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Globally, agriculture productivity is challenged by abiotic and biotic stresses, but abiotic stresses in particular (Gong et al., 2013) affect spreading of plant species across different environmental zones (Chaves et al., 2003). The changing climate is expected to worsen abiotic factors globally and adaptation strategies need to be established for target crops to specific environments (Beebe et al., 2011). Connect between different stress factors will likely surge harm to crop yields (Beebe, 2012). Soil salinity is a major environmental constraint to agricultural productivity (Greenway and Munns, 1980; Rhoades and Loveday, 1990). High concentrations of different types of salts, including chlorides, carbonates, and sulfates of magnesium, calcium, potassium, and sodium, characterize different saline soil areas around the world. Moreover, for each type of naturally occurring salinity, constantly changing environmental conditions, such as temperature and precipitation, as well as agricultural practices cause rapid modifications in levels of salinity and salt distribution patterns. Sodium and chloride are the predominant ions in the vast majority of saline areas.

During evolution, various species of plants, known as halophytes, readapted to life in high-salinity environments, but a large majority of plant species grown in non-saline areas are salt-sensitive (referred to as glycophytes). These glycophytic plants, including the majority of crop species, differ greatly in their tolerance to salt stress (Greenway and Munns, 1980; Flowers and Colmer, 2008).

Sample Design

Sample design is a specific system for obtaining a sample from a given population. For the effective planning and sample survey, this sample design is the framework or road map that serves as the basis for the selection of the survey sample and affects many other important aspects of a survey as well. It is a definite plan for obtaining a sample from a given population. Sampling design refers to the procedure that the researcher would adopt in selecting items as the sample. Also, sampling design is a working plan that specifies the sample frame, sample size, sample selection and estimation method in detail. The blueprint for obtaining a sample from the sampling frame and this technique used in drawing a sample is known as sample design or sampling design. This whole process is done before the determination of data collection.

Introduction

In some practical field situations, the results are described by some percentages or proportions. In agricultural field conditions, if any disease prevalence is to find then in the form of percentage or proportion, we can say how much disease rate is present i.e., 10 % or may be any other. So, in those situations, we need to describe our results in proportions. Similarly, in many fields such as medical sciences, social sciences and other allied sciences this type of results in proportions we need to describe.

Yet now we have discussed probability sampling techniques in which sampling units are assigned with equal probabilities. But sometimes in practice if want to draw a sample with unequal probabilities i.e., every sampling unit is assigned with varying probabilities and we draw a sample from these units with the help of equal probability methods, then the results are not as much efficient as compared to unequal probability sampling.

Simple random sampling is a procedure wherein the chance of selection of every unit in the required sample is equal. However, the use of simple random sampling is not advisable when the units differ substantially in size as the significance of unit size is ignored.

The basic idea of this type of probability technique is that chance of each unit of a population being selected in the sampling is proportional to its size. The units vary significantly in size and the variable under study is largely related to the size of the unit. Therefore, the probabilities fixed for each unit are proportional to their sizes.

INTRODUCTION

Sapota [Manilkara zapota (L) P. Royen] commonly known as chiku in India, is an exotic fruit crop originated in Tropical America. The name sapodilla is derived from the Spanish word zapotilla, meaning “small sapote.” Tree have dark green beautiful radiating canopy with central flag having aesthetic values.It is a popular crop widely cultivated in most tropical countries. The cultivation of sapota is a profitable venture as it does not need much spraying, pruning and it is a long-life fruit tree. Moreover, the fruit fetches good price in market as it ripens in April and May in North India, when mango and litchi fruits are scarce. At international level in India crop attained an important place in fruit industry. In India this fruit species is cultivated only for its delicious fruit for table purpose but in South America, it is cultivated for chickle the “gutta parcha” which is used as base material for chewing gum.This is extracted from bark. Sapota fruit present a climacteric behavior. In India farmer from Bordi village near Gholwad, late Sri Gopal Rao Patil realized the commercial potential of this evergreen and ever fruiting tree and procured a few plants and began to propagate for distribution among poor farmers of this area and within short time it had spread from Palghar in Maharashtra to Amalsad in Gujarat. Subsequently commercial cultivation in his region was helped by lranis and Marwari settlers. The best sapota orchards in this area belong to lranis and Marwaris. It is from this area that this fruit went to various other parts of the country like Andhra Pradesh, Tamil Nadu, and Karnataka, Punjab and Haryana etc. In India crop become very popular among farmers as a cash crop. There is a possibility of extending cultivation of this crop into warm and humid climate of all tropical regions of the world. In India area under this crop increasing every year. Therefore, in recent years, it has attained the status of major fruit in peninsular India. Popularity of this fruit is on increase due to high production per unit area and continuous fruiting throught out the year.

Appendix-'K'    :    Supreme Court Directions on School Safety
    
Case Study    :    Kumbakonam School Fire Tragedy

1.    Major Branches of Horticultural Science

    
2.    Potential Production Zones of Various Horticultural Crops in India
    
3.    Indian Horticulture
    
4.    Current Production and Projected Demand of  Horticultural Products
    
5.    Extent of Value Addition in Fruits and Vegetables
    
6.    Horticulture as Profession
    
7.    Projected Demand for Horticulture Professionals in 2020
    
8.    Major Career Opportunities in Horticulture
    
9.    Level of Employment (%) in Horticultural Processing Sector
    
10.    Conclusion
        
References

Abstract: This article gives an overview of the possibility and scope of successful cultivation of medicinal and aromatic herbs as intercrops with multipurpose tree species under agroforestry conditions. The challenges are many. Sustainable production under any agroforestry system is the main goal to be achieved through short and long term strategies. Diversification of the existing conventional cropping sequences coupled with developing of suitable technology packages is the need of the hour to cope up with ever increasing demand for diversified products. The hypothesis is, if intercropping of annuals, biennials and perennial medicinal plants in association with fuel, fodder, timber, pulp, fruit trees including tree species with medicinal values on the farmland, an alternate land use system; can provide economically viable option for sustainable systems. This chapter describes the potential and benefits of medicinal plants based agroforestry. Our experience is that planting timber, fuel and fodder or fruit tree species in combination with medicinal crops paves the way for diversified products and better economic returns to the farmers. Multipurpose tree species outside the forest have played very important role in catering to the day to day requirements of the rural population. Different farming systems consisting of crops + trees have yielded encouraging results and have not only helped diversification but enhanced productivity of land per unit area. Intercropping medicinal and aromatic herb species further makes agroforestry more remunerative.

Introduction

Agroforestry offers both adaptation and mitigation options to climate change especially for the poor rural communities in the developing world. It is now getting ample attention from different investors, scientists, policy makers and international bodies due to its multiple benefits to the environment; and remain an important component of sustainable land use in agricultural production. Agroforestry provides economic, environmental, and social security to the vulnerable communities who are dependent on agricultural production for their livelihoods, and on forest/ trees for their energy requirement. Agricultual production is vulnerable to climate change, and there is a need to cushion these communities to be less vulnerable to climate change, or natural hazards. The suitable, sustainable and smart method is agroforestry based agriculture which offer host of ecosystem services to cope the vagaries of climate change, particularly in rural areas.

8.1 Introduction

Common onion, Allium cepa L., is a vegetable that is the most widely cultivated species of the genus Allium. It has been cultivated for more than 5000 years. However, its wild species do not exist. Allium is a Greek word. Onion is native of Central Asia. According to Vavilov onion originated in Pakistan, however, others opined it to have domesticated in the mountainous regions of Central Asia comprising Turkmenistan, Uzbekistan, Tajikistan, Afghanistan, Pakistan and north Iran. Jones and Mann proposed the area comprising Pakistan and Iran or South East Asia as the centre of origin. Onion is very important in cookery. 

11.1 Introduction

The word Raphanus has been originated from Greek, meaning quick appearing, refers to its very rapid germination and growth characteristics. It is grown chiefly for its succulent and fleshy edible taproot eaten raw as salad or cooked. The leafy tops are very rich in vitamins A, B and C, and minerals particularly calcium and iron. Major sugar present in radish is glucose. It is a short duration crop and highly productive, so preferred as intercrop or in relay and sequential cropping. 

15.1 Introduction

It is an important vegetable grown since long and used as fresh vegetable. It is an important legume vegetable rich in proteins. The crop is usually grown for its green pods which contains immature seed and are cooked as vegetable, alone or mixed with others. It prefers cool weather and it does not grow well during intense heat of the summer season, especially the wrinkled seeded cultivars which are tender, sweet and of much better quality than the smooth cultivars. 

17.1 Introduction

Lettuce is one of the most important vegetable crops in temperate countries. However, it occupies an important position for its cultivation in tropical and subtropical countries also. In the world, the largest consumer and producer is USA. Lettuce is also grown on large areas in South Eastern Australia, Japan, China, Israel, Northern Mexico, Chile, Argentina, Brazil and Peru. Probable ancestor of lettuce is Lactuca serriola L. The crop was spread throughout the 

20.1 Introduction

Asparagus is a herbaceous perennial plant with an erect branched stem growing to 1-3 m height and is grown in large areas in countries like USA, Germany, Spain and France, while India’s contribution is meagre. The tender shoots called ‘spears’ are used as vegetable and in preparation of soup. It is also eaten as salad. The canned and frozen spears are also used as processed foods. Once asparagus starts producing, it continues to give economic yield for 10-15 years. The tender shoots contain a white crystalline substance, asparagine, which is used in medicine as diuretic in cardiac dropsy and chronic gout. It has good potential as fresh vegetable.

SEED GERMINATION

Germination is the growth of a plant contained within a seed; it results in the formation of the seedling, it is also the process of reactivation of metabolic machinery of the seed resulting in the emergence of radicle and plumule. The seed of a vascular plant is a small package produced in a fruit or cone after the union of male and female reproductive cells. All fully developed seeds contain an embryo and, in most plant species some store of food reserves, wrapped in a seed coat. Some plants produce varying numbers of seeds that lack embryos; these are called empty seeds and never germinate. Dormant seeds are ripe seeds that do not germinate because they are subject to external environmental conditions that prevent the initiation of metabolic processes and cell growth. Under proper conditions, the seed begins to germinate and the embryonic tissues resume growth, developing towards a seedling.

A. Bhattacharya

2.1.    Seed Germination
    
    2.1.1.        Drought Tolerance in Plants
    2.1.2.        Osmotic Adjustment
    2.1.3.        Cell membrane Stability
    2.1.4.        Epicuticular Wax
    2.1.5.        Partitioning and Stem Reserve Mobilization
    2.1.6.        Salt Stress and Seed Germination
    
2.2.    Seedling Drought Traits
    
2.3.    Seed Germination Under Abiotic Stress

2.4.    Salt Stress and Seed Germination

2.5.    Seedling Growth

2.6.    Stress Effects on Seedling Growth
    
    2.6.1.        Temperature
    2.6.2.        Nutrition, Salinity, and pH
    2.6.3.        Water
    2.6.4.        Under Flooding Condition
    
2.7.    Drought Stress and Abscisic acid (ABA)
    
2.8.    Salt Stress on Seedling Length
    
    2.8.1.        Salt Stress on Seedling Dry Weight
    2.8.2.        Mechanism of Salt Stress on Germination
    2.8.3.        Root Establishment Methods
    
2.9.    Root Development
    
    2.9.1.        Root System Development and Abiotic Stress
    
2.10.    Root Development Under Abiotic Stress
    
    2.10.1.        Drought Stress
    2.10.2.        Regulation of Root System Architecture by Water Availability and Salinity Stress
    2.10.3.        Regulation of Root System Architecture by Nutrients
    2.10.4.        Phosphate Starvation
    2.10.5.        Nitrogen
    2.10.6.        Potasium and Iron
    2.10.7.        Meristematic Activity Regulation by Abiotic Stress
    2.10.8.        Waterlogging Stress
    2.10.9.        Salt Stress
    2.10.10.    Temperature Stress
    2.10.11.    Illumination Stress
    2.10.12.    Nutrient Deficiency or Excess
    2.10.13.    Heavy Metal Stress
    2.10.14.    Elevated Atmospheric Levels of CO2
    2.10.15.    Mechanical Stress
    
2.11.    Biochemical Regulation of Root
        
References

Seed handling ensures the potential utilization of seed material. Collection and utilization of quality seeds are indispensable in producing quality planting material and better seedling establishment. After selecting the quality seed source, collecting good quality seeds physiologically and genetically is considered the first step in seed handling, followed by processing seeds, testing, storage, and pre-treatment for germination. The main goal of seed handling is to attain an excellent seed survival rate. The chances of seeds getting damaged during any stages of seed handling because of careless or rough approaches are very high.

From the regeneration point of view, the quantity of seed production per tree correspondingly has a vital role to play. If considered virtually, only one successful seed (or two if the species is dioecious) would serve to replace the parent tree(s); hence the production of seeds during the lifetime of a tree is absurd. A full-grown Eucalyptus camaldulensis tree may produce a million or more seeds per year and live further, producing seeds for over a century. Each year’s production could help afforest

India is the largest goat producing countries in the world exhibiting rich diversity between and within goat breeds. The implementation of a genetic improvement programme requires a clear breed-based breeding objectives and selection criteria, tailored to the needs of goat farming community. Indigenous goat breeds bear a great degree of adaptability for climatic stress, tropical diseases and low quality feed resources, require low inputs for enhancing productivity, thus, little investment along with use of high merit bucks bring a great change in the economy of the farmers. There are currently 37 recognized goat breeds in the country which are kept mostly in small herds on extensive or partial semi-intensive feeding system. Productivity of Indigenous goats, however, observed less than their actual genetic potential and attributed to low input system, lack of suitable breed specific structural genetic improvement programme and poor adoption of technologies. A buck is the most important animal in the herd. A breeding male or buck contributes 50% of the genetic merit of the herd and also determine the future improvement rate.

Hygienic collection of semen is an integral part of the artificial insemination process. Semen collection implies mounting a teaser doe or a dummy. Therefore, proper semen collection deserves the utmost attention. Sexual efficiency is measured by the percentage or successful semen collections among attempted collections. When males are allowed to female teaser, the male exhibits characteristic behavioural symptoms such as sniffing, nudging or mounting at that time it is necessary for the operator to attempt an approach. This approach has to be done quietly to avoid a fear reflex in the male. The male, even if it mounts the female, deviation of its penis into the receptacle. Under the circumstances, the operator should not more from his squatting position, so that the male does not associate the two events. The animal generally comes back by itself to attempt remounting the female and will serve the artificial vagina. The operator should also stimulate the male by voice.

The semen evaluation is of great importance in predicting fertility of the male. There are several parameters to evaluate the semen quality. Usually bucks with good semen samples have good fertility and bucks with poor or very poor semen samples are invariably infertile or sterile. A single test is never sufficient to assess the semen quality and the examiner should be acquainted with several tests to evaluate the semen. The semen should be examined with in a shortest possible period after ejaculation and the ejaculate must be properly protected and handled until examination. Semen can be evaluated by following methods

1. Macroscopic test
2. Microscopic test
3. Metabolic test

Introduction

Sensors are the key components for enabling any IoT(Internet of Things) application. The concept of IoT came as early as 1990 but the practical implementations of the IoT technology is actually becoming possible as the cost of the devices that are needed to create any IoT application have reduced. Sensors are one of the major hardware components needed to form IoT systems and decrease in its price has given a forward leap in developing IoT applications. Sensors have to be uniquely identifiable devices with a unique device ip address so that they can be easily identifiable over a large network. These have to be active in nature which means that they should be able to collect real time data. These can either work on their own (autonomous in nature) or can be made to work by the user depending on their needs (user controlled).

Sequence Alignment

Sequence Alignment is the procedure of comparing two (Pair-wise Alignment) or more (Multiple Sequence Alignment) sequences by searching for a series of individual characters or character patterns that are in the same order in the sequences.

Significance: Discovering functional, structural and evolutionary information in biological sequences.

Introduction

The word ‘Sericulture’ is derived from the Greek word ‘sericos’ meaning ‘silk’ and the English ‘culture’ meaning ‘rearing’. It refers to the mass scale rearing of silkworm for obtaining silk from them. Mulberry sericulture involves production of silk using mulberry as the host plant. Silk is known as Resham in Hindi, Soie in French, Seide in German, Seda in Spanish, Seta in Italian, Tsi in Chinese, Soi in Korean, Knu in Japanese, Solk in Russian etc. It is regarded the queen of textiles as it is most elegant among all the  textile fibers with unparalleled grandeur, natural sheen, inherent affinity for dyes, high absorbance, light weight with soft touch and high durability.

The major requirement that distinguishes frozen semen/IVF laboratory from other laboratories is the need to maintain aseptic conditions. The wash up and sterilization of media and other equipments should be located at one end of the room and clean area for sterilize handling at the other end, and preparation, storage and incubation in between. The storage and incubation area should be near to the sterile working area.

In recent years, the introduction of laminar flow cabinets has been a great boon in providing a sterile working area and allows the use of unspecialized laboratory accommodation for culture work. For sterile work, area should be in a quiet part of the laboratory preferably in a cubicle where a laminar flow cabinet is suitably fitted. The area should be free from dust or draughts. Nothing should be stored on the laminar flow cabinet or bench used for sterile handling except most necessary equipments like holding pipettes etc. The laminar flow cabinets provide sterile air blown over the work surface. For laboratory, a horizontal laminar flow is more preferable as opposed to a vertical one because of ease of handling the ovaries etc. If an air curtain is provided at the door of the cabinet, introduction of dust etc. can be avoided. In India laminar flow are manufactured by companies like Clenzoids, Yorco etc, among others. The laminar flow size should be a minimum of 300 X 300 or 450 X 450 mm with a 12-18 in, square filter size).

The animals are mostly social ones and prefer living in herds. In each species there are certain rules for group survival, cohesion, defence and also for propagation. The basic patterns of male sexual behaviour appear to be innate in nature. Kids of both sexes are very often seen exhibiting sexual display during play and mounting is seen most commonly. In females the sexual receptivity is restricted to few hours or days near the estrous phase of the estrous cycle, while in males the sexual receptivity is grossly permanent. The physiological signals for arousal of sexual motivations originate from gonadal steroid balance. However, the secretion of gonadal steroids is not permanent. In males the androgen secretion is in the form of several peaks within 24 hours reflecting the pulsatile release of pituitary gonadotropins. However, the total amount of androgen in males is almost constant practically for day to day. In females the secretions of estrogens are restricted only during few days (follicular phase) of the estrous cycle.

6.1. Introduction

Food packaging has a significant contribution in preserving the quality of the food throughout the processing and storage. The package containing food should maintain the quality of the product for the longest time under particular environmental conditions. The quality of various food and beverages decline with the passage of time and food become unacceptable to consume. The time in which food deteriorates and become unacceptable is termed as shelf-life. The degradation of quality with time under storage conditions depends upon intrinsic as well as extrinsic factors. The shelf-life study of a product provides important information to manufacturer and consumer regarding the quality of the food product throughout the storage time.

The goat rearing on extensive rearing system has been practiced since ancestry for livelihood and nutritional security of poor, landless and marginal farmers of our country with the flock size ranging from 2-10 goats. However, in the recent past, goat rearing is shifting towards semi-intensive and intensive rearing systems for commercial purposes with flock size ranging from 25 to 500. The goats reared in small flocks needs minimal housing facilities following the scientific principles with low-cost structures. On the other hand, elaborate housing is generally recommended for goats raised under large scale commercial production systems. Separate housing arrangements for different categories of animals viz. growers, pregnant females, lactating females, breeding males, etc. are to be ensured for rearing goats scientifically for harnessing maximum output sustainably.

Abstract: Shifting cultivation locally called Jhuming is a part and parcel of tribal life of the North Eastern Hill Region of India and it has direct bearing with their socio-cultural system. It is a boon to the farmers as long as the jhuming cycle is sufficiently longer (10-15 years) as this would not only produce a good crop but also gives sufficient time for ecological restoration and biophysical balance. However, with the increase in population pressure on land the jhuming cycle is getting drastically reduced (3-6 years). As a result of this, soil health is getting degraded and overall ecosystem is in threat. Many important flora and fauna are in the verge of extinction. As we cannot run away from the problem at least thinking about posterity, we have to find a decisive solution immediately. Developing improved methods of jhum cultivation like proper bunding, residue recycling, use of high yielding varieties etc. are few short term options. However long term viable options would be proper land configuration like terraces, water harvesting, agroforestry, adoption of integrated farming system approach and above all education and awareness among the tribal farmers which would help in sustaining the ecosystem of the region.

A genome is an organism’s complete genetic signature and the collection of information that an organism can pass on to its offspring. Genomics, the study of the structure, function, and evolution of entire genomes is principally dealing with genetic information which helps us to understand how organisms and ecosystems work, how theymalfunction, or how they might be melded to human needs. The model organisms used in genomics have, in general, small genomes and short generation times. To meaningfully analyze the gene-to-phenotype relationships, a large amount of sequencing information is necessary. Progress in DNA sequencing technologies leads to accumulate Information about structures of genomes (Mohan Kumar, 2007).

HISTORY OF INSECT GENOMICS

Commencing from the publication of the entire nucleotide sequence of the genome of Haemophilus influenzae in 1995, a complete genome sequence of many organisms, including lower and higher eukaryotes, have been reported. The cost-effective way to get sufficient sequence information to address the questions is to sequence a high-quality reference genome and then map sequences from other genomes onto the reference sequence. Insects constitute the vast majority of known species with their importance including biodiversity, agricultural, and human health concerns. Hence, a study of Insect genomics is imperative to elucidate information to other organisms.

Abstract: Stall feeding to cattle is not practiced in the Andaman Islands since generations. In the morning, after milking, cattle are allowed to go for free range grazing in the nearby forest or coconut arecanut orchards. But, like mainland territory the cattle do not form herd. They are trained in such a way that come back home during evening where they are fed with concentrate before the milking. Coconut and arecanut orchards occupying more than 14000 ha land are second major land use after forest in the Islands. The forage production in the grazing lands are not sufficient to meet out the demand of huge livestock population particularly during the lean period, form January to April. An attempt has been made to know the effect of four N fertilizer levels (0, 60, 80 and 120 kg ha-1 N) on net soil N mineralization rate (NMR) and soil moisture (SM), and shoot biomass (SB), FP, shoot biomass/root biomass ratio (SB/RB), N concentration in SB, N uptake and nitrogen use efficiency (NUE) of three grasses [Guinea (Panicum maximum Jacq.), Para (Brachiaria mutica (Forssk) Stapf) and Hybrid-napier (Pennisetum purpureum Schumach.)] under three canopy positions [under canopy (UC, representing high shade), between canopy (BC, representing low shade) and open] of coconut trees (Cocos nucifera L.) in a coconut based silvopastoral system in the Island conditions. The study has revealed that the tree reduces light 59% under UC and 32 % under BC positions, but the N fertilizer levels increase NMR by 11 to 51 % under UC and 3 to 44 % under BC positions compared to the open. SM does not differ across the canopy positions

Simple Random Sampling (SRS)

Simple random sampling is probability sampling and refers to a technique of sampling where each and every unit of the population have an equal and independent opportunity of being selected and included in the sample during the sampling. In the SRS the selection of the sample depends on the chance factor and is also known as the method of probability sampling.

There are two ways in which SRS can be performed:

• SRSWR: Simple Random Sampling With Replacement
• SRSWOR: Simple Random Sampling Without Replacement

1. Introduction

Size reduction is applied to all the ways in which particles of the solids are cut or broken into smaller pieces. Size reduction operation of solids is referred to as 'Comminution", some of the common comminutive processes are - crushing, grinding, milling, mincing, and dicing. Breaking down of large sized particles of food substances into smaller particles is a common unit operation in many food processes, e.g. wheat flour, turmeric powder, spices, etc. are mostly used in powdered form. Some ofthe common objectives that are fulfilled by size reduction are:

16.1. INTRODUCTION

Millets are a large part of the basic diet for farm households in the world's poorest people in the poorest countries. The production of millets on average for the 5 years have been given in Table 16.1. Top consuming countries are India, Nigeria, Niger and China. However, just because a country is a top global consumer does not mean that millet is a significant source of calories for them. India and China are rank as the 1st and 4th consumers of millet, but due to their population size they rank 11th and 38th in per-capita consumption, accordingly.

Millet particularly the finger millet) is an excellent dietary source of calcium, iron, manganese, and methionine-  an amino acid lacking in the diets of hundred of millions of the poor who live on starchy foods such as cassava, plantain, polished rice, and maize meal. Millet use is diverse, including in cereals (including porridge and kasha), soups, breads and stuffings, fermented beverages, and baby food.

4.1    Urban Issues
    
4.2    Environmental Ethics - Issues and Possible Solutions
    
4.3    Water Conservation
    4.3.1 Rainwater Harvesting
    
4.4    Greenhouse Gases and their Sources
    4.4.1 Climate Change
    4.4.2 Global Warming
    4.4.3 The Greenhouse Effect
    4.4.4 Consequences of the Greenhouse Effect
    4.4.5 Acid Rain, 176
    
4.5    Ozone Layer Depletion
    
4.6    Nuclear Accidents
    
4.7    Waste Reclamation
    
4.8    Consumerism and Waste
    
4.9    Forest (Conservation) Act 1980
    
4.10    Wildlife Protection Act
    
4.11    The Air  (Prevention and Control of Pollution) Act 1981
    
4.12    Water (Prevention and Control of Pollution) Act 1974
    4.13    The Environment (Protection) Act, 1986
    4.14    Environmental  Laws

Introduction

In general economic model, technological change in agriculture is expected to cause the commodity supply curve to shift down and out against a stationary demand curve, giving rise to an increase in quantity produced and consumed, and at a relatively lower price. Agricultural economists have used supply and demand models of commodity markets to represent agricultural research impacts, beginning with Schultz (1953) and Griliches (1958), with important subsequent contributions by Duncan and Tisdell (1971), Akino and Hayami (1975), among others. Such a model is explicitly used in many studies. However, low crop productivity, food insecurity, hunger and malnutrition; inadequate farming knowledge and skills, implements and inputs are characteristic of smallholder agriculture in developing countries including India. Many researchers argue that conservation agriculture can guarantee higher crop productivity, food security, improved net income of the farmers and environmental protection, better than the traditional systems of cultivation practices.

ABSTRACT
It is impossible to envision a world without energy provisions and has become inevitable and an integral part of a nation’s prosperity. It has unparallel contributions towards the socioeconomic empowerment, industrial growth, and technological advancements, as also in mitigating greenhouse gas (GHG) emissions. Judicious utilisation of energy sources without infringing upon the sustainable energy demand is the need of the hour. Taking India’s huge bovine strength into account, biogas technology has the potential to transform the standard of living of rural millions. Effectively implementing the Govt. of India’s National Biogas and Organic Manure Programme (NBOMP) could save precocious demand on electricity, fertiliser and firewood while promoting self-sustainable organic farming. In this chapter, the cost and benefit analyses of biogas technology (involving biogas plants of different capacities) are discussed along with the long-term approach at the grassroots level to promote digested slurry for organic farming. The commercialisation and carbon crediting of biodigester technology is also narrated. It is necessary to chalk out a revenue model to commercialise slurry at the grassroots level to economically empower the beneficiaries, from family-type to industrial-scale biogas plants. Small-scale biofertiliser hubs at district level may be organised to collect dry slurry from the beneficiaries and process them further to make it market-ready through entities operating at the national level developing manure for agricultural practices, as also feeding materials for animal husbandry practices.

Biology is in the middle of a major paradigm shift driven by computing technology. Due to the impact of information technology, biological sciences have been rapidly becoming much more computational and analytical. Rapid progress in research in the field of genetics and related field combined with the tools provided by modern biotechnology has generated massive volumes of genetic and protein sequence data over last two decades. Compilation, storage, analysis for extraction of information and knowledge from this data becomes a challenging task as usual analytical procedures are not directly applicable to these data sets.
 
Bioinformatics has been defined as a means for analysing, comparing, graphically displaying, modeling, storing, systemising, searching, and ultimately distributing biological information, which includes sequences, structures, functions, and phylogeny. Thus, bioinformatics may be defined as a discipline that generates computational tools, databases, and methods to support genomic and post-genomic research. It comprises the study of DNA structure and function, gene and protein expression, protein production, structure and function, genetic regulatory systems, and clinical applications. Bioinformatics applications need knowledge from computer science, mathematics, statistics, medicine, chemistry and biology.

Introduction

Soil organisms contribute to the maintenance of soil quality in that they control the decomposition of plant and animal materials, biogeochemical cycling of elements, including nitrogen fixation; the formation of soil structure and the fate of organics and inorganics applied to soils. Soils and their biodiversity thus play a critical role in maintaining soil health. Non-return or diminished return of organic matter and residues deprive the soil biota of their food with loss of soil health and fertility. A large, diverse, and active population of soil organisms is the most important indicator of a healthy soil. The effects of physical and chemical degradation of soils are obvious. But the effects of biological degradation which is caused due to loss of specific soil organic matter (SOM) fractions (and consequently the loss of microbial species/communities dependent on them for nutrition) as well as and specific toxicity influences on soil flora and fauna are insidious. Proper management of soil biodiversity will help in sustainable agriculture and reduce the cost of external inputs especially for nutrient supply and crop protection.

Introduction

Soil biology is the study of the complex system of interrelationships existing among living organisms and their abiotic (physical and chemical) and biotic (living) environments and themselves. The abiotic factors in the environment determine the ability of organisms to live and reproduce. The chemical and physical sampling and analyses provide a broad picture of the parameters that define the aquatic environment. Biological investigation of soil can determine the extent of soil function and activity. To address environmental issues and increase land’s productive potential, we must now go beyond erosion control, soil fertility enhancement and management for soil quality.

Introduction

Carbon is an essential building block of life. It has always been transported from one form or ecosystem to another as a basic part of natural processes. Examples include its transport, through soil erosion, into aquatic ecosystems, or the undersea formation of limestone, the chief component of which is carbon. Much of the world’s carbon is held in soils, including agricultural soils. Another significant carbon pool is in the atmosphere, as carbon dioxide. Ever since agriculture began, between 7,000 and 10,000 years ago, the balance between these two pools has been changing. The loss of soil carbon through soil disturbance has augmented the atmospheric carbon pool. Since about 1750, the burning of fossil fuels has accelerated the process. Carbon dioxide is the largest single agent of climate change.

Climate change is a major issue facing society today with extensive studies being undertaken to find ways to mitigate its effects and impacts in the future. A key factor contributing to climate change is excessive levels of greenhouse gases in the atmosphere and global efforts are focussed on both reducing the emissions of greenhouse gases and increasing the storage (sequestration) of atmospheric carbon.

Introduction

Increasing carbon content in the soil, through better management practices, produce a number of benefits in terms of soil biodiversity, soil fertility and soil water storage capacity and hence productivity. Soil carbon sequestration through the restoration of soil organic matter can further reverse land degradation and restore soil “health” through restoring soil biota and the array of associated ecological processes. In particular, through improved soil water storage and nutrient cycling, land use practices that sequester carbon will also contribute to stabilizing or enhancing food production and optimizing the use of synthetic fertilizer inputs, thereby reducing emissions of nitrous oxides from agricultural land. Conservation tillage practices also reduce significantly the use of fuel and hence gaseous emissions. Soil carbon sequestration is thus very cost effective and could take effect very quickly (FAO, 2008). It also constitutes a valuable win-win approach combining mitigation (CO₂ is removed from the atmosphere) and adaptation, through both increased agro-ecosystem resilience to climate variability and more reliable and better yields (production and income generation). Under climate change scenarios, increased temperature may enhance soil organic matter mineralization in colder regions of the world, releasing carbon dioxide from soils (FAO, 2008). Improved soil management will mitigate the effects of global warming by improved and permanent soil cover. Soil carbon storage was hitherto left out of international negotiations because of envisaged difficulties of validation of amounts and duration/permanency of sequestration. 

Carbon sequestration implies removing atmosphere carbon and storing it in natural reservoirs for extended periods (Lal, 2011). Soil carbon sequestration is the process of transferring carbon dioxide from the atmosphere into the soil through crop residues and other organic solids, and in a form that is not immediately remitted. This transfer or “sequestering” of carbon helps off-set emissions from fossil fuel combustion and other carbon-emitting activities while enhancing soil quality and long-term agronomic productivity. Soil carbon has gained increased interest in the recent past owing to its importance in carbon sequestration studies and its potential impact on sustainable crop production. However, accuracy in estimating soil carbon sequestration to determine best management practices is hindered by inherent variability of soil properties (Srinivasarao et al., 2008 and 2009b). Maintaining or arresting the decline in soil organic matter (SOM) is the most potent weapon in fighting against soil degradation and for ensuring sustainability of agriculture in tropical regions. In India, 65 per cent of agriculture is rainfed, covering the categories of arid, semi-arid and sub-humid climatic zones. Consequences of depletion of organic matter are poor soil physical health, loss of favorable biology and occurrence of multiple nutrient deficiencies. It was stated that in rainfed arid, semi-arid and sub-humid tracts, next to poor rain water management, depletion of nutrients caused by organic matter deficiency is an important cause of soil degradation. Improving organic matter is, therefore, crucial to sustenance of soil quality and future agricultural productivity. Humus is known to favor many useful physical, chemical and biological processes that occur within the soil (Srinivasarao et al., 2011c). Accordingly, 

INTRODUCTION

Soil is one of the most important factors associated with the success or failure of fruit production. Orchard soil management refers to those practices in the soil that aim at getting maximum productivity/production of quality fruits within the limits of soil, water and fertility management over the years. The decision regarding the practices of orchard management should always be taken well in advance before planting of an orchard. The practices for orchard management should be executed in a timely manner during the lifetime of the orchard. An efficient orchard management system always ensures higher return to the grower. However, no single management practice can be recommended for all orchards. The management systems varies from orchard to orchard, locality to locality, soil to soil, from one set of climatic conditions to another set of climatic conditions etc. These systems also have their own merits and demerits. Thus the choice of best suitable system depends on many factors such as climate, topography, rainfall, tree spacing, planting system/ orchard design, root depth of tree, economic condition of orchardists, fertility status of soil and type of main fruit crop etc.However, it should be combined with pruning, nutrient and water management, provision for pollination, fruit thinning and disease and pest management in order to obtain desirable tree growth and vigour with the aim to promote precocity with high productivity. The objectives of an ideal soil management system should be:

5.1. Nature and role of soil enzymes
    General account
    Role in terrestrial ecosystems
    Role in aquatic ecosystems

5.2. Environmental conditions and microbial enzyme activity

Abstract: This chapter reports soil and nutrient loss due to water erosion from five major land uses, i.e. vegetable fields, coconut plantation, arecanut plantation, home garden and moist evergreen forest on the undulating topography of the island. Soil loss under the land uses was quantified using replicated runoff plots. Vegetative methods, i e Gliricidia hedgerow + crop, hedgerow + mulch + crop, hedgerow + mulch + crop + grass barrier, for vegetable field under till conditions, and Pueraria cover crop (coconut + Pueraria phaseoloides  cover crop) for coconut plantation were tested to know their potential to arrest soil erosion in the respective system. Soil loss from the vegetable field under No till conditions, coconut plantation, arecanut plantation, home garden and forest was 3.8, 12.4, 10.6, 8.4 and 2.3 tonnes/ha, respectively. Soil working in vegetable fields (till + crop treatment) provoked soil loss to124 tonnes / ha. Erodibility was the lowest (0.06) in the forest and highest (0.26) in the vegetable field under till condition.  Among the nutrients, the highest loss, across the treatments, occurred for nitrogen and lowest for phosphorus. The hedgerow alone in vegetable fields reduced the soil loss substantially (66 %). However, it together with mulch and grass barrier reduced the soil loss nearly equal to that found in the forest. Like wise, Pueraria cover crop (19 years old) brought down the soil loss under the coconut plantation equal to that in the forest. These observations suggest that Gliricidia hedgerows for vegetable cultivation and cover crop for coconut plantation may be good vegetative methods for soil erosion control in the island.

Abstract

In a developing country like India with exploding population pressure and shrinking availability of resources per capita, agricultural intensification maintain soil health is the only way to solve hunger and poverty. Soil is a fundamental resource base for agricultural production systems. Besides being primary medium for crop growth, soil functions to sustain crop productivity, maintain environmental quality and provide for plant, animal and human health. Soil organic matter (SOM) content is frequently identified as a primary attributes of soil quality assessment. It is evident that SOM influences various soil physical,chemical and biological properties. Besides, SOM serves as a slow release reserviour for macro-, secondary and micronutrients to plants.

Soil is formed by disintegration and decomposition of rocks, minerals and organic matter, Soil is a habitant for plant growth and serves as a storehouse of water and food nutrients for plants, Soil is not same everywhere and varies morphologically, physically, chemically and mineralogically from one point to another both in horizontal and vertical directions. Development of soil informatics is necessary to classify the soils, to assess the productivity of soils for various crop productions and to use the soil for various purposes such as land capability classification, soil irrigability classification, soil rating and soil mapping.

Morphologically soil may appear red, yellow, black, brown or ashy in colour. Soil may vary from sandy to clayey in texture. Depending upon the nutrient reserve capacity, the soil may be fertile or infertile. On the basis of climate, a soil may be classified as laterite soil. Red earth and red loam soil, podzol soil or desert soil.

Different kinds of soil contain minerals of various types and amounts and so exhibit distinct physio co-chemical properties. Although various methods have been used in the past to classify the soils, the most modern and scientific methods is based on dominants pedogenic processes acting on a place to from a soil. The new method of soil classification has two important characteristics-Firstly soil classification is based on certain diagnostic parameters which could be estimated quantatively, and secondly depending on diagnostic parameters, a scientific method is being followed to classify a soil from higher to lower levels such as order, suborder, great group, subgroup, family and series.

Introduction

Soil organic matter is an important component of soil quality and productivity; however, its measurement alone does not adequately reflect changes in soil quality and nutrient status. Instead, measurements of biologically active fractions of organic matter, such as microbial biomass carbon and nitrogen, and potential C and N mineralization, could better reflect changes in soil quality and productivity that alter nutrient dynamics. Therefore, measuring microbial biomass is a valuable tool for understanding and predicting long-term effects on changes in land use and associated soil conditions.

Introduction

The basic principle of conservation agriculture is to minimize soil disturbance in order to stabilize the soil structure, increase the fertility and balance the eco-system. Applied together, conservation agriculture practices – no tillage, permanent soil cover, use of crop cover and crop rotation, residue management- have complementary positive outcomes; no tillage maintains soil structure and biological activity; a permanent soil cover protects the soil surface from erosion and creates a stable and favourable micro-climate; cover crops and residue management provides organic matter, reduce soil erosion and improves soil fertility. Management of the soil water balance should be considered as a positive for cover crops and improvement of soil water infiltration, reduction in soil water evaporation, and decreasing water extraction from the soil would impact subsequent plant growth.

1.     Concentration