Авторы:
Свиридова А.Д.
Анна Дмитриевна Свиридова – кандидат сельскохозяйственных наук, доцент кафедры Землепользования и землеустройства Новочеркасского инженерного-мелиоративного института им. А.К. Кортунова, ДГАУ.
Власов А.И.
Власов Александр Иванович,
начальник отдела библиотеки Новочеркасского инженерно-мелиоративного института им. А. К. Кортунова, ДГАУ (РФ, 346428, г. Новочеркасск, ул. Пушкинская, 111)
bibliogrngma@yandex.ru
Аннотация
Представлен обзор последних научных разработок в области орошаемого виноградарства. Сделан акцент на инновационные разработки, изучающие фенологические особенности раз-вития виноградной лозы в условиях водного стресса, освещены вопросы использования альтернативных источников для орошения, рассмотрены основные тенденции в развитии цифровых технологий по управлению системами водосбережения.
Ключевые слова
виноградарство, физиология виноградной лозы, водный стресс, водный статус, орошение, управление системами орошения, мониторинг состояния виноградников
Библиография
1. Тенденции мирового рынка винограда / Вино. Виноград : [сайт]. — URL: https://vinograd-vino.ru/stati-i-issledovaniya/909-tendentsii-mirovogo-rynka-vinograda.html (дата обращения: 22.12.2021).
2. Roca, P. Состояние винодельческой отрасли в мире в 2020 : презентация / Р. Roca / Всемирная организация виноградарства и виноделия : [сайт]. — URL: https://enogrup.com/wp-content/uploads/2021/05/Мировое-виноделие-2020-в-цифрах-доклад-OIV.pdf (дата обращения: 22.12.2021).
3. Мировое производство и потребление винограда / Виноцентр.ру : [сайт]. — URL: http://vinocenter.ru/mirovoe-proizvodstvo-i-potreblenie-vinograda.html (дата обращения: 22.12.2021).
4. Анализ рынка винограда в России в 2016–2020 гг., оценка влияния коронавируса и прогноз на 2021–2025 гг. / Магазин исследований : [сайт]. — URL: https://marketing.rbc.ru/research/46262/ (дата обращения: 22.12.2021).
5. Литература по виноградарству и виноделию / Виноград северных широт : [сайт]. — URL: https://www.rusvinograd.ru/viewtopic.php?t=156 (дата обращения: 22.12.2021).
6. A review of the potential climate change impacts and adaptation options for European viticulture / J. A. Santos [et al.] // Appl. Sci. — 2020. — Vol. 10. — 3092. — URL: https://www.mdpi.com/2076-3417/10/9/3092/htm
7. An update on the impact of climate change in viticulture and potential adaptations / C. van Leeuwen [et al.] // Agronomy. — 2019. — No 9. — 514. — URL: https://pdfs.semanticscholar.org/8b07/5021f8cfd2a9eb6045d6701536e3e6063a31.pdf?_ga=2.102983104.1763685303.1639474178-1498117619.1614767340
8. Vineyards in transition: A global assessment of the adaptation needs of grape producing regions under climate change / D. Santillán [et al.] // Sci. Total Environ. — 2019. — Vol. 657. — P. 839–852. — URL: https://elearning.unite.it/pluginfile.php/161845/mod_resource/content/1/1-s2.0-S0048969718349192-main.pdf
9. Miras-Avalos J.M. Optimization of Vineyard Water Management: Challenges, Strategies, and Perspectives / J.M. Miras-Avalos, E. Araujo // Water. — 2021. — № 13. — 746. — URL: https://doi.org/10.3390/wl3060746
10. Zsófi Z. Texture properties and phenol extractability indices of the grape berry under pre-and post-veraison water deficit (vitis vinifera l. 'kékfrankos') / Z. Zsófi, X. Pálfi, S. Villangó // Vitis - Journal of Grapevine Research. — 2021 — 60(3). — P. 125–135.
11. Impact of low rainfall during dormancy on vine productivity and development / M. Bonada [et al.] // Aus. J. Grape Wine Res. — 2020. — № 26. —P. 325–342.
12. Soil water availability during spring modulates canopy growth and impacts the chemi-cal and sensory composition of Shiraz fruit and wine / M. Bonada, A. A. Catania, J. M. Gambetta, P. R. Petrie // Australian Journal of Grape and Wine Research. — 2021. — 274). — P. 491–507.
13. Regulated deficit irrigation and its effects on yield and quality of vitis vinifera l., tour-iga francesa in a hot climate area (douro region, portugal) / Cabral, I.L., Carneiro, A., Nogueira, T., Queiroz, J. // Agriculture (Switzerland). — 2021. — № 11 (8). — 774.
14. Effects of Irrigation at Different Fractions of Crop Evapotranspiration on Water Productivity and Flavonoid Composition of Cabernet Sauvignon Grapevine / N. Torres [et al.] // Frontiers in Plant Science. — 2021. — № 12. — 712622.
15. Grapevine trunk diseases under thermal and water stresses / A. Songy [et al.] // Planta. – 2019. — Vol. 249. — P. 1655–1679.
16. Sosnowski, M.R. The Influence of Water Deficit Stress on the Grapevine Trunk Disease Pathogens Eutypa lata and Diplodia seriata / M.R. Sosnowski, M.R. Ayres, E.S. Scott // Plant Dis-ease. — 2021. — Vol. 105(8). — P. 2217–2221.
17. Rienth, M. State-of-the-art of tools and methods to assess vine water status / M. Rienth, T. Scholasch // OENO One. — 2019. — № 4. — P. 619–637.
18. Evaluation of point hyperspectral reflectance and multivariate regression models for grapevine water status estimation / H.-E. Wei [et al.] // Remote Sensing. — 2021. — 13 (16). — 3198.
19. Vitis vinifera bZIP14 functions as a transcriptional activator and enhances drought stress resistance via suppression of reactive oxygen species / Y.-H. Yu [et al.] // Journal of Berry Research. — 2020. — № 10 (4). — P. 547–558.
20. Anatomical physiological and biochemical processes involved in grapevine rootstock drought tolerance / M. Li [et al.] // Vitis - Journal of Grapevine Research. — 2021. — Vol. 60 (2). — P. 53–61.
21. Assessing the effects of vineyard soil management on downy and powdery mildew de-velopment / A.F. de Oliveira [et al.] // Horticulturae. — 2021. — № 7 (8). — 209.
22. Romero, P. Towards a sustainable viticulture: The combination of deficit irrigation strategies and agroecological practices in Mediterranean vineyards. A review and update / P. Romero, J.M. Navarro, P.B. Ordaz // Agricultural Water Management. — 2022. — Vol. 259. — 107216.
23. A trait-based approach in a Mediterranean vineyard: Effects of agricultural manage-ment on the functional structure of plant communities / J.G. Guerra, F. Cabello, C. Fernández-Quintanilla, J. Dorado, // Agriculture Ecosystems and Environment. — 2021. — Vol. 316. — 107465.
24. Effects of cover crops and irrigation on 'Tempranillo' grapevine and berry physiology: An experiment under the Mediterranean conditions of Southern Portugal / Tomaz, A., Martínez, J.C., Pacheco, C.A. // Oeno One. — 2021. — Vol. 55(3). — P. 191–208.
25. Reclaimedwater for vineyard irrigation in a mediterranean context: Life cycle envi-ronmental impacts, life cycle costs, and eco-efficiency / K. Canaj [et al.] // Water (Switzerland). — 2021. — № 13(16). — 2242.
26. Oenological characteristics of Vitis vinifera L. Cabernet Sauvignon grapes from vine-yards treated with ozonated water / M. Mercedes García-Martínez, A. Campayo, J.M. Carot, G.L. Alonso // Australian Journal of Grape and Wine Research. — 2020. — № 26 (4). — P. 388–398.
27. Effects of treatments with ozonated water in the vineyard (cv Vermentino) on microbi-al population and fruit quality parameters / M. Modesti, S. Baccelloni, S. Brizzolara Scuola, M.P. Aleandri // BIO Web of Conferences. —2019. — Vol. 13 (2). — 04011.
28. Actual transpiration and canopy resistance in a Mediterranean vineyard irrigated with saline water / Rana, G., Ferrara, R.M., Cona, F., De Lorenzi, F. // Irrigation Science. — 2021. — Vol. 39 (4). — P. 469–481.
29. Effects of deficit irrigation with saline water on wine color and polyphenolic composi-tion of Vitis vinifera L. cv. Monastrell / A. Martínez-Moreno [et al.] // Scientia Horticulturae. — 2021. — Vol. 283. — 110085.
30. The Effects of Irrigation Amount on Sap Flow in Stems of Wine Grape and Its Consequence for Grape Yield and Quality | [不同灌溉水平对酿酒葡萄茎秆液流特征和产量, 品质的影响] / J. Sun [et al.] // Journal of Irrigation and Drainage. — 2021. — Vol. 40 (10). — P. 18–24.
31. Physiological response of post-veraison deficit irrigation strategies and growth patterns of table grapes (cv. Crimson Seedless) / M.R. Conesa [et al.] // Agricultural Water Management. — 2018. — Vol. 208. — P. 363–372.
32. Ma X. Improving Net Photosynthetic Rate and Rooting Depth of Grapevines Through a Novel Irrigation Strategy in a Semi-Arid Climate / X. Ma, P.W. Jacoby, K.A. Sanguinet // Fron-tiers in Plant Science. — 2020. — № 11. — 575303.
33. A 3-D functional-structural grapevine model that couples the dynamics of water transport with leaf gas exchange / J. Zhu [et al.] // Ann. Bot. — 2018. — Vol. 121. — P. 833–848.
34. Modelling grape growth in relation to whole-plant carbon and water fluxes / J. Zhu // J. Exp. Bot. — 2019. — Vol. 70. — P. 2505–2521.
35. Modeling stem water potential by separating the effects of soil water availability and climatic conditions on water status in grapevine (Vitis vinifera L.) / B. Suter et al.] // Front. Plant. Sci. — 2019. — № 10. — 1485.
36. Gautam D. Estimation of grapevine crop coefficient using a multispectral camera on an unmanned aerial vehicle / D. Gautam, B. Ostendorf, V. Pagay, // Remote Sensing. — 2021. — № 13(13). — 2639.
37. Dual crop coefficient approach in Vitis vinifera L. cv. Loureiro / S.P. Silva [et al.] // Agronomy. — 2021. — № 11 (10). — 2062.
38. Modeling Pinot Noir aroma profiles based on weather and water management infor-mation using machine learning algorithms: A vertical vintage analysis using artificial intelligence / S. Fuentes, E. Tongson, D.D. Torrico, C. Gonzalez Viejo // Foods. — 2020. — № 9. — P. 33.
39. Soil apparent electrical conductivity and must carbon isotope ratio provide indication of plant water status in wine grape vineyards / Yu, R., Zaccaria, D., Kisekka, I., Kurtural, S.K. // Precision Agriculture. — 2021. — № 22 (4). — P. 1333–1352.
40. Taylor J.A. Comparison of different vegetative indices for calibrating proximal canopy sensors to grapevine pruning weight // J. A. Taylor, T. R. Bates // American Journal of Enology and Viticulture. — 2021. — Vol. 72 (3). — P. 279–283.
41. Robotics-based vineyard water potential monitoring at high resolution / V. Saiz-Rubio, F. Rovira-Más, A. Cuenca-Cuenca, F. Alves, // Computers and Electronics in Agriculture. — 2021. — Vol. 187. — 106311.
42. A NB-IoT based platform for smart irrigation in vineyard / A. Liopa-Tsakalidi [et al.] // 2021 10th International Conference on Modern Circuits and Systems Technologies, MOCAST 2021. — 2021. — 9493381.
43. Vineyard water status estimation using multispectral imagery from an UAV platform and machine learning algorithms for irrigation scheduling management / M. Romero, Y. Luo, B. Su, S. Fuentes // Comput. Electron. Agric. — 2019. — Vol. 147. — P. 109–117.
44. Determining evapotranspiration by using combination equation models with sentinel-2 data and comparison with thermal-based energy balance in a california irrigated vineyard / G. D’urso [et al.] // Remote Sensing. — 2021. — № 13 (18). — 3720.
45. Раджабов, А. К. Состояние и перспективы развития виноградарства, включая пи-томниководство: науч. аналит. обзор / А. К. Раджабов, Н. П. Мишуров, Т. А. Щеголихина. — Москва : ФГБНУ «Росинформагротех», 2019. — 92 с.