The qualitative aspect of this mass balance is not so simple, since soil organic matter compounds usually have cation exchange capacity (CEC) values of 1000 to 3000 mmolc kg-1,18 while the biochar CEC values range from 20 to 800 mmolc kg-1.19 It is also reasonable to consider that the fraction of organic matter lost due to the stimulation of soil microbial activity is the least humified fraction,20 which do not represent the compounds with higher CEC.

In this context of carbon balance in biochar application systems, which encompasses qualitative aspects that are closely related to soil functions in the environment, it is also important to take into account the negative surface charges generated in the process of aging of the biochar in the soil.

In biochar aging, charges are created by oxidation on particles surface, introducing functional groups, such as carboxylic,15 which tend to develop negative charges to values usually found in agricultural soils (pH>4,0).21 Environmental conditions such as moisture, temperature and microbial activity may alter the magnitude and intensity of surface charge generation in the biochar particles.22

The aim of this research was to evaluate the potential of soil carbon sequestration by using low temperature pyrolyzed biochar and the change in CEC with biochar aging to support carbon balance estimates in biochar-applied agricultural systems. Additionally, some factors possibly controlling the biochar aging process were tested, whose motivation is for later technological use to adding value to biochar or its products

Material and methods

The research strategy involved, besides the materials characterization, the installation and conduction of two incubations under controlled laboratory conditions.

The evaluation of the biochar stability of C carbon, the effects on soil organic matter (SOM) and, therefore, the potential for the use of biochar in soil C sequestration was carried out in a respirometric experiment with quantification of the released CO2.

Samples of four typical tropical soil types were used, with variations in texture and initial levels of C (Table 1 & Table 2): Oxisol 1, Entisol, Oxisol 2 and Oxisol 3.

Soil (1)

pH 1

SOM

COT 2

P

K+

Ca2+

Mg2+

H+Al

SB 3

 

CaCl2

g dm-3

g dm-3

mg dm-3

mmolc dm-3

Oxisol 1

4,4
(0,1)

10
(0)

6
(0)

8
(1)

0,9
(0,0)

10
(1)

4
(0)

14
(1)

14,9
(1,4)

Entisol

4,8
(0,1)

8
(1)

5
(1)

5
(1)

0,5
(0,0)

8
(1)

4
(0)

11
(1)

12,2
(0,5)

Oxisol 2

4,8
(0,1)

20
(1)

12
(1)

11
(1)

1,8
(0,1)

37
(1)

16
(0)

22
(0)

54,9
(0,9)

Oxisol 3

5,1
(0,1)

11
(15)

6
(0)

7
(3)

1,2
(0,0)

21
(1)

9
(0)

10
(1)

31,5
(1,9)

Table 1 Average values (and standard deviation) for some chemical attributes of soils

1Soil (0 to 20 cm depth) was analyzed for fertility according to the methodology of van Raij et al.23 pH in solution of CaCl2; SOM in aqueous medium using wet oxidation; P, K+, Ca+2 and Mg+2 extracted by ion exchange resin; and H+Al determined by pH SMP buffer.

2Total organic carbon determined on an elemental analyzer (TruSpec; LECO, St. Joseph, MI).

3Sum of bases calculated by the sum of the contents of K+, Ca+2 and Mg+2.

Soil

Clay 1

Silt

Sand

Soil texture classification

 

g kg-1

 

Oxisol 1

163
(9)

99
(12)

738
(4)

Sandy loam

Entisol

137
(11)

92
(9)

771
(5)

Sandy clay loam

Oxisol 2

457
(193)

210
(20)

333
(172)

Clay

Oxisol 3

195
(3)

127
(6)

678
(9)

Sandy loam

Table 2 Mean values (and standard deviation) for soil particle size fractions
1The particle size of soil (0 to 20 cm depth) was analyzed using the pipette method .24

The soil samples were previously torn, air dried and sieved with a 2 mm mesh.

The BC used in this study was produced by the pyrolysis of eucalyptus wood (charcoal fines) at approximately 400°C. Charcoal fines (particles with diameter<9,54 mm) are residues generated by the production and transportation of charcoal used in the Brazilian steel industry for pig iron production.25

For chemical characterization of BC (Table 3), the pH (H2O) and electrical. conductivity of BC were measured according to the International Biochar Initiative.26 Elemental composition (C, H and N) was determined using an elemental analyzer (Series II 2400; Perkin Elmer, Waltham, Massachusetts, USA). The ash content was determined following the procedure ASTM D1762-84.27 The oxygen content was determined by mass difference, using the following formula: 100%–(C+H+N+ash). The specific surface area was obtained using the N2-BET method (NOVA 1200 surface area analyzer; Quantachrome, Boynton Beach, Florida, USA). Cation exchange capacity (CEC) was analyzed according to the method of Gaskin et al.28 and by the official Ministry of Agriculture, Livestock and Food Supply method.29

 

Unit

Average value±standard deviation

pH

-

7,7 ± 0,1*

EC

mS cm-1

420 ± 24

Ash

%

4,3 ± 0,6

C

%

71 ± 2

H

%

2,7 ± 0,2

N

%

0,9 ± 0,2

O

%

21,1 ± 0,6

O/C (1)

-

0,22

H/C (2)

-

0,46

CEC (3)

mmolc kg-1

52 ± 3

CEC (4)

mmolc kg-1

184 ± 18

SSA

m2 g-1

16,9 ± 8,9

Table 3 Partial chemical characterization of the biochar used in the experiments

CEC determined by MAPA method.29

O/C molar Ratio=O/16C/12

H/C molar Ratio=H/1C/12

CEC determined by Gaskin et al.28 method, with compulsory exchange with ammonium acetate.

The biochar was analyzed in a Fourier Transform Infrared Absorption Spectrophotometer (FTIR) after pellet preparation of samples mixed with potassium bromide. The spectrum was obtained from 4000 to 450 cm-1, with a resolution of 4 cm-1 and 64 scans (Figure 1). The equipment used was Cary 360 – FTIR Spectrometer – Agilent.

Figure 1 Medium infrared (FTIR) of the original biochar and signaling of the main functional groups.

A two-factor randomized factorial experiment was performed to evaluate the stability of biochar carbon compounds in soil and effects on SOM. Four soil types with differences in texture (Table 2) and initial C levels (Entisol, Oxisol 1, Oxisol 2 and Oxisol 3 – Table 1) were used and biochar rates of 0.0, 2.5, 5.0, 10.0 and 20.0 g C kg-1, equivalent to 0, 5, 10, 20 and 40 t C ha-1, respectively.

Each microcosm consisted in a 100 g of soil or the mixtures of soil with biochar added to a hermetic sealed glass jar (1,5 L). The incubation was carried in a dark room with controlled temperature (28±1°C) for 120 days. The microcosm soil moisture was maintained at 70% of water holding capacity (WHC) through all the experiment conduction. Moisture was adjusted by weighing each microcosm and adding deionized water when necessary.

In each microcosm, a plastic cup with 50 mL of sodium hydroxide (NaOH 0.5 mol L1) solution was placed at soil surface to react with the emitted CO2 (mgCO2-C kg1soil). Microcosms remained sealed until a new solution exchange occurred. Alkaline solution exchange was twice a day or daily at the beginning and spaced at longer intervals over the experiment.

CO2 evolved from the microcosm was captured in NaOH solution30 and quantified by conductimetric method presented by Rodella and Saboya (1999).

Cumulative C-CO2 emission results discounted the respective control (soil only, without added biochar) were used to calculate the mineralization rate. Statistical analysis of these results was performed by calculating mean and standard deviation for further discussion about the dispersion of values as a function of soil type and applied rates, as well as comparison with other studies in the literature.

The impact of biochar on C originally present in MOS was evaluated using 13C analyzes on soil samples after the incubation period to determine the amount of C remaining soil introduced by biochar. The analyzes were performed in the Laboratory of Ecology Isotopic (LEI) at the Center for Nuclear Energy in Agriculture (CENA) of the University of São Paulo, in elemental analyzer Carlo Elba coupled to mass spectrometer Delta Plus.

To identify the C origin in the samples, the isotopic mixing equation was applied:

% C Biochar = ( δ 13 C Sample δ 13 C initial soil )  δ 13 C biochar δ 13 C initial soil ×100 MathType@MTEF@5@5@+= feaagKart1ev2aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr 4rNCHbGeaGqiVu0Je9sqqrpepC0xbbL8F4rqqrFfpeea0xe9Lq=Jc9 vqaqpepm0xbba9pwe9Q8fs0=yqaqpepae9pg0FirpepeKkFr0xfr=x fr=xb9adbaqaaeGaciGaaiaabeqaamaabaabaaGcbaqcLbsaqaaaaa aaaaWdbiaacwcacaWGdbqcfa4damaaBaaaleaajugib8qacaWGcbGa amyAaiaad+gacaWGJbGaamiAaiaadggacaWGYbaal8aabeaajugib8 qacqGH9aqpjuaGdaWcaaGcbaqcLbsapaGaaiika8qacqaH0oazjuaG paWaaWbaaSqabeaajugWa8qacaaIXaGaaG4maaaajugibiaadoeaju aGpaWaaSbaaSqaaKqzGeWdbiaadofacaWGHbGaamyBaiaadchacaWG SbGaamyzaaWcpaqabaqcLbsapeGaeyOeI0IaeqiTdq2cpaWaaWbaae qabaqcLbmapeGaaGymaiaaiodaaaqcLbsacaWGdbqcfa4damaaBaaa leaajugib8qacaWGPbGaamOBaiaadMgacaWG0bGaamyAaiaadggaca WGSbGaaiiOaiaadohacaWGVbGaamyAaiaadYgaaSWdaeqaaKqzGeGa aiyka8qacaGGGcaakeaajugibiabes7aKTWdamaaCaaabeqaaKqzad WdbiaaigdacaaIZaaaaKqzGeGaam4qaKqba+aadaWgaaWcbaqcLbsa peGaamOyaiaadMgacaWGVbGaam4yaiaadIgacaWGHbGaamOCaaWcpa qabaqcLbsapeGaeyOeI0IaeqiTdq2cpaWaaWbaaeqabaqcLbmapeGa aGymaiaaiodaaaqcLbsacaWGdbqcfa4damaaBaaaleaajugib8qaca WGPbGaamOBaiaadMgacaWG0bGaamyAaiaadggacaWGSbGaaiiOaiaa dohacaWGVbGaamyAaiaadYgaaSWdaeqaaaaajugib8qacqGHxdaTca aIXaGaaGimaiaaicdaaaa@8FE1@

where:

% C biochar = percentage of carbon from biochar;

d13C sample = isotopic signal of the soil sample analyzed after incubation;

d13C initial soil = isotopic signal from the original soil sample, i.e. before incubation and without mixture with biochar; and d13C biochar = isotopic signal from biochar sample.

The original soil C percentage was found by difference: % C soil = 100 - % C biochar

The soils Oxisol 1, Entisol, Oxisol 2 e Oxisol 3 originally presented average values of d13C equal to, respectively, -19,4‰; 20,6‰; - 19,3‰; e -17,26‰, contrasting with the average value of biochar equal to -27,6‰.

The results of carbon origin discrimination after the incubation period were submitted to variance analysis and regression analysis for rates of biochar.

The experiment to evaluate biochar aging, focusing on the generation of negative charges, was performed in a quadruple factorial design (2x2x2x7), considering the following variation factors: presence or absence of soil; moisture (constant between 70 and 80% of WHC or subjected to drying cycles up to 30% and wetting up to 80% of WHC); temperature (25 or 32°C); and incubation times (0, 15, 30, 60, 120, 240 and 360 days). Each microcosm consisted in a 150 g of soil and/or 30 g of biochar added to a plastic jar (250 mL). The soil used in the experiment was Oxisol 1 (Table 1) (Table 2).

The biochar (30 g) was placed in a polyamide bag (6 cm wide and 8 cm long) and closed to prevent particle loss. In the treatments with biochar and in the presence of soil, the bag containing the biochar was buried in 150 g of soil.

On the evaluation dates the biochar was removed from the bags, dried at 40ºC and analyzed for CTC, pH and EC. The pH and EC were determined following the International Biochar Initiative methods.26 The determination of biochar CTC was performed according to Gastkin et al.28 by adapting the method described by Summer and Miller31 of compulsory exchange with ammonium acetate.

The 240 days incubation biochar samples were sent for analysis of the elemental composition C, H, N and O, using the same methodology used in the initial characterization of the material.

The biochar aging results were submitted to analysis of variance and t-test for comparison of means (qualitative variation factors) and regression analysis for the time of incubation.

Results & Discussion

The biochar had a pH of 7,8±0,06, showing alkaline reaction; and had a CEC by MAPA official method less than 200 mmolc kg-1 necessary limit to the registry as a soil conditioner. It is important to understand, however, that the official Brazilian method of the Ministry of Agriculture, Livestock and Supply–MAPA32 was developed for typical organic materials such as manure and compost, and is based on variable charge sites saturation with hydrogen ions. The biochar has an organic matrix different from original biomass and, because of that, the proposed method by Gaskin et al.28 has been most used. Considering the average result of CEC and the standard deviation of Table 3, maintained the reference of 200 mmolc kg-1 from MAPA,32 one seen that through alternative method it could be the possibility of the registration as soil conditioner.

The biochar proved to be very concentrated in carbon, overcoming 70% in mass; which is superior to values close to 50% of C in eucalyptus wood.33,34 It has been known that during pyrolysis there is an increasing of aromaticity through the establishment of carbon-carbon bond and loss of O and H,34 which resulted in O/C ratio values of 0,22 and H/C of 0,46 less than eucalyptus wood values, equals to 0,67 and 1,45, respectively.35

After comparing band and functional groups of Table 3 with other results from literature,36,37 one seen that biochar still presents original peaks of biomass, such as OH band and cellulose and lignin signs. This is partially explained by the relatively low temperature of pyrolysis, from 350 to 400ºC, which agrees with H/C ratio values equals to 0,46, in the range that indicates simultaneous occurrence of aliphatic and cyclic (aromatic) carbon chains.38

The results showed C mineralization rates between 0,4 and 9,3% (Table 4) which demonstrates the high carbon stability in the biochar.

Soil (1)

Rate

C added

C-CO2 released

Mineralization rates

tha-1 C

mg kg-1

mg kg-1

%

Oxisol 1

5

2516

15,00
(0,20)

0,60
(0,01)

 

10

5032

64,62
(22,18)

1,28
(0,44)

 

20

9990

53,40
(15,83)

0,53
(0,16)

 

40

19980

141,46
(10,17)

0,71
(0,05)

Entisol

5

2516

0,00
(13,16)

0,00
(0,55)

 

10

5032

109,31
(109,55)

1,37
(1,93)

 

20

9990

72,71
(41,68)

0,88
(0,37)

 

40

19980

228,85
(174,09)

0,66
(0,08)

Oxisol 2

5

2516

37,77
(13,81)

1,50
(0,55)

 

10

5032

21,12
(13,04)

0,42
(0,26)

 

20

9990

69,35
(17,22)

0,69
(0,17)

 

40

19980

156,56
(47,09)

0,78
(0,24)

Oxisol 3

5

2516

22,92
(51,57)

0,91
(2,05)

 

10

5032

304,83
(100,04)

6,06
(1,99)

 

20

9990

363,65
(17,80)

9,31
(5,85)

 

40

19980

94,63
(13,58)

1,42
(1,30)

Table 4 Accumulated carbon released as CO2 (C-CO2) within 120 days of soil sample incubation and rates of biochar

Mineralization rates observed are compatible with other results of literature,12 given that the higher rates, at a rate of 10 to 15% of C mineralization, are normally found to low pyrolysis temperature.39,10

The difference between soils has become evident when, for example, it compares the Oxisol 3 and the Oxisol 1. One hypothesis initially raised by the research was the possibility of a positive priming effect in response to the application of biochar. In this case, an additional part of C-CO2 in some treatments (superior to the control) would occur due to the C mineralization from SOM and not from biochar.

From the 13C results (Table 5), it was possible to verify that in Oxisols 1 and 2 the original carbon remained at the same level, that is, it did not change with increasing biochar rates. For Entisol and Oxisol 3, reductions in the original C content of SOM were observed with increasing biochar rate applied.

Oxisol 1

Entisol

Total C

Biochar C

Soil C

Total C

Biochar C

Soil C

0

0,61

0,00

0,61

0,39

0,00

0,39

5

0,65

0,13

0,53

0,83

0,48

0,34

10

0,90

0,31

0,58

0,72

0,36

0,36

20

1,35

0,81

0,54

0,98

0,68

0,30

40

1,82

1,24

0,58

1,58

1,32

0,26

Model

y = 0,582 + 0,032x

y = 0,013 + 0,032x

Ns

y = 0,498 + 0,027x

y = 0,121 + 0,030x

y = 0,378 - 0,003x

r2

0,974*

0,973*

-

0,928*

0,931*

0,910*

CV%

13,37

27,44

13,83

33,08

52,05

7,3

 

Oxisol 2

Oxisol 3

 

Total C

Biochar C

Soil C

Total C

Biochar C

Soil C

0

1,2

0

1,2

0,51

0

0,51

5

1,445

0,2325

1,2125

0,645

0,185

0,4625

10

1,705

0,4825

1,2175

0,8825

0,4125

0,47

20

2,1

0,925

1,1725

1,28

0,855

0,4275

40

3,0075

1,8325

1,1775

2,31

1,89

0,4225

Model

y = 1,221 + 0,045x

y = 0,009 + 0,045x

Ns

y = 0,441 + 0,045x

y = -0,046 + 0,048x

y = 0,487 - 0,002x

r2

0,999*

1,000*

-

0,994*

0,997*

0,733*

CV%

3,73

9,1

3,45

4,87

7,11

7,56

Table 5 Carbon content and the origin discrimination (soil or biochar) in four soil samples after 120 days incubation with rates of biochar

Specialized literature provides information on the negative and positive priming effect due to biochar application. The negative priming effect is explained by the encapsulation of SOM in biochar pores and also due to surface chemical reactions that result in the formation of organo-mineral complexes.40,41 The positive priming effect, most often cited in scientific studies with biochar, results from stimulating SOM mineralization by increasing soil microbial activity.12

The SOM C reductions for two of the evaluated soils (Table 5) are negligible compared to the total C increments verified with the biochar dose increase (Figure 2), in agreement with the C stability results previously discussed. Therefore, biochar should be understood as an input for soil C sequestration and we recommend using 90% as a conservative value in accounting for C increment in production systems with biochar application.

Figure 2 Representation of carbon content variation with origin discrimination (C soil; and C biochar) in four incubated soils during 120 days with rates of biochar.

In terms of impact on CEC, as the lost SOM C fraction is negligible and not always occurring, it remains to understand about the charges added via biochar to the soil. Table 3 shows the biochar CEC values determined by two analysis methods. In addition to these values there are the negative charges possibly resulting from biochar aging in the soil, which is discussed below.

There was an expectation that abiotic factors, such as temperature and moisture, would interfere in surface charges generation through change of oxidative process. However, it was only verified time effect in CEC (Figure 3) and neither the absence nor presence of the soil has interfered in the process.

Figure 3 Cation Exchange Capacity (CEC) of biochar in aging process (incubation time).

The increase of CEC with the biochar aging is due to the progressive formation of surface carboxylic, phenolic, carbonyl groups.42,43

It is important to note that CEC is a requirement for registration as a product (soil conditioner) in MAPA and that typical organic materials such as manure and compost generally reach the required limit value of 200 mmolc kg-1. In the case of biochar, this limit may be a barrier to its registration, but the basic differences between the behavior of typical organic materials and biochar after soil application must be considered. Unlike typical organic materials, biochar practically remains in the soil after application (we recommend using 90% of total C for the stable fraction) and still has CEC gains over time (100 mmolc kg‑1 in one year - Figure 3). Such differences would justify the request for registration as a new product in a specific category for biochar in MAPA.

Surface changes in biochar particles with the aging process involve increased O/C ratio,40 which was observed in our results. At 240 days of incubation the biochar presented values ​​of 0.25± 0.01 and 0.49±0.01 for the O/C and H/C ratios, respectively. These values ​​are greater than 0.22 for O/C and 0.46 for H/C in the original biochar (Table 3) and indicate the occurrence of C-C bond cleavage and new O and H bonds formation with biochar aging. The new O and H bonds make the material more aliphatic and polar, which corroborates the increases in CEC.

In order to improve the understanding of aging process of biochar, there was realized FTIR analyses at 240 days of incubation (Figure 4). In general way, both the presence and the absence of soil, the changes in signals of functional groups were quite similar.

Figure 4 Fourier transform infrared absorption spectrophotometer (FTIR) analysis of biochar samples aged for 240 days in the presence (a) or absence of soil (b). The lines of different colors represent the combinations with the other variation factors studied (temperature and moisture).

In comparison to Figure 1, which shows the analysis of initial biochar sample (without aging), it can be observed in Figure 4 that changes occurred in the band near 2300 cm-1, indicating that the functional group of C-O has disappeared from original biochar in relation to treatments. In the band near 1436 cm-1, there was a displacement of O-C-O or aromatic CH2. There was attenuation of bands under 100cm-1 of aromatic C-H, alkane C-H and alkenes with the disappearing of band in 670 cm-1.

In the near 1100 to 1030 cm-1 band of Figure 4b, the attenuation of the vibrational stretching of C‑O-C in cellulose and hemicellulose is noted. This band can also be seen in Figure 4a, but the changes in the absence of soil were more remarkable.

The set of changes observed suggest the formation of more simple structures by the increasing of linear saturated carbonic chains (break of aromatic CH2, aromatic C-H) and of residual C-O and O-C-O of cellulosic structures. This loss of signal of O linked to C can be suggest a loss of polarity regarding cellulosic structure. However, such hypothesis it was not confirmed because the 240-day incubation O-C ration was higher than original biochar.

Conclusion

The biochar must be considered an input to soil carbon (C) sequestration, in the reason of its high stability after application, recommending the use of the conservative value of 90% of the total C applied via biochar rate to environmental accounting related to C sequestration. Losses of original C from soil organic matter due to the application of biochar are insignificant in terms of mass and in comparison with the observed total carbon increments.

The biochar aging was characterized by the increase of 50% in cation exchange capacity after one year, but this aging was not influenced by the presence or absence of contact with the soil, with temperature variations and wet and dry cycles. The non-interference of these other factors allows the promotion of biochar aging before its field application, in exclusive or in composting piles, for example.

Acknowledgments

The authors are grateful for the financial support from São Paulo Research Foundation (FAPESP; Grant No. 2017/02886-7). Also, we would like to thank Felipe Puga for translating the paper.

Conflicts of interest

Authors declare no conflict of interest exists.

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