Upland rice
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Upland rice (also called dry rice) is rice grown in dry-land environments. The term describes varieties of rice developed for rain-fed or less-intensely irrigated soil instead of flooded rice paddy fields or rice grown outside of paddies.[1][2]
Introduction
[edit]The term “upland rice” refers to rice cultivated in non-flooded conditions, and it can encompass various specific definitions. While most of the world's rice is grown in paddy fields or wet environments that require significant amount of water, rice itself does not inherently need flooding to thrive. However, flooded fields help ensure the ample water supply that certain rice varieties require and assist in weed suppression. Upland rice, by contrast, is primarily rain-fed or lightly irrigated and is not reliant on flooded conditions. This category includes both specially bred varieties that are drought-tolerant and traditional rice varieties that have adapted to drier environment.[2]
Nearly 100 million people depend on upland rice as their daily staple food. Almost two-thirds of the upland rice cultivation occurs in Asia, with Bangladesh, Cambodia, China, Northeastern India, Indonesia, Myanmar, Nepal, Thailand, and Vietnam all being important producers. [2]
Ecosystems involving upland rice are often relatively diverse, including fields that are level, gently rolling, or steep. Such ecosystems also occur at altitudes up to 2,000 m, with average annual rainfall ranging between 1,000 mm to 4,500 mm.
Soils used to grow upland rice range from highly fertile to highly weathered, infertile, and acidic soil. However, only 15% of total upland rice grows where soils are fertile, and the growing season is long.
Many upland farmers plant local rice that does not respond well to improved management practices, like intensive farming using artificial fertilizers, but these local rice varieties are well adapted to their environments and produce grains that meet local needs. [3]
Although the rice technology of the 1960s and 1970s focused on irrigated rice, research also studied the cultivation of upland rice. Researchers produced cultivars adapted to poor soils with improved pest resistance and drought tolerance. [4] Some have out-yielded traditional rice by over 100 percent in evaluations. Scientists at national agricultural research systems have crossed these improved strains with local cultivars, introducing hybrid varieties of rice.
Challenges to upland rice farming
[edit]New challenges are emerging[when?] in the world's upland rice farming areas where poverty is already a problem. These farmers try to make a living by farming on deficient soil, which makes it hard to grow their crops.
Population growth, the demands of urbanism and industry, and the increasing adoption of high-value cash crop farming in the surrounding lowlands are leading to strong competition for upland terrain.
The uplands have always suffered from drought, infertile soils, weeds, and plant diseases. The soils there have been severely eroded and degraded as a result of the slash-and-burn agriculture that followed logging for many years. This destroys the watershed, producing problems in the lands below.
These new upward pressures result in a movement toward permanent agriculture and an intensification of land use in upland areas. In addition to the usual upland problems, those involved in growing upland rice find themselves facing an urgent need to conserve soil and the diversity of plant species and to deal with increasingly frequent and severe weed and disease infestations.
Blast fungus
[edit]Recently, scientists have been improving their knowledge of the genetics of resistance to the blast fungus, one of the most damaging diseases of rice. Using the techniques of biotechnology, they are developing cultivars with more durable disease resistance.
In the uplands, the blast is particularly important because the environment favors its proliferation. Although many traditional upland cultivars show stable resistance to this disease under low-input cropping practices, they have other characteristics that make them difficult to use in intensified systems. So, the risk of blast increases as cropping practices intensify and improved varieties are introduced.
Scientists from the International Rice Research Institute (IRRI) have been working with colleagues in the Upland Rice Research Consortium to better understand pathogen populations and identify resistance genes found in some cultivars. Armed with this knowledge, they are working with IRRI's upland rice breeder to combine such genes with other desirable traits for incorporation into new upland varieties. [5]
Consortium scientists are also trying to understand how upland rice farmers' cropping systems contribute to soil erosion, with the aim of proposing possible erosion control techniques. Studies in the Philippines have shown that hedgerows of trees, shrubs, and grasses along hill contours can help reduce soil erosion by up to 90 percent. Rice or other crops are planted between these strips of permanent ground cover.
Leguminous plants in hedgerows make substantial amounts of atmospheric nitrogen available to both rice plants and annual crops and recycle other nutrients and organic matter.
Such legumes can simultaneously increase farmers' incomes and contribute to the sustainability of the farming system.
The importance of weeds
[edit]Weeds are the most serious biological constraint to upland rice production. IRRI scientists are pursuing projects on managing weeds with less herbicide use. One approach is to search for rice plant species that exhibit a characteristic known as allelopathy. Allelopathic plants can affect the growth of nearby plants through the production of biological compounds they release into the environment. If allelopathic rice—or other plant species—could be found to inhibit the growth of weeds important in rice production, it might be possible through genetic engineering to develop rice cultivars that would provide their own weed control.
Most weed species are susceptible to certain diseases . The purposeful application of the agents of such diseases to weed pests among rice crops could constitute another approach to weed control.
Researchers from IRRI, Maejo University, and Chiang Mai University launched a study in 1993 of the interactions between weeds, crop environmental conditions, and farmers' practices in upper northern Thailand. The goals are to understand the diversity of farmers' practices and decision-making processes and to grade the factors that limit rice crop yields.
IRRI scientists are also studying how fertilizer and cultural practices influence weed communities. In one project on phosphorus management, they are investigating how weed communities change as soil fertility is improved over time in the Philippines, Indonesia, and Thailand.
Rice plant cultivars differ in their ability to compete with weeds in the field. Scientists in the Philippines tested the competitiveness of a dozen cultivars against weeds to help farmers choose the most highly competitive one. By planting this cultivar and enhancing their competitive ability through good management practices, farmers should be able to reduce the amount of hand weeding necessary while achieving maximum yields.
Improving soil fertility
[edit]Research on farms in Thailand, Laos and the Philippines confirmed that a lack of phosphorus in upland farms is a limiting factor in rice crop yields- arising from the fact that many highly weathered upland soils are inherently low in phosphorus and are acidic.[6]
This lack of phosphorus will limit production even if calcium is added to the soil to overcome the acidity, or if acid-tolerant cultivars are planted. Rotations of rice and legumes could lead to stable, higher-value production if phosphorus is added and that soil quality does not degrade over time.
Acid barrier
[edit]The acidity present in the subsoil of many upland areas prevents plant roots from reaching the moisture and nutrients therein, thus reducing crop yield. Adding lime to the subsoil is not practical, but in 1994, IRRI and Indonesian scientists began experiments to see if components of lime applied to the soil surface could be leached down into the subsoil. This is done by manipulating soil chemistry and using deep-rooted, acid-tolerant rice cultivars to help capture the leached components.
Scientists are currently studying the processes that govern the rate of leaching of lime components and their accumulation in the subsoil. Using this data, they plan to construct mathematical models that will be used to develop practical technologies and to indicate under what conditions the technologies might be effective.
The experiments began at the Upland Rice Research Consortium site in Sitiung, Indonesia. French collaborators from l'Institut francais de recherche scientifique pour le développement en cooperation are planning similar experiments in Thailand and Vietnam.
Perennial upland rice
[edit]Rice, like most cereal crops, is an annual plant, which leads to soil erosion when grown as a monoculture. A perennial variety of rice that would not need to be replanted annually could help reduce erosion by providing a permanent ground cover and deeper, tighter root systems. Perenniality exists in several wild species of rice from Southeast Asia, but their yields are low. These species, however, can be crossed with cultivated rice through selection to develop both high-yield and perennial crops.[7]
The challenge facing scientists is to produce a high-yielding perennial plant adapted to the poor soils of the uplands, with high yields from low-purchased inputs, and resistant to diseases and insects.
The development of high-yield, resilient, perennial rice varieties is an important focus at the International Rice Research Institute. Genomics allows the transfer of perennial genetic properties into traditional varieties of cultivated rice, and new knowledge of genetic diversity will be applied to develop pest resistance.[8]
Participatory crop improvement
[edit]Upland rice is being partially replaced by other crops, such as maize. On the other hand, the landraces are gradually disappearing from farmers' fields. Diversity of upland rice can be maintained while, at the same time, levels of production can be increased using participatory techniques. The addition of upland rice to fields allows for crop rotation and the improvement of diversity in fields.
See also
[edit]References
[edit]- ^ "Definition of UPLAND RICE". www.merriam-webster.com. Retrieved 2022-06-23.
- ^ a b c Gupta, P.C.; O'Toole, J.C.; International Rice Research Institute (1986). Upland Rice: A Global Perspective. International Rice Research Institute. p. 1. ISBN 978-971-10-4172-4. Retrieved 2024-06-06.
- ^ Joshi, K.D., R.B. Rana and A. Subedi. 2001. Farmer and Researcher contributions to the selection of Landraces of Ghaiya (Upland rice) for Tar areas of Nepal. L-BIRD/SANFEC. Katmandu / Dhaka
- ^ Adhikari, B. B. and Rosyara, U.R. 2007. Collection of Upland Rice Landraces from Western Mid Hill Districts and Evaluation for Drought Tolerance. Report submitted to Nepal Academy of Science
- ^ Arraudeau, M. A. (1995). "Upland Rice: Challenges and Opportunities in a Less Favorable Ecosystem". GeoJournal. 35 (3): 325–328. ISSN 0343-2521.
- ^ George, Thomas; Magbanua, Roger; Roder, Walter; Van Keer, Koen; Trébuil, Guy; Reoma, Veronica (November 2001). "Upland Rice Response to Phosphorus Fertilization in Asia". Agronomy Journal. 93 (6): 1362–1370. doi:10.2134/agronj2001.1362. ISSN 0002-1962.
- ^ Arraudeau, M. A. (1995). "Upland Rice: Challenges and Opportunities in a Less Favorable Ecosystem". GeoJournal. 35 (3): 325–328. ISSN 0343-2521.
- ^ Developing Perennial Upland Rice I: Field Performance of Oryza sativa/O. rufipogon F1, F4, and BC1F4 Progeny. Crop Sci. 43:120–128
Bibliography
[edit]- Arraudeau, M. A. Upland rice: Challenges and opportunities in a less favorable ecosystem. GeoJournal, March 1995, Volume 35, Issue 3, pp. 325–328.
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- Subedi, S., U.R. Rosyara, B.B. Adhikari, B.R. Ojha, D.P. Ghimire. D.D. Dhakal, H.B. Gurung, and S. Pandey. 2011. Participatory Crop Improvement: Effect of Farmers’ Selection Criteria on Diversity of Rice Grown In Uplands of Nepal. Journal of Agriculture Science. Vol 49.
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