Preface
Page: i-i (1)
Author: Rubab Sarfraz and Christopher Rensing
DOI: 10.2174/9789815238068124010001
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Endorsement
Page: ii-ii (1)
Author: Rubab Sarfraz and Christopher Rensing
DOI: 10.2174/9789815238068124010002
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The Science of Biochar Production: Understanding the Formation and Characteristics of Biochar
Page: 1-16 (16)
Author: Rubab Sarfraz, Muhammad Tayyab*, Awais Shakoor, Muhammad Waqas Khan Tarin and Iqra Sahar
DOI: 10.2174/9789815238068124010004
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Abstract
Mineral fertilizers have been associated with the accelerated decomposition
of organic matter in the soil. This rapid decomposition primarily affects organic
materials such as plant residues and other organic substances present in the soil.
Biochar, produced by the pyrolysis of biomass, offers a sustainable solution to enhance
soil fertility and crop productivity. Biochar has a one of a kind potential to improve soil
health and counteract global climate change. Its distinct qualities, such as high carbon
content and the potential to promote soil health, make it an efficient, environmentally
friendly and cost-effective material for overcoming global food security and increasing
temperatures. Biochar can be produced using a variety of biomass materials and at
various temperatures, resulting in a wide range of variations in the final product.
Because of variations in its physicochemical attributes, such as microporosity, surface
area and pH, biochar can be customized for specific applications. The pyrolysis
temperature, heating rate, residence time, and biomass used during production all have
a strong influence on the structural configuration and elemental composition of
biochar. According to research, biochar produced at high pyrolysis temperatures has
high ash, phosphorus, and potassium concentrations. Furthermore, many important
macro and micronutrients, such as calcium, magnesium, iron, and zinc, have been
found to be positively associated with increasing temperature. Biochar produced at low
pyrolysis temperatures, on the other hand, provides relatively more available nutrients
in the soil and can help to reduce carbon dioxide emissions. Biochar produced at high
pyrolysis temperatures has a stronger affinity for organic contaminants due to its
increased surface area, hydrophobicity, microporosity, high pH, and low dissolved
organic carbon. It is important to note that the properties of biochar should be thoroughly assessed before application due to the wide variability of biomass
resources and pyrolysis conditions. Furthermore, biochar production should be tailored
to the intended application in soil to maximize its efficacy.
Effect of Biochar on Soil Properties
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Author: Shazia Iqbal*, Humaira Aziz, Munaza Naseem and Muhammad Irfan
DOI: 10.2174/9789815238068124010005
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Abstract
Soil is the most significant source and home of many nutrients and
microflora. There is an urgent need to maintain sustainable agricultural production
methods due to the rapid deterioration of agricultural areas and soil quality because of
population growth and excessive use of chemical fertilizers. Biochar is a solid,
carbonaceous material produced under a limited oxygen environment. Nowadays, it is
considered a potential amendment in comparison to inorganic fertilizers as they affect
soil health. It not only improves plant growth but also maintains soil health by
optimizing soil's physical (e.g., bulk density, surface area, hydraulic properties, and
water availability) and chemical properties (e.g., pH, electrical conductivity, cation
exchange capacity, and organic matter). Keeping in view the effects of biochar on soil
quality indicators, in this chapter, we will discuss the potential of biochar in restoring
soil physical and chemical health.
Impact of Biochar on Soil Organisms
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Author: Bushra Nisar Khan*
DOI: 10.2174/9789815238068124010006
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Abstract
Soil organisms are very important to improve soil fertility and maintain a
natural balance between soil nutrient cycles, enzyme activities and biological
transformation of complex substances. Typically, one gram of soil contains more than
90 million bacteria, which helps plants in nutrient uptake by converting them into
forms that are available to the plants. People tend to think negatively of microbes
because they are unaware of how important they are, even though they frequently
behave as disease-causing agents. Similarly, the role of soil macroorganisms in
improving soil structure and nutrient movement is equally significant. The use of
biochar as an exuberant carrier of soil organisms in the soil ecosystem has been widely
studied. Therefore, in this chapter, we will emphasis the types and functions of macro
and microorganisms in the soil, the impact of biochar on soil organisms, nutrient
cycling and enzyme activities.
Impact of Biochar on Plant Pathogen Control
Page: 64-81 (18)
Author: Adnan Akhter*, Muhammad Taqqi Abbas, Waheed Anwar, Tiyyabah Khan and Hafiz Azhar Ali Khan
DOI: 10.2174/9789815238068124010007
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Abstract
It has been reported that organic amendments can lessen the impact of
pathogen-caused plant diseases. Researchers have been looking for alternative
materials for growth mixes for plants, especially for pots, as a result of the growing
demand for substrates without soil and the escalating environmental concerns
associated with the utilization of resources that are not renewable, such as peat. A
variety of biochar effects help to prevent root or foliar fungal infections by altering root
exudates, soil characteristics, and nutrient availability, all of which influence the
proliferation of antagonistic microorganisms. Biochar's induction of systemic plant
defenses in the roots to combat foliar pathogenic fungus and the activation of stress
hormone responses are all indicators of coordinated hormonal transmission within the
plant. Additionally, nematodes and pest insects are controlled by biochar. The primary
mechanisms of action of plant-parasitic nematodes are changes in the diversity of soil
microbes, the release of nematicidal chemicals, and the development of plant defenses.
In this chapter, we looked at how the health and disease of plants are affected by
biochar as a component of the growing medium. Biochar treatments show a lot of
promise, according to this study, but not enough research has been done to support
their widespread use as a soil supplement in modern agricultural systems. More
research on the processes that drive biochar disease suppression and long-term field
tests are required to make biochar a safe, effective, and cost-effective tool for
controlling plant diseases.
Impact of Biochar on Crop Yield and Production
Page: 82-108 (27)
Author: Sajid Ali, Adnan Zahid*, Mukhtar Ahmed, Ammara Fatima, Asma Ayub, Aisha Zahra and Aamir Shahzad
DOI: 10.2174/9789815238068124010008
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Abstract
Urbanization and population growth have significantly impacted the health
and fertility of the soil, putting more strain on farming systems. It is becoming
increasingly necessary to use chemical pesticides and fertilizers in order to meet the
world's growing food demand. There is a significant contribution to greenhouse gas
emissions from these practices. The use of biochar as a multifunctional carbon material
is being extensively investigated in order to address the problems of improving soil
fertility and lowering climate change at the same time. In order to enhance seed
germination and seedling growth, biochar is applied at a low level. In addition to
changing the abiotic and microbial activities of the rhizosphere, biochar increase the
mineralization of nutrients and make them more available to plants. By reducing heavy
metals and increasing plant resistance to environmental stresses, biochar increases plant
resistance to pathogens and abiotic challenges. By providing an in-depth analysis of
biochar's impacts on crop physio-morphological traits, soil’s physio-chemical
properties and productivity, as well as ways toreduce environmental problems were
determined. As a result of this chapter, biochar can be produced in a way that is
efficient and serves the purpose that crops and soil need. Increasing crop production,
assuring food security, and improving environmental management may all benefit from
it.
Environmental Implications of Biochar
Page: 109-125 (17)
Author: Munaza Naseem*, Shazia Iqbal, Hina Malik, Muhammad Awais, Sarvet Jehan and Shazia Jabeen
DOI: 10.2174/9789815238068124010009
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Abstract
Biochar is a form of charcoal that is produced by heating organic material in
the absence of oxygen. It has been studied as a potential tool for mitigating climate
change by sequestering carbon in the soil, improving soil fertility, and reducing
greenhouse gas emissions from agriculture. However, the environmental implications
of biochar production and use are complex and depend on various factors, such as the
feedstock used, the production process, and the intended use. One potential benefit of
biochar is its ability to sequester carbon in the soil for long periods, potentially
reducing greenhouse gas emissions. However, the amount of carbon sequestered and
the duration of sequestration may vary depending on factors such as soil type, climate,
and management practices. Additionally, there is a risk of releasing greenhouse gases
during production, particularly if the feedstock is not properly managed. It can also
improve soil fertility by increasing nutrient retention and reducing nutrient leaching.
However, the effectiveness of biochar for this purpose may depend on factors such as
soil type, climate, and the properties of the biochar itself. There is also a risk that the
use of biochar could lead to soil acidification or other unintended consequences. The
use of biochar in agriculture could also have implications for water resources. While
biochar has the potential to reduce nutrient leaching, it could also increase runoff and
erosion if not properly managed. Additionally, the production process could require
significant amounts of water, particularly in areas where water resources are already
limited. Overall, the environmental implications of biochar depend on various factors
and require careful consideration. While biochar has the potential to provide a range of
environmental benefits, it is important to ensure that its production and use are
sustainable and do not lead to unintended consequences.
Potential Limitations of Biochar
Page: 126-138 (13)
Author: Rashid Mahmood, Ammara Arooj and Rubab Sarfraz*
DOI: 10.2174/9789815238068124010010
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Abstract
Agriculture nowadays confronts several challenges due to the increase in
global food demand and environmental concerns. In recent years, there has been a
significant increase in the application of biochar in agricultural soils. Biochar has been
shown to have various benefits in enhancing soil quality and crop yield. Biochar can be
used to boost up the soil carbon pool, as an adsorbent to clean up soil contamination
and to decrease greenhouse gas (GHG) emissions. The fate of biochar in agricultural
soils has been found to depend on a few factors, including pyrolysis temperature,
feedstock, soil type, and biotic interactions. Biochar in freshwater systems and as a
source of black carbon emissions, however, calls for more research because they can
have detrimental effects on the climate and can also cause toxicity. Several techniques
used by biochar systems (such as surface albedo, black carbon emissions from soils,
etc.) or nutrient leakage into water bodies can also have adverse impacts on the climate.
Environmental assessment studies sometimes overlook these elements due to the
complexity of the implications. Specific emission factors derived from diverse climate
and ecosystem models are essential for improving the characterization of the
heterogeneity of varying local conditions and combinations of feedstock, pyrolysis
processes, soil conditions, and application practices. These factors can help improve
the resolution and accuracy of environmental sustainability analysis of biochar systems.
Moreover, the use of biochar has been shown to be harmful in several circumstances,
directly or indirectly deteriorating the agricultural soils and our environment.
Moreover, the variability in feedstock costs can pose challenges to the economic
viability of large-scale biochar production. Government policies and incentives that
support sustainable feedstock management and biochar production can play a
significant role in overcoming this hurdle and promoting the broader use of biochar for
its environmental and agricultural benefits. This chapter evaluates the limitations
associated with biochar production and its application in agricultural soils and the
environment.
Future Perspectives
Page: 139-140 (2)
Author: Rubab Sarfraz and Christopher Rensing
DOI: 10.2174/9789815238068124010011
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Subject Index
Page: 141-146 (6)
Author: Rubab Sarfraz and Christopher Rensing
DOI: 10.2174/9789815238068124010012
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Introduction
Biochar - Solid Carbon for Sustainable Agriculture explores the potential of biochar, a form of charcoal produced from organic materials, to improve soil health, increase crop yields, and mitigate climate change. This book offers a comprehensive overview of biochar and its applications in sustainable agriculture. The book begins by introducing the concept of biochar and its historical use in agriculture. Next, the content deals with the production methods and properties of biochar, providing insights into its chemical composition and physical characteristics. Subsequent chapters explore the diverse applications of biochar in agriculture, including its role in soil fertility improvement, carbon sequestration, and pollution remediation. Case studies and practical examples illustrate the effectiveness of biochar across different agricultural settings. The authors also discuss the potential challenges and future directions of biochar research and application. This book is essential reading for agronomists, soil scientists, environmental scientists, farmers, policymakers, and anyone interested in sustainable agriculture and climate change mitigation strategies.