Synopses & Reviews
Plant nutrition in greenhouse cultivation differs in many essential aspects from field crops and justified the development of a special publication on this subject. The high productions realised and the specific produce quality requirements ensure high uptakes of nutrients and a careful tuning of the application. The covering with glass or plastic is responsible for specific climatic conditions, which in modern greenhouse can be fully adjusted to the requirements of the crop by automatic climate control. The natural precipitation is excluded, thus, the water has to be applied in greenhouses by artificial irrigation of water from different origin. On thing and another involves that the growing conditions are more or less completely controlled. This especially holds when the crops are grown in substrates.The high uptake of minerals in greenhouses requires high fertilizer additions. The quantities absorbed by many crops are that high, that it is impossible to supply the required quantities of nutrients as a base dressing at once. Therefore, top dressings are common practice and are carried out together with the supply of the irrigation water. Therefore, fertigation is common practice and in greenhouses already for many years. Specific systems have been developed for the application of the right concentrations to keep the level of nutrients in the root environment on the optimum level for the performance of the crop.Beside the management of the nutrient application, greenhouse growers also need a close control on the salt accumulation. This accumulation is closely connected with the quality of the irrigation water. Moreover, also the addition of the fertilizers plays a role in the salt accumulation in the root environment. Therefore, choice of the fertilizers used is important to prevent accumulations of residual salts possibly supplied with the fertilizers. On the other hand, for a number of crops the level of fertilizer supply is not only focussed on the nutrient requirements, but also utilized to realize a certain salt concentration in the irrigation water. In this way the osmotic potential of the soil solution is affected and this characteristic is an important tool for the grower for the regulation of the growth of the crop and the quality of the produce. When the salinity passes certain threshold values, the growth and production of crops is reduced, but the quality of the harvested produce of some crops is improved. Such regulations are very precisely adjusted to the crops grown and to the growing conditions in the greenhouse. Another line is the development of sustainable production methods. For the main subject discussed in this book, namely plant nutrition, methods for an optimum use of fertilizers with a minimum environmental pollution were developed last decennia. In this field the development of the cultivation in substrates offered excellent possibilities for an optimal use of water and nutrients. With this growing method it has been proved that it is possible to grow greenhouse crops without any discharge of minerals to the environment. The conditions required for such cultivation are thoroughly discussed. Moreover, growing in substrates offers suitable opportunities for optimization of yield and quality, because of the adequate control on the conditions in the root environment, like the supply of water and nutrients. However, this requires a perfect management of water and nutrient supply. Not only for the fact that plants are grown in very small rooting volumes and therefore, mistakes with irrigation and fertilizer supply easily will damage the crop, but also for the fact that the fertilizer supply is complicated. For substrate growing it is not enough that some nutrient elements are controlled, like with soil grown crops, but the full packet of nutrients essential for plant growth will be kept in view. This means that the addition of six macro nutrients and at least six micro nutrients will be regulated, with respect to the right concentration and mutual ratios in the irrigation water. Physical and chemical properties of substrates essentially differ and a right use of these properties is necessary for a right interpretation of the nutrient and salinity status. To this purpose the grower is supplied with detailed recommendations developed by the research stations founded in The Netherlands. The horticultural research stations in The Netherlands developed numerous tools to the growers often in cooperation with the horticultural industries and laboratories. An example of such cooperation is the development of soil and substrate testing methods by the research stations. These methods offered excellent possibilities for a frequent control for the salt and nutrient status in the root environment. Together with these methods schedules for interpretation and recommendation were developed and adjusted for computerized information to the growers. The book contains information about soil testing methods, in relation to a universal interpretation based on the composition of soil solution. Methods for interpretations of tissue tests are supplied. Crop response on salinity and water supply is discussed in relation to fertilizer application. The management of fertilizer addition in relation to analytical data of soil and substrate samples is presented for a wide range of crops grown in greenhouses. The specific requirements in relation with the climatic conditions and the crop grown are discussed. The management as described is especially focussed on a sustainable production of vegetable and ornamental crops. The water supply, fertilization and the realisation of the osmotic potential in the root environment is focussed on the production of the high quality products required on the consumer market as appeared last decennia in the Western world. Such a market is characterized by diversity, quality and immediate answers to demands of luxurious productions. Greenhouse production is able to meet these demands including the demands with respect to environmental pollution. The contents of the book supply much information to these requirements suitable for greenhouse industry, being an important, strongly growing high technological horticultural activity.
From the reviews: "This book is a comprehensive, detailed treatise on fertilisation and nutrient relationships in growing media and hydroponics. ... the book is of most value to research workers in soilless culture and substrate methods of growing under glass, and students on final year horticulture and applied plant science courses. ... is likely to form the standard reference work on plant nutrition in glasshouse crops for many years." (Bill Carlile, Chronica Horticulturae, Vol. 50 (3), 2010) "This 17-chapter book covers a wide range of topics, including fertilizers and soil improvements; soil, substrate, and tissue testing; water uptake, supply, and quality ... . References are listed at the end of each chapter. ... Color photographs of disorders caused by calcium deficiency or excess in several species of vegetable and floral crops are also included. ... An index includes references to nutrient elements as well as topics covered in the book. ... Summing Up: Recommended. Upper-division undergraduate through professional collections." (F. G. Dennis Jr., Choice, Vol. 47 (11), July, 2010)
Greenhouse cultivation is noted for its high uptake of minerals, consistent climatic conditions, exclusion of natural precipitation and control of salt accumulation. Acknowledging that plant nutrition in greenhouse cultivation differs in many essentials from field production, this volume details specific information about testing methods for soils and substrates in a greenhouse environment. It does so while offering a universally applicable analysis. This is based on the composition of the soil and substrate solutions, methods for the interpretation of tissue tests, and crop responses on salinity and water supply in relation to fertilizer application. Fertilizer additions, related to analytical data of soil and substrate samples, are presented for a wide range of vegetable and ornamental crops. The subject is especially apt now as substrate growing offers excellent possibilities for the optimal use of water and nutrients, as well as the potential for sustainable production methods for greenhouse crops.
Table of Contents
1. Greenhouse horticulture; 2. Fertilizers and soil improvers; 3. Soil solution; 4. Soil and substrate testing to estimate nutrient availability and salinity status; 5. Tissue tests; 6. Water uptake and water supply; 7. Salinity and water quality; 8. Crop response to an unequal distribution of ions in space and time; 9. Calcium nutrition and climatic conditions; 10. Chemical effects of disinfestations; 11. Substrates: chemical characteristics; 12. Nutrient solutions for soilless cultures; 13. Nutrient management in substrate systems; 14. Fertigation management of potted plants; 15. Fertigation in soil grown crops; 16. Nutrient management in soil grown crops; 17. Plant nutrition in future greenhouse production; Definitions; Appendices