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Potential and importance of carbon sequestrations in agricultural soils

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Soil organic carbon (SOC) pool is the largest among the terrestrial pools. The restoration of SOC pool in arable lands represents a potential sink for atmospheric CO2. The management and enhancement of SOC is important for sustainable agriculture. The cropping system and soil type influence crop biomass under different fertilization. Agriculture acts as both the sink and sources of the greenhouse gases.

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Nội dung Text: Potential and importance of carbon sequestrations in agricultural soils

  1. Int.J.Curr.Microbiol.App.Sci (2017) 6(2): 1776-1788 International Journal of Current Microbiology and Applied Sciences ISSN: 2319-7706 Volume 6 Number 2 (2017) pp. 1776--1788 Journal homepage: http://www.ijcmas.com Review Article http://dx.doi.org/10.20546/ijcmas.2017.602.199 Potential and Importance of Carbon Sequestrations in Agricultural Soils Rupa Ram Jakhar1*, S.R. Yadav2, Rajendra Kumar Jakhar1, Prahalad Devra, Hardev Ram3 and Rakesh Kumar3 1 Agricultural Research Station, Swami Keshwanand Rajasthan Agricultural University, Bikaner 334 006, India 2 Soil Science, ARS, Swami Keshwanand Rajasthan Agricultural University, Bikaner, India 3 Agronomy, ICAR-NDRI, Karnal 132001, India *Corresponding author ABSTRACT Keywords Soil organic carbon (SOC) pool is the largest among the terrestrial pools. The restoration of SOC pool in arable lands represents a potential sink for Carbon sequestration, atmospheric CO2. The management and enhancement of SOC is important for Conservation sustainable agriculture. The cropping system and soil type influence crop agriculture, GHGs, biomass under different fertilization. Agriculture acts as both the sink and Soil organic carbon (SOC). sources of the greenhouse gases .Conservation agriculture play significant role in soil organic carbon sequestration by increasing soil carbon sinks, reducing Article Info GHG emission, and contributing biomass feed stocks for energy use. Adoption Accepted: of conservation agriculture with use of crop residues, mulch and no till farming 24 January 2017 helps to conserve moisture, reduces soil erosion and enhances soil organic Available Online: concentration. Sequestering the carbon in the soil plant system through site 10 February 2017 specific management practice may help to mitigate impact of climate change. Introduction In view of the growing world population, in the ability to provide ecosystem services within two decades global demand for food is because of soil carbon losses (Bai et al., projected to increase by 50 per cent, for water 2008). Soil erosion associated with by 35-60 per cent, and for energy by 45 per conventional agricultural practices can occur cent. The world’s soils are consequently at rates up to 100 times greater than the rate at under increasing pressure. Soil carbon plays a which natural soil formation takes place vital role in regulating climate, water supplies (Montgomery, 2007). and biodiversity, and therefore in providing the ecosystem services that are essential to Soil is one of the important sources and sinks human well-being. Since the 19th century, of greenhouse gases (GHGs) causing global around 60 per cent of the carbon in the warming and climate change. It contributes world’s soils and vegetation has been lost about 20 per cent to the total emission of owing to land use (Houghton, 1995). In the carbon dioxide through soil respiration and past 25 years, one-quarter of the global land root respiration, 12 per cent of methane and area has suffered a decline in productivity and 60 per cent of anthropogenic nitrous oxide 1776
  2. Int.J.Curr.Microbiol.App.Sci (2017) 6(2): 1776-1788 emissions. Global warming may affect global with high organic matter is more productive carbon cycle thereby distorting structure and than the same soil where much of the organic functions of ecosystems. Organic matter matter has been “burned” through tillage and concentration, which is quite low (
  3. Int.J.Curr.Microbiol.App.Sci (2017) 6(2): 1776-1788 different forms of carbon are shown in the physical and biological fertility. The activity Table-1. Organic carbon is found in soils in of living organisms in soil is dependent on the form of various organic compounds, regular inputs of organic matter. The impact collectively called soil organic matter (SOM). of soil organic matter on the soil qualities can The amount of carbon found in SOM ranges be summarized as follows: from 40 to 60% by mass. SOM includes all living and non-living organic material in the Physical effects: Soil aggregation, erosion, soil. The living component includes plants, drainage, aeration, water-holding capacity, soil fauna and microbial biomass. The non- bulk density, evaporation, and permeability. living component, representing the bulk of SOM, includes a spectrum of material from Chemical effects: Cation exchange capacity; fresh residues and simple monomeric metal complexing; buffering capacity; supply compounds to highly condensed, irregular and availability of macro and micronutrients; polymeric structures with residence times and adsorption of pesticides and other added varying from days to millennia. chemicals. Soil organic carbon refers to the carbon in Biological effects: Activities of bacteria, soils associated with the products of living fungi, actinomycetes, earthworms, roots, and organisms. It is a heterogenous mixture of other microorganisms. Different sources of simple and complex organic carbon organic matter supply soils with carbon to compounds which can be divided into replenish their C and nutrient pools in soil. different pools dependent on their ease of However, organic materials added to soils decomposition and functions in soil. The use contain a wide range of C compounds that of soil to sequester carbon needs to consider vary in their rate of decomposition. The at least three significant soil carbon pools. biological breakdown of the added organic These carbon pools are the labile, less labile material depends on the rate of degradation of (recalcitrant) and inert fractions. The labile each of the carbon-containing materials. soil carbon pool consists mainly of soil Changes in environmental factors can cause organisms, polysaccharides, celluloses and changes in the rate of decomposition of hemi-celluloses with a half-life in soils organic materials in soils, such as soil varying from weeks to months. The moisture status, soil aeration, soil recalcitrant pool consists of lignins, lipid temperature, pH, and availability of minerals. polymers, suberins, resins, fats, and waxes with half-lives varying from years to decades. The Global Carbon Cycle This pool also contains humified products formed by biological transformation of carbon Soils play significant roles in global carbon compounds. The inert pool consists of cycle. It was estimated that soils have charcoal and pyrolysed carbon with half-lives contributed as much as 55 to 878 billion tons of centuries to millennia. (GT) of carbon to the total atmospheric CO2 (Kimble et al., 2002). Globally, the top metre Impact of Soil Organic Carbon on Soil of soil stores approximately 1500 Pg as Health organic C and an additional 900-1700 Pg as inorganic C and exchanges 60 Pg C yr-1 with Soil organic carbon is of fundamental the atmosphere, which contains ~750 Pg C as importance to soil health as it affects all three carbon dioxide (Eswaran et al., 1993; aspects of soil fertility, such as chemical, Schlesinger, 1997). The sheer size of the soil 1778
  4. Int.J.Curr.Microbiol.App.Sci (2017) 6(2): 1776-1788 carbon pool and the annual flux of carbon soil inorganic C (SIC) pool at 950 Pg (Batjes, passing through the soil are two of the reasons 1996). The SOC pool includes highly active that SOC can play a significant role in humus and relatively inert charcoal C. It mitigating greenhouse gases emissions. comprises a mixture of: (i) plant and animal residues at various stages of decomposition; The global carbon cycle describes the transfer (ii) substances synthesized microbiologically of carbon in the earth’s atmosphere, and/or chemically from the breakdown vegetation, soils, and oceans. The two most products; and (iii) the bodies of live micro- important anthropogenic processes organisms and small animals and their responsible for the release of carbon dioxide decomposing products (Schnitzer, 1991). On into the atmosphere are burning of fossil fuels the basis of the mean residence time (MRT) (coal, oil, and natural gas) and land use. or ease of decomposition, the SOC pool can Emissions from land-use change are about 1.5 be grouped into three categories: labile with Gt Cyr-1, largely determined by tropical MRT of days to years, intermediate with deforestation that exacerbates soil erosion and MRT of years to decades and centuries and organic matter decomposition. The underlying passive with MRT of centuries to millennia. driving factors of tropical deforestation The SIC pool includes elemental C and arehighly interconnected and include poverty, carbonate minerals such as calcite, and policy and institutional failures, population dolomite, and comprises primary and growth, and the attendant demand for natural secondary carbonates. The primary carbonates resources, urban expansion, and international are derived from the weathering of parent trade. Rapidly growing emissions are material. In contrast, the secondary carbonates outpacing the growth in natural sinks. The are formed by dissolution of CO2 in soil air efficiency of oceans and lands as into dilute carbonic acid and its interaction carbondioxide sinks has declined over the with calcium (Ca+2) and magnesium (Mg+2) years. There are five global C pools, of which brought in from outside the local ecosystem the largest oceanic pool is estimated at 38 000 (e.g. calcareous dust, irrigation water, Pg and is increasing at the rate of 2.3 Pg C yr- fertilizers, manures). The SIC is an important 1 . The geological C pool, comprising fossil constituent of soils in arid and semi-arid fuels, is estimated at 4130 Pg, of which 85 regions. The fourth largest pool is the percent is coal, 5.5 percent is oil and 3.3 atmospheric pool comprising ~800 Pg of percent is gas. Proven reserves of fossil fuel CO2-C, and is increasing at the rate of 4.2 Pg include 678 Pg of coal (3.2 Pg yr-1 of C yr-1 or 0.54 percent yr-1. production), 146 Pg of oil (3.6 Pg yr-1 of production) and 98 Pg of natural gas (1.5 pg The smallest among the global C pools is the yr-1 of production) (Schrag, 2007). Currently, biotic pool, which is estimated at 620 Pg, coal and oil each account for approximately comprising 560 Pg of live biomass and 60 Pg 40 percent of global CO2 emissions (Schrag, of detritus material. The pedologic and biotic 2007). Thus, the fossil fuel pool is depleting C pools together are called the terrestrial C as a result of fossil fuel combustion, at the pool estimated at approximately 3120 Pg. The rate of 8.3 Pg C yr-1. terrestrial and atmospheric C pools strongly interact with one another through The third largest pool is in the soil, pedologic photosynthesis and respiration. The annual and is estimated at 2 500 Pg to 1 m depth. rate of photosynthesis is 120 Pg C, most of This pool has two distinct components: soil which is returned to the atmosphere by plant organic carbon pool estimated at 1550 Pg and and soil respiration. Conversion from natural 1779
  5. Int.J.Curr.Microbiol.App.Sci (2017) 6(2): 1776-1788 to managed ecosystems, extractive farming other carbon-emitting activities while practices based on low external input, and soil enhancing soil quality and long-term degrading land use tend to deplete terrestrial agronomic productivity. Soil carbon C pools. The pedologic pool loses 1.1 Pg C sequestration can be accomplished by into the atmosphere as a result of soil erosion management systems that add high amounts and another 0.3-0.8 Pg C yr-1 to the ocean of biomass to the soil, cause minimal soil through erosion-induced transportation to disturbance, conserve soil and water, improve aquatic ecosystems. Yet, the terrestrial sink is soil structure, and enhance soil fauna activity. currently increasing at a net rate of 1.4 ± 0.7 Continuous no-till crop production is a prime Pg C yr-1. Thus, the terrestrial sink absorbs example. approximately 2-4 Pg C yr-1 and its sink capacity may increase to approximately 5 Pg Carbon sequestration refers to the removal of C yr-1 by 2050 (Cramer et al., 2001; Scholes carbon dioxide from the atmosphere into a and Noble, 2001). Increase in the terrestrial long-lived stable form that does not affect sink capacity may be the result of the CO2 atmospheric chemistry. Carbon sequestration fertilization effect and changes in land use is defined as the removal of CO2 from the and management. The biotic pool also atmosphere into various long lived chemically contributes to an increase in atmospheric CO2 bound forms, either on land or in the ocean. concentration through deforestation and land- Through the process of photosynthesis, CO2 is use conversion at the rate of ~1.6 Pg C yr-1. sequestered from the atmosphere into plant tissues. Photosynthesis represents the largest The strong interactions between the transfer of CO2 in the C cycle, and therefore, atmospheric, pedologic and the biotic C pools is of great importance in understanding how comprise important components of the global to manage the global C cycle. Carbon carbon cycle (GCC). Understanding and sequestration on land (or terrestrial C managing these interactions form the basis of sequestration) occurs in standing biomass any strategy to sequester atmospheric CO2 in (e.g., trees), long-term harvested products the biotic and pedologic pools. The (e.g., lumber), living biomass in soil (e.g., atmospheric pool is connected to the oceanic perennial roots and microorganisms), pool, which absorbs 92.3 Pg yr-1 and releases recalcitrant organic matter in surface soil 90 Pgyr-1 with a net positive balance of 2.3 Pg (e.g., humus), and inorganic C in subsoil (e.g., C yr-1. The oceanic pool will absorb carbonates). approximately 5 Pg C-1 yr-1 by2100 (Orr et al., 2001). The total dissolved inorganic C in Potential of Soil Carbon Sequestration in the oceans is approximately 59 times that of India the atmospheric pool. With a large land area and diverse eco- Carbon Sequestration regions, there is a considerable potential of terrestrial/ soil carbon sequestration in India. Soil carbon sequestration is the process of Of the total land area of 329 m ha, 297 m ha transferring carbon dioxide from the is the land area comprising 162 m ha of arable atmosphere into the soil through crop residues land, 69 m ha of forest and woodland, 11 m and other organic solids, and in a form that is ha of permanent pasture, 8 m ha of permanent not immediately reemitted. This transfer or crops and 58 m ha is other land uses. The “sequestering” of carbon helps off-set SOC pool is estimated at 21 Pg (Pg =1 x 1015 emissions from fossil fuel combustion and g) to 30 cm depth and 63 Pg to 150 cm depth. 1780
  6. Int.J.Curr.Microbiol.App.Sci (2017) 6(2): 1776-1788 The SIC pool is estimated at 196 Pg to 1 m depletion of SOC levels, soils have the depth. The SOC concentration in most capacity to store more carbon than they do at cultivated soils is less than 5 g kg-1 compared present (Paustian et al., 1997; Lal et al., with 15 to 20 g kg-1 in uncultivated soils. The 1998). Soil organic carbon can be increased total potential of carbon sequestration range by adopting practices that reduce soil from 39.3 to 49.3 Tg C yr-1 (Tg = 1 x 1012 g) disturbance and/or by increasing the amount of India are shown in Table 2. Included in this of biomass produced and retained. potential is also that of the restoration of Agricultural ecosystems represent an degraded soils and ecosystems estimated at estimated 11% of the earth’s land surface and 7.20 to 9.8 Tg C yr-1 (Table 3). include some of the most productive and carbon-rich soils. As a result, they play a Importance of Carbon Sequestration significant role in the storage and release of C within the terrestrial carbon cycle (Lal et al., Soil Organic Carbon is part of the global C 1995). The major considerations of the soil C cycle and the global SOC pool (1580 Gt) is balance and the emission of greenhouse gases twice as large as that in the atmosphere and from the soil are: (1) the potential increase of nearly three times that of the vegetation CO2 emissions from soil contributing to the biomass carbon pool. The scientific consensus increase of the greenhouse effect, (2) the is that the levels of greenhouse gases in the potential increase in other gas emissions (e.g., atmosphere are increasing. These changes in N2O and CH4) from soil as a consequence of greenhouse gas emissions generally are linked land management practices and fertilizer use, to human activities. The concern is that the and (3) the potential for increasing C (as CO2) mean global level of greenhouse gases in the storage into soils, which equals 1.3 – 2.4 x atmosphere is increasing to a level that can 109 metric tons of carbon per year (Tans et al. trigger serious climate changes in air 1990), and to help reduce future increases of temperature and violent weather cycles. CO2 in the atmosphere. Carbon sequestration by agricultural land has generated international interest because of its Needs of Carbon Sequestration in potential impact on and benefits for Agriculture agriculture and climate change. Where proper soil and residue management techniques are Although carbon emissions from agricultural implemented, agriculture can be one of many activities contribute the enrichment of potential solutions to the problem of atmospheric CO2, carbon sequestration in greenhouse gas emissions. Additionally, agricultural soils, through the use of proper agriculture conservation practices such as the management practices, can mitigate this trend. use of different cropping and plant residue While the soil inorganic carbon contributes management, as well as organic management approximately 25% of the overall soil carbon farming, can enhance soil carbon storage. inventory, agricultural activities have more Farmers, as well as the soil and environment, profound influence on changes of soil organic receive benefits from carbon sequestration. carbon both in the short and the long term. Increasing soil organic carbon content The global decline in SOC as a result of land enhances soil quality, reduces soil erosion and use changes, including deforestation, shifting degradation, improves surface water quality, cultivation and arable cropping have made and increases soil productivity. Thus, carbon significant contributions to increased levels of sequestration in soils, i.e., increasing soil atmospheric CO2. Because of this past organic carbon in agricultural soils through 1781
  7. Int.J.Curr.Microbiol.App.Sci (2017) 6(2): 1776-1788 proper management, provides a multitude of Basic Concepts of Carbon Sequestration environmental benefits. The goals to sequester soil organic carbon is to create a Atmospheric enrichment of GHGs can be win-win situation to improve soil moderated by either reducing anthropogenic productivity, reduce unnecessary inputs, and emissions, or sequestering C in plant biomass promote sustainability. or the soil. Transfer of atmospheric CO2 into other pools with a longer MRT, in such a Historically, approximately 78 Pg C has been manner that it is not re-emitted into the lost from the global soil pool due to land-use atmosphere in the near future, is called conversion for agriculture with approximately sequestration. Depending on the processes 26 Pg attributed to erosion and 52 Pg and technological innovations, there are three attributed to mineralization (Lal 2004). main types of C sequestration: (i) those based Conversion of native forest and pasture to on the natural process of photosynthesis and cropland has been found to reduce SOC conversion of atmospheric CO2 into biomass, stocks by an average of 42% and 59%, soil organic matter or humus and other respectively (Guo and Gifford 2002). These components of the terrestrial biosphere; (ii) large historic losses and the concomitant those involving engineering techniques; and potential to return to pre-clearing SOC (iii) those involving chemical transformations conditions are precisely the reason many (Lal, 2008). researchers believe there is great potential for agricultural soils to sequester large amounts The rate of enrichment of atmospheric CO2 of atmospheric CO2 relative to current SOC concentration can be reduced and moderated levels. by its transfer to other pools by mitigative and adaptive options. Mitigative strategies involve Over the past 150 years, the amount of carbon those options that either reduce emissions or in the atmosphere has increased by 30%. sequester C. Emission reduction includes Most scientists believe there is a direct those technologies that enhance energy-use relationship between increased levels of efficiency, and involve low-C or no-C fuel carbon dioxide in the atmosphere and rising sources. In general, natural processes of global temperatures. One proposed method to sequestering C into terrestrial and aquatic reduce atmospheric carbon dioxide is to ecosystems are more cost-effective and have increase the global storage of carbonin soils. numerous co-benefits, such as enhancement of ecosystem services, as compared with An added benefit to this solution is the engineering techniques and conversion of potential for simultaneous enhancement in CO2 into carbonates (McKinsey and agricultural production. Increasing carbon Company, 2009). pools in the soil beyond a threshold level (about 1.2% in the surface layer) is essential The engineering techniques of C capture and to enhancing soil quality, increasing storage (Lackner, 2003; Koonin, 2008; agronomic productivity, and improving Broecker, 2008) involve injection of quality of natural water. The strategy of compressed and liquefied CO2 beneath the carbon sequestration in soil and biota is cost ocean, into a saline aquifer or into a stable effective, safe, and has numerous co-benefits rock strata (Chu, 2009; Haszeldine, 2009). over leaving carbon in the atmosphere or Injecting CO2 into old oil wells can enhance sequestering it in geological and oceanic oil recovery, and in unmineable coal seams it strata. can displace coal bed methane. The principal 1782
  8. Int.J.Curr.Microbiol.App.Sci (2017) 6(2): 1776-1788 concerns about geologic sequestration are the process of photosynthesis, plants take in relatively high cost and the need for an carbon and return some of it to the established protocol for measurement, atmosphere through respiration. The carbon monitoring and verification. Despite the that remains as plant tissue is then consumed technical potential, the engineering techniques by animals or added to the soil as litter when (geologic and oceanic sequestration) are still plants die and decompose. The primary way works in progress, and monitoring and that carbon is stored in the soil is as soil verification protocol still needs to be organic matter. It is a complex mixture of developed and approved. carbon compounds, consisting of decomposing plant and animal tissue, Mineral carbonation is the transformation of microbes (protozoa, nematodes, fungi, and industrial CO2 into calcium carbonate bacteria), and carbon associated with soil (CaCO3), and magnesium carbonate (MgCO3) minerals. Carbon can remain stored in soils and other minerals in the form of stable for millennia, or be quickly released back into carbonates. It is a two-stage process the atmosphere. Any practice that moves plant comprised of scrubbing and mineral material down into the soil extends the period carbonation. Application of the slow natural that carbon is sequestered. Agricultural processes under industrial conditions requires practices can also sequester carbon above development of appropriate technology. ground in the form of woody material. Sequestration of CO2 by plants occurs both in Climatic conditions, natural vegetation, soil terrestrial and inland aquatic ecosystems (or texture, and drainage all affect the amount wetlands). CO2 sequestration in terrestrial and length of time carbon is stored. ecosystems is significant in protected areas and in extensively and intensively managed Practices for Improve the Carbon land-use systems, but to different degrees Sequestration In Soils depending on vegetation, soil types and conditions. Managed ecosystems include the In agricultural systems, the amount and length world’s croplands, grazing lands, forest lands of time carbon is stored is determined and urban lands. Restoration of predominately by how the soil resource is degraded/desertified lands, and drastically managed. A variety of agricultural practices disturbed ecosystems (i.e. mined lands) that can enhance carbon storage have been comprise an important sink for atmospheric proposed. The benefits of these various CO2. Important strategies for aquatic practices as well as their potential hidden ecosystems are the management and costs must be considered when management restoration of wetlands (peat soils and their decisions are made. Management techniques, permanent vegetation). Although fertilization which are successful in providing a net carbon of oceans using iron is technically possible, sink in soils, include the following: there are environmental concerns (Kintisch, 2001). Conservation tillage: Conservation tillage minimizes or eliminates manipulation of the Carbon Sequestration Process in soil for crop production. It includes the Agriculture practice of mulch tillage, which leaves crop residues on the soil surface. These procedures Agriculture can play an important role in generally reduce soil erosion, improve water mitigating the greenhouse gases through in use efficiency, and increase carbon soil carbon sequestration. Through the concentrations in the topsoil. Conservation 1783
  9. Int.J.Curr.Microbiol.App.Sci (2017) 6(2): 1776-1788 tillage can also reduce the amount of fossil Management for carbon sequestration fuel consumed by farm operations. It has been affects other gases that influence climate: estimated to have the potential to sequester a Management for carbon sequestration affects significant amount of CO2. other gases that influence climate such as atmospheric concentrations of nitrous oxide Cover cropping: Cover cropping is the use of and methane. Changes in these gases must crops such as clover and small grains for also be factored into management strategies protection and soil improvement between for carbon storage. periods of regular crop production. Cover crops improve carbon sequestration by Advantages of Carbon Sequestration enhancing soil structure, and adding organic matter to the soil.  Farm level benefits: Carbon sequestration builds soil fertility, improves soil quality, Crop rotation: Crop rotation is a sequence of improves agronomic productivity, crops grown in regularly recurring succession sustaining biological activity, protect soil on the same area of land. It mimics the from compaction and nurture soil diversity of natural ecosystems more closely biodiversity, regulating and partitioning than intensive mono-cropping practices. water and solute transport. Varying the type of crops grown can increase the level of soil organic matter. However,  Off- farm level benefits: It is also helpful effectiveness of crop rotating depends on the in the protection of streams, lakes, and type of crops and crop rotation times. rivers from sediment, runoff from Cropping intensity and soil carbon are agricultural fields, and enhanced wildlife positively related. The more frequent the habitat. Instead of these major role is in cropping and greater the biomass inputs, the mitigating GHG’s emissions. more soil carbon.  Sequestration of soil organic C from plant Fertilization: Fertilization affects soil carbon biomass is a key sequestration pathway in mainly through crop biomass. However, the agriculture; offering an offset strategy (i.e., carbon: nitrogen ratio of soil organic matter mitigation) for agriculture’s other results in stable organic matter typically greenhouse gas emissions. Soil C within a range of about 8-10:1. If insufficient sequestration is also important at the farm nitrogen is present to permit stable formation level to build soil fertility, protect soil from of soil organic matter via soil microbial compaction, and nurture soil biodiversity. degradation of crop residues, then little In addition to its vital role of mitigating carbon may be sequestered. greenhouse gas emissions, soil C sequestration provides many other Growing plants on semiarid lands: Growing significant off-farm benefits to society. plants on semiarid land has been suggested as These benefits include the protection of a way to increase carbon storage in soils. streams, lakes, and rivers from sediment, However, the fossil fuel costs of irrigating nutrient, and pathogen runoff from these lands may exceed any net gain in carbon agricultural fields, as well as enhanced sequestration. Additionally, in many semi- wildlife habitat. A full-system cost-to- arid regions surface and groundwater contain benefit ratio of soil C sequestration from high concentrations of dissolved calcium, and various conservation agricultural practices bicarbonate ions. As these are deposited in the has not been adequately addressed, but is soil, they release CO2 into the atmosphere. 1784
  10. Int.J.Curr.Microbiol.App.Sci (2017) 6(2): 1776-1788 needed to more fully appreciate this oxidation and breakdown of plant residue will important pathway. accelerate the loss of carbon as CO2. Several factors can accelerate organic carbon Factors Affecting Carbon Sequestration in breakdown and production of greenhouse Soils gases. They include soil moisture, soil pH, the oxidation-reduction process, soil temperature, Several factors can affect the storage of chemical and physical soil properties, nutrient carbon in soils. The amount of carbon stored status, and plant residue quantity and quality. in the soil system depends on the rate and The breakdown of residue through magnitude of the process. These factors can conventional tillage and soil disturbance must be influenced by agriculture management be minimal to fully store carbon in the soil systems and practices. system. Carbon stored in the soil can help in improving soil physical properties such as Organic production: Carbon production can infiltration rate, water-holding capacity, be increased through photosynthesis, in which aggregate stability, soil structure, soil the permanent vegetation cover can store a aeration, and other physical properties. In significant amount of carbon dioxide as addition, carbon storage can contribute organic carbon. The volume of vegetation acts significantly to improving soil nutrient pools as a sink for capturing CO2 and secures and other chemical properties. Plant residues storage of it as carbon. Farming practices and play a significant role in providing a positive land use can greatly affect the carbon status in environment for improving soil microbial the soil system. During plant growth, CO2 populations, which in turn play a significant from the atmosphere will be fixed in the plant role during the decomposition process of as carbon compounds. Therefore, the primary organic materials. Keeping plant residues source of carbon is the plant, in which the intact is a critical component of soil carbon has been manufactured initially management, not only for nutrient value, but through the photosynthesis process. also for soil protection from wind and water erosion. Minimize organic carbon breakdown: The Table.1 Forms of carbon in the soil Forms Sources Elemental Geological materials (e.g. graphite and coal) Incomplete combustion of organic materials (e.g. charcoal, graphite) Dispersion of these carbon forms during mining Inorganic Geological or soil parent materials, usually as carbonates- that is calcite, CaCO3, dolomite, CaMg(CO3) and to some extent, siderite (Fe CO3) Agricultural input such as liming can also introduce calcite and dolomite into soil. Organic Plant and animal materials at various stages of decomposition ranging from crop residues with size of 2 mm or more plant debris, also referred to as particulate organic carbon, with size between 0.05 and 2 mm and humus, highly decomposed materials less than 0.05 mm that are dominated by molecules attached to soil minerals. Source: Schumacher (2002) 1785
  11. Int.J.Curr.Microbiol.App.Sci (2017) 6(2): 1776-1788 Table.2 The total potential of carbon sequestration in soils of India Process Potential (Tg C y-1) I. Soil organic carbon (SOC) Restoration of degraded soils 7.2-9.8 Agricultural intensification 5.5-6.7 II. Secondary carbonates 21.8-25.6 III. Erosion control 4.8-7.2 Total 39.3-49.3 Source: Debnath and Bhatt (2014) Table.3 Soil organic carbon sequestration through restoration of degraded soils Area SOC sequestration Total SOC sequestration Degradation process (m ha) rate (kg ha-1 yr-1) Potential (Tg C yr-1) Water erosion 32.8 80-120 2.62-3.94 Wind erosion 10.8 40-60 0.43-0.65 Soil fertility decline 29.4 120-150 3.53-4.41 Water logging 3.1 40-60 0.12-0.19 Salinization 4.1 120-150 0.49-0.62 Lowering of water table 0.2 40-60 0.01-0.012 Total 7.20-9.8 Source: Debnath and Bhatt (2014) Soil erosion: Improper soil and residue removal of carbon from the soil will lead to a management results in increased erosion by decline in soil fertility and aggregate stability. water and wind. Soil erosion is leading cause of soil degradation due to the loss of organic In conclusion, farmers can benefit from matter, which is the “glue” or binding factor carbon sequestration through the use of in soil. In Iowa, water erosion contributes conservation tillage, crop rotation, the use of significantly to the degradation of soil quality. buffer strips, and permanent vegetation for The most effective way to minimize soil highly eroded soils. These benefits include erosion is through the use of conservation improved soil productivity, an improved tillage practices. The impact of no-tillage environment due to less erosion, and practices in improving soil quality in terms of improved physical and biological properties carbon content at the upper part of the soil of soil. Carbon credit is another benefit that profile is evident where permanent vegetation has been explored recently by many different has been established in grassy areas. Tillage entities. Carbon credit is worth exploring but can cause the loss of significant amounts of needs careful consideration. The issues of carbon (CO2 bursts) immediately after tillage. market value, policy, carbon monitoring The exposure of soil organic carbon to procedures, and management entities are aeration during soil erosion increases CO2 among those that need to be addressed when emissions. In addition, soil erosion can cause considering carbon sequestration and credits. carbon to accumulate with soil sediments and Carbon sequestration must be viewed as a be removed from the soil carbon pool. The long-term process in order to see meaningful 1786
  12. Int.J.Curr.Microbiol.App.Sci (2017) 6(2): 1776-1788 impacts of conservation tillage, residue Eswaran, H., Vandenberg, E. and Reich, P. management, manure and fertilizer use, crop 1993. Organic carbon in soils of the rotations, etc. Farmers, crop advisors, and world. Soil Sci. Society America J., 57: others, who deal with carbon sequestration 192-194. need to recognize that carbon sequestration is Gregorich, E.G., Drury, C.F. and Baldock, a reversible process. They must adopt a J.A. 2001. Changes in soil carbon under system that improves soil carbon long-termmaize in monoculture and sequestration as a long-term management tool legume-based rotation. Can. J. Soil Sci., because any short-term disturbance, such as a 81: 21–31. change from conservation tillage to Guo, L.B. and Gifford, R.M. 2002. Soil conventional tillage, will not achieve carbon stocks and land use change: a significant improvement in soil carbon status. meta analysis. Global Change Bio., l8: Therefore, farmers need to think long-term 345-360. when thinking about carbon sequestration. Haszeldine, R.S. 2009. Carbon capture and The overall benefits of soil carbon storage: how green can black be? Sci., sequestration need to be viewed as an 325: 1647-1651. opportunity to improve soil quality as well as Houghton, R.A. 1995. Changes in the storage the environment. of terrestrial carbon since 1850. In Lal, R., Kimble, J., Levine,E. and Stewart, References B.A. (eds.), Soils and Global Change. Lewis Publishers, Boca Raton, Florida, Bai, Z.G., Dent, D.L., Olsson, L., and USA. Schaepman, M.E. 2008. Proxy global Kimble, J.M., Lal, R. and Follett, R.R. 2002. assessment of land degradation. Soil Agricultural Practices and policy Use Manage, 24: 223-234. options for carbon sequestration: what Batjes, N.H. 1996. Total C and N in soils of we know and where we need to go. In the world. Eur. J Soil Sci., 47: 151-163. Agricultural practices and policies for Broecker, W.S. 2008. CO2 capture and carbon sequestration in soil eds. New storage: possibilities and perspectives. York, Lewis Publishers, pp 512. Elements, 4: 295-297. Kintisch, E. 2001. Should oceanographers Chu, S. 2009. Carbon capture and pump iron? Sci., 318: 1368-1370. sequestration. Sci., 325: 1595. Koonin, S. 2008. The challenge of CO2 Cramer, W., Bondeau, A., Woodward, F.I., stabilization. Elements, 4: 293-296. Prentice, I.C., Betts, R.A., Brovkin, V., Lackner, K.S. 2003. A guide to CO2 Cox, P.M., Fisher, V., Foley, J., Friend, sequestration. Sci., 300: 1677-1678. A.D., Kucharik, C., Lomas, M.R., Lal, R. 2004. Carbon emission form farm Ramankutty, N., Sitch, S., Smith, B., operations. Env. Intl., 30: 981-990. White, A., and Young, M.C. 2001. Lal, R. 2008. Sequestration of atmospheric Global response of terrestrial ecosystem CO2 into global carbon pool. Energy structure and function to CO2 and Env. Sci., 1: 86-100. climate change: results from six Lal, R., Kimble, J., Levin, E. and Stewart, dynamic global vegetation models. B.A. 1995. Advances in soil science: Global Change Biol., 7: 357-373. Soil management and greenhouse Debnath, S. and Bhatt, S.C. 2014. Carbon effect. Bocan Raton: Lewis Publishers sequestration: potential of Indian soils. pp. 93. Agrobios. News Lett., 68-69. Lal, R., Kimble, J.M., Follett, R.F., Cole, 1787
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