Purpose. To establish the optimal seeding time and depth of ‘Dniprovskyi 39’ and ‘Vinets’ sorghum varieties, to prove their effect on the crop photosynthetic capacity in the Right-Bank Forest-Steppe of Ukraine. Methods. Field, laboratory, comparative, analytical, generalizing, mathematical and statistical. Results. It was proved that the best results of crop photosynthetic capacity of sorghum were obtained by sowing in the first decade of May (the second sowing period) at a seeding depth of 4–6 cm. Accordingly, the leaf surface area in these variants reached its maximum during the “panicle-blooming” period and equated 36.13–38.81 thousand m2/ha for the ‘Dniprovskyi 39’ variety and 34.23–36.91 thousand m2/ha for the ‘Vinets’ variety. By sowing seeds in the third decade of April (the first sowing period) at the seedining depth values described above the leaf surface area of the varieties was slightly smaller and amounted to 29.56–31.20 thousand m2/ha for the ‘Dniprovskyi 39’ variety and 27.76–29.40 thousand m2/ha for the ‘Vinets’ variety. By sowing seeds in the second decade of May (the third sowing period), the leaf surface area was 30.68–32.92 thousand m2/ha for the ‘Dniprovskyi 39’ variety and 29.08–31.32 thousand m2/ha for the ‘Vinets’ variety. The highest photosynthetic potential was obtained for sorghum plants in the second sowing period at the seeding depth of 4–6 cm and was 1.27 and 1.34 million m2/ha for the ‘Dniprovskyi 39’ variety and 1.16 and 1.22 million m2/ha for the variety ‘Vinets’. In the first sowing period, this indicator was slightly lower and amounted to 1.18 and 1.23 million m2/ha for the ‘Dniprovskyi 39’ variety and 0.98 and 1.02 million m2/ha for the ‘Vinets’ variety respectively. In the third sowing period, it was the smallest one and equated 1.09 and 1.13 million m2/ha for the ‘Dniprovskyi 39’ variety, and 0.88 and 0.93 million m2/ha for the ‘Vinets’ variety at the optimal seeding depth. The photosynthetic potential was lower at the seeding depth of 2 and 8 cm, which is explained by the different soil and climatic parameters during a certain period of sorghum plant vegetation. The highest value of the photosynthetic capacity net indicator was obtained by sowing seeds at the optimal time and the optimal seeding depth and it equated 3.84–4.02 g/m2 per day for the ‘Dniprovskyi 39’ variety and 3.79 – 3.98 g/m2 per day for the ‘Vinets’ variety. Conclusions. It has been established that the sorghum plants had better vegetation and formed photosynthetic capacity by sowing seeds in the first decade of May at the planting depth of 4–6 cm, which we recommend for growing this crop in the Right-Bank Forest-Steppe of Ukraine.

Цель. Установить оптимальные сроки сева и глубину заделки семян сорго зернового сортов ‘Дніпровський 39’ и ‘Вінець’, обосновать их влияние на фотосинтетическую продуктивность посевов в условиях Правобережной Лесостепи Украины.Методы. Полевой, лабораторный, сравнительный, аналитический, обобщающий, математически-статистический.Результаты. Наилучшие результаты фотосинтетической продуктивности посевов сорго зернового получены во время сева в I декаде мая (второй срок) на глубине заделки семян 4–6 см. Соответственно, площадь листовой поверхности в этих вариантах в период «выбрасывания метелки–цветения» достигала максимума и составляла 36,13–38,81 тыс. м2/га у сорта ‘Дніпровський 39’ и 34,23 – 36,91 тыс. м2/га у сорта ‘Вінець’. При севе семян в III декаде апреля (первый срок) при вышеуказанных значениях глубины заделки площадь листовой поверхнос­ти у сортов была несколько меньше и составляла 29,56–31,20 тыс. м2/га у сорта ‘Дніпровський 39’ и 27,76–29,40 тыс. м2/га у сорта ‘Вінець’. При севе семян во II декаде мая (третий срок) площадь листовой поверхности составляла 30,68–32,92 тыс. м2/га у сорта ‘Дніпровський 39’ и 29,08–31,32 тыс. м2/га у сорта ‘Вінець’. Фотосинтетический потенциал был самым высоким в растениях сорго зернового во втором сроке сева семян на глубине заделки 4–6 см и составлял 1,27 и 1,34 млн м2/га у сорта ‘Дніпровський 39’ и 1,16 и 1,22 млн м2/га у сорта ‘Вінець’. В первом сроке сева этот показатель был несколько ниже и составлял 1,18 и 1,23 млн м2/га у сорта ‘Дніпровський 39’ и 0,98 и 1,02 млн м2/га у сорта ‘Вінець’, соответственно. В третьем сроке сева он был самым низким, у сорта ‘Дніпровський 39’ этот показатель составлял 1,09 и 1,13 млн м2/га, у сорта ‘Вінець’ – 0,88 и 0,93 млн м2/га при оптимальных значениях глубины заделки семян. На глубине заделки семян 2 и 8 см фотосинтетический потенциал был ниже, что объясняют различными почвенно-климатическими условиями в определенный период развития растений сорго. Наивысшее значение показателя чистой продуктивности фотосинтеза было получено при севе семян в оптимальные сроки и оптимальной глубине заделки семян и составляло 3,84–4,02 г/м2 в сутки у сорта ‘Дніпровський 39’ и 3,79–3,98 г/м2 в сутки у сорта ‘Вінець’, соответственно.Выводы. Лучше развивались и формировали фотосинтетическую продуктивность растения сорго зернового при севе семян в первой декаде мая на глубине заделки 4–6 см, которые и рекомендованы для выращивания данной культуры в Правобережной Лесостепи Украины. | Purpose. To establish the optimal seeding time and depth of ‘Dniprovskyi 39’ and ‘Vinets’ sorghum varieties, to prove their effect on the crop photosynthetic capacity in the Right-Bank Forest-Steppe of Ukraine. Methods. Field, laboratory, comparative, analytical, generalizing, mathematical and statistical. Results. It was proved that the best results of crop photosynthetic capacity of sorghum were obtained by sowing in the first decade of May (the second sowing period) at a seeding depth of 4–6 cm. Accordingly, the leaf surface area in these variants reached its maximum during the “panicle-blooming” period and equated 36.13–38.81 thousand m2/ha for the ‘Dniprovskyi 39’ variety and 34.23–36.91 thousand m2/ha for the ‘Vinets’ variety. By sowing seeds in the third decade of April (the first sowing period) at the seedining depth values described above the leaf surface area of the varieties was slightly smaller and amounted to 29.56–31.20 thousand m2/ha for the ‘Dniprovskyi 39’ variety and 27.76–29.40 thousand m2/ha for the ‘Vinets’ variety. By sowing seeds in the second decade of May (the third sowing period), the leaf surface area was 30.68–32.92 thousand m2/ha for the ‘Dniprovskyi 39’ variety and 29.08–31.32 thousand m2/ha for the ‘Vinets’ variety. The highest photosynthetic potential was obtained for sorghum plants in the second sowing period at the seeding depth of 4–6 cm and was 1.27 and 1.34 million m2/ha for the ‘Dniprovskyi 39’ variety and 1.16 and 1.22 million m2/ha for the variety ‘Vinets’. In the first sowing period, this indicator was slightly lower and amounted to 1.18 and 1.23 million m2/ha for the ‘Dniprovskyi 39’ variety and 0.98 and 1.02 million m2/ha for the ‘Vinets’ variety respectively. In the third sowing period, it was the smallest one and equated 1.09 and 1.13 million m2/ha for the ‘Dniprovskyi 39’ variety, and 0.88 and 0.93 million m2/ha for the ‘Vinets’ variety at the optimal seeding depth. The photosynthetic potential was lower at the seeding depth of 2 and 8 cm, which is explained by the different soil and climatic parameters during a certain period of sorghum plant vegetation. The highest value of the photosynthetic capacity net indicator was obtained by sowing seeds at the optimal time and the optimal seeding depth and it equated 3.84–4.02 g/m2 per day for the ‘Dniprovskyi 39’ variety and 3.79 – 3.98 g/m2 per day for the ‘Vinets’ variety.Conclusions. It has been established that the sorghum plants had better vegetation and formed photosynthetic capacity by sowing seeds in the first decade of May at the planting depth of 4–6 cm, which we recommend for growing this crop in the Right-Bank Forest-Steppe of Ukraine. | Мета. Встановити оптимальні строки сівби та глибину загортання насіння сорго зернового сортів ‘Дніпровський 39’ та ‘Вінець’, обґрунтувати їхній вплив на фотосинтетичну продуктивність посівів в умовах Правобережного Лісостепу України. Методи. Польовий, лабораторний, порівняльний, аналітичний, узагальнюючий, математично-статистичний. Результати. Найкращі результати фотосинтетичної продуктивності посівів сорго зернового отримано за сівби у  І декаді травня (другий строк) на глибину загортання насіння 4–6 см. Відповідно, площа листкової поверхні за цих факторів у період «викидання волоті – цвітіння» сягала максимуму і дорівнювала 36,13–38,81 тис. м2/га у сорту ‘Дніпровський 39’ та 34,23–36,91 тис. м2/га у сорту ‘Вінець’. За сівби насіння у ІІІ декаді квітня (перший строк) за таких самих значень глибини загортання площа листкової поверхні у сортів була дещо меншою і становила 29,56–31,20 тис. м2/га у сорту ‘Дніпровський 39’ та 27,76–29,40 тис. м2/га у сорту ‘Вінець’. За сівби насіння у ІІ декаді травня (третій строк) площа листкової поверхні дорівнювала 30,68–32,92 тис. м2/га у сорту ‘Дніпровський 39’ та 29,08–31,32 тис. м2/га у сорту ‘Вінець’. Фотосинтетичний потенціал був найвищим у рослин сорго зернового за ІІ строку сівби насіння та глибини загортання 4–6 см й дорівнював 1,27 та 1,34 млн м2/га у сорту ‘Дніпровський 39’ і 1,16 та 1,22 млн м2/га у сорту ‘Вінець’. За І строку сівби цей показник був дещо меншим і відповідно становив 1,18 та 1,23 млн м2/га у сорту ‘Дніпровський 39’ й 0,98 і 1,02 млн м2/га у сорту ‘Вінець’. За ІІІ строку сівби він був найменшим та у сорту ‘Дніпровський 39’ дорівнював 1,09 і 1,13 млн м2/га, у сорту ‘Вінець’ 0,88 і 0,93 млн м2/га за оптимальних значень глибини загортання насіння. За глибини загортання насіння 2 та 8 см фотосинтетичний потенціал був нижчим, що пояснюють різними ґрунтово-кліматичними умовами у певний період розвитку рослин сорго. Найбільше значення показника чистої продуктивності фотосинтезу було отримано за сівби насіння в оптимальні строки та за оптимальної глибини загортання насіння і становило у сорту ‘Дніпровський 39’, відповідно, 3,84–4,02 г/м2 за добу, у сорту ‘Вінець’ 3,79–3,98 г/м2 за добу.Висновки. Найкраще розвивались та формували фотосинтетичну продуктивність рослини сорго зернового за сівби насіння у першій декаді травня на глибину загортання 4–6 см, які й рекомендовано для вирощування даної культури в Правобережному Лісостепу України.

Purpose. To establish the optimal seeding time and depth of ‘Dniprovskyi 39’ and ‘Vinets’ sorghum varieties, to prove their effect on the crop photosynthetic capacity in the Right-Bank Forest-Steppe of Ukraine. Methods. Field, laboratory, comparative, analytical, generalizing, mathematical and statistical. Results. It was proved that the best results of crop photosynthetic capacity of sorghum were obtained by sowing in the first decade of May (the second sowing period) at a seeding depth of 4–6 cm. Accordingly, the leaf surface area in these variants reached its maximum during the “panicle-blooming” period and equated 36.13–38.81 thousand m2/ha for the ‘Dniprovskyi 39’ variety and 34.23–36.91 thousand m2/ha for the ‘Vinets’ variety. By sowing seeds in the third decade of April (the first sowing period) at the seedining depth values described above the leaf surface area of the varieties was slightly smaller and amounted to 29.56–31.20 thousand m2/ha for the ‘Dniprovskyi 39’ variety and 27.76–29.40 thousand m2/ha for the ‘Vinets’ variety. By sowing seeds in the second decade of May (the third sowing period), the leaf surface area was 30.68–32.92 thousand m2/ha for the ‘Dniprovskyi 39’ variety and 29.08–31.32 thousand m2/ha for the ‘Vinets’ variety. The highest photosynthetic potential was obtained for sorghum plants in the second sowing period at the seeding depth of 4–6 cm and was 1.27 and 1.34 million m2/ha for the ‘Dniprovskyi 39’ variety and 1.16 and 1.22 million m2/ha for the variety ‘Vinets’. In the first sowing period, this indicator was slightly lower and amounted to 1.18 and 1.23 million m2/ha for the ‘Dniprovskyi 39’ variety and 0.98 and 1.02 million m2/ha for the ‘Vinets’ variety respectively. In the third sowing period, it was the smallest one and equated 1.09 and 1.13 million m2/ha for the ‘Dniprovskyi 39’ variety, and 0.88 and 0.93 million m2/ha for the ‘Vinets’ variety at the optimal seeding depth. The photosynthetic potential was lower at the seeding depth of 2 and 8 cm, which is explained by the different soil and climatic parameters during a certain period of sorghum plant vegetation. The highest value of the photosynthetic capacity net indicator was obtained by sowing seeds at the optimal time and the optimal seeding depth and it equated 3.84–4.02 g/m2 per day for the ‘Dniprovskyi 39’ variety and 3.79 – 3.98 g/m2 per day for the ‘Vinets’ variety. Conclusions. It has been established that the sorghum plants had better vegetation and formed photosynthetic capacity by sowing seeds in the first decade of May at the planting depth of 4–6 cm, which we recommend for growing this crop in the Right-Bank Forest-Steppe of Ukraine.

Pourpose. Establish compliance of heat and moisture resources to biological requirements of sunflower hybrids (Helianthus annuus), reveal criteria for assessing weather conditions in the northern regions of Ukraine; establish links between temperature, precipitation and yield. Methods. Field and mathematical methods were used. Field multifactorial experiment was conducted during 2016–2018 in the Left Bank of Ukraine, on the border of two soil and climatic zones of Ukraine - Forest-Steppe and Polissya. Peculiarities of plant growth and development, formation of "hybrids" yield (factor A) were studied: 'Ukrainskyi F1', 'P63LL06', 'NK Brio', 'NK Ferti' depending on "plant density" (factor B): 50, 55 , 60, 65 thousand pieces/hectare. We calculated and analyzed the sums of active, effective temperatures for two biological minima - 5 and 10 ° C; the sum of thermal units according to the method of Brown and Bootsma, 1993; coefficients of materiality of elements deviations of the agrometeorological mode of the current year from long-term averages; plasticity and yield stability according to the method of Eberthart S.A., Russel W.Q. (1966). Results. To pass the full cycle of sunflower plants development, the sum of active temperatures (t = 10 °C) for hybrid 'Ukrainskyi F1' – 2354.6; P63LL06 – 2306.4; 'NK Brio' – 2401.3; 'NK Ferti' – 2379.7; and the sum of effective temperatures for 'Ukrainskyi F1'- 1081.5; 'P63LL06' – 1056.9; 'NK Brio' – 1104.9; 'NK Ferti' – 1109.1 is required. The sum of temperatures, both at a biological minimum temperature 10 °C and 5 °C, meet biological needs of sunflower plants and is not a limiting factor for this crop growing. The sum of thermal units for the period April–October is 3780 on average for three years. During the period of active sunflower vegetation (April–August) the sum of thermal units is 2868–3258, significantly exceeding the sum of active and effective temperatures at biologically active temperatures 5 °С and 10 °С. The most determined limits of changes in active, effective temperatures and thermal units were observed in May – September. Conclusions. Plasticity and stability of sunflower yield more depending on hybrid and plants density than on conditions of the year. Yield stability coefficient for hybrid 'Ukrainskyi F1' was 1.68 - 2.30; 'P63LL06'- 2.51 - 3.14; 'NK Brio'- 3.15 - 4.63; 'NK Ferti' - 2.70 - 3.75 for yields, respectively: 2.16 - 3.11; 2.58 - 3.52; 3.20 - 4.12; 2.70 - 3.79 t/ha.

Pourpose. Establish compliance of heat and moisture resources to biological requirements of sunflower hybrids (Helianthus annuus), reveal criteria for assessing weather conditions in the northern regions of Ukraine; establish links between temperature, precipitation and yield.Methods. Field and mathematical methods were used. Field multifactorial experiment was conducted during 2016–2018 in the Left Bank of Ukraine, on the border of two soil and climatic zones of Ukraine - Forest-Steppe and Polissya. Peculiarities of plant growth and development, formation of "hybrids" yield (factor A) were studied: 'Ukrainskyi F1', 'P63LL06', 'NK Brio', 'NK Ferti' depending on "plant density" (factor B): 50, 55 , 60, 65 thousand pieces/hectare. We calculated and analyzed the sums of active, effective temperatures for two biological minima - 5 and 10 ° C; the sum of thermal units according to the method of Brown and Bootsma, 1993; coefficients of materiality of elements deviations of the agrometeorological mode of the current year from long-term averages; plasticity and yield stability according to the method of Eberthart S.A., Russel W.Q. (1966).Results. To pass the full cycle of sunflower plants development, the sum of active temperatures (t = 10 °C) for hybrid 'Ukrainskyi F1' – 2354.6; P63LL06 – 2306.4; 'NK Brio' – 2401.3; 'NK Ferti' – 2379.7; and the sum of effective temperatures for 'Ukrainskyi F1'- 1081.5; 'P63LL06' – 1056.9; 'NK Brio' – 1104.9; 'NK Ferti' – 1109.1 is required. The sum of temperatures, both at a biological minimum temperature 10 °C and 5 °C, meet biological needs of sunflower plants and is not a limiting factor for this crop growing. The sum of thermal units for the period April–October is 3780 on average for three years. During the period of active sunflower vegetation (April–August) the sum of thermal units is 2868–3258, significantly exceeding the sum of active and effective temperatures at biologically active temperatures 5 °С and 10 °С. The most determined limits of changes in active, effective temperatures and thermal units were observed in May – September.Conclusions. Plasticity and stability of sunflower yield more depending on hybrid and plants density than on conditions of the year. Yield stability coefficient for hybrid 'Ukrainskyi F1' was 1.68 - 2.30; 'P63LL06'- 2.51 - 3.14; 'NK Brio'- 3.15 - 4.63; 'NK Ferti' - 2.70 - 3.75 for yields, respectively: 2.16 - 3.11; 2.58 - 3.52; 3.20 - 4.12; 2.70 - 3.79 t/ha. | Мета. Встановити відповідність ресурсів тепла та вологи біологічним вимогам гібридів соняшнику (Helianthus annuus L.); встановити критеріальні показники оцінювання погодних умов в північних регіонах України; встановити зв’язки між температурним режимом, сумою опадів та врожайністю.Методи. Використовували польовий та математичний методи. Польовий багатофакторний дослід проводили в 2016–2018 роках в Лівобережному Лісостепу України на межі двох ґрунтово-кліматичних зон – Лісостепу і Полісся. Досліджували особливості росту та розвитку рослин, формування врожайності «гібридів» (фактор А) ‘Український F1’, ‘Р63LL06’, ‘НК Бріо’, ‘НК Ферті’ залежно від «густоти рослин» (фактор В): 50, 55, 60, 65 тис. шт./га. Розраховували й аналізували суми активних та ефективних температур за двома біологічними мінімумами – 5 і 10 °С; суми теплових одиниць за методикою Brown and Bootsma (1993); коефіцієнти суттєвості відхилень елементів погоди поточного року від середніх багаторічних; пластичність і стабільність урожайності за методикою Eberthart S. A., Russel W. Q. (1966).Результати. Для проходження повного циклу розвитку рослин соняшнику необхідна сума активних температур (tб.м. = 10 °C) для гібрида ‘Український F1’ – 2354,6; ‘Р63LL06’ – 2306,4; ‘НК Бріо’ – 2401,3; ‘НК Ферті’ – 2379,7; сума ефективних температур: ‘Український F1’ – 1081,5; ‘Р63LL06’ – 1056,9; ‘НК Бріо’ – 1104,9; ‘НК Ферті’ – 1109,1. Суми температур як за температурою біологічного мінімуму 10 °C, так і 5 °C, відповідають біологічним потребам рослин соняшнику і не є обмежувальним чинником для вирощування. Сума теплових одиниць за період квітень–жовтень складала в середньому за три роки 3780. За період активної вегетації соняшнику (квітень–серпень) сума теплових одиниць складала 2868–3258, суттєво перевищуючи суму активних та ефективних температур за біологічно активних температур 5 °С і 10 °С. Найбільш детерміновані межі змін активних, ефективних температур і теплових одиниць спостерігали в період травень–вересень.Висновки. Пластичність і стабільність урожайності соняшнику більше змінюються залежно від гібрида і густоти рослин, ніж від умов року. Коефіцієнт стабільності врожайності для гібрида ‘Український F1’ склав 1,68–2,30; ‘Р63LL06’ – 2,51–3,14; ‘НК Бріо’ – 3,15–4,63; ‘НК Ферті’ – 2,70–3,75 за урожайності 2,16–3,11; 2,58–3,52; 3,20–4,12; 2,70–3,79 т/га, відповідно. | Цель. Установить соответствие ресурсов тепла и влаги биологическим потребностям гибридов подсолнечника (Helianthus annuus L.); установить критериальные показатели оценивания погодных условий в северных регионах Украины; установить связь между температурным режимом, осадками и урожайностью.Методы. Использовали полевой и математический методы. Полевой многофакторный опыт проводили в 2016–2018 годах в Левобережной Лесостепи Украины. Исследовали особенности роста и развития растений, формирования урожайности «гибридов» (фактор А): ‘Украинский F1’, ‘Р63LL06’, ‘НК Брио’, ‘НК Ферти’ в зависимости от «густоты стояния растений» (фактор В): 50, 55, 60, 65 тыс. штук/га. Рассчитывали и анализировали суммы активных, эффективных температур по  двум биологическим минимумам – 5 и 10 °С; суммы тепловых единиц по методике Brown and Bootsma (1993); коэффициенты существенности отклонений погодных условий от средних многолетних данных; пластичность и стабильность урожайности по методике Eberthart S. A., Russel W. Q. (1966).Результаты. Для прохождения полного цикла развития растений подсолнечника, необходима сумма активных температур (tб.м. = 10 °C) для гибрида ‘Украинский F1’ – 2355; ‘Р63LL06’ – 2306; ‘НК Брио’ – 2401; ‘НК Ферти’ – 2380; сумма эффективных температур: ‘Украинский F1’ – 1082; ‘Р63LL06’ – 1057; ‘НК Брио’ – 1104,9; ‘НК Ферти’ – 1109. Суммы температур как при биологическом минимуме 10 °C, так и 5 °C, соответствуют биологическим требованиям растений подсолнечника и не являются лимитирующим фактором для выращивания. Сумма тепловых единиц за период апрель–октябрь составляла в среднем за три года – 3780. В период активной вегетации подсолнечника (апрель–август) сумма тепловых единиц составляла 2868–3258 и существенно превышала сумму активных и эффективных температур при биологически активных температурах 5 °С и 10 °С. Наиболее детерминированные границы изменений активных, эффективных температур и тепловых единиц наблюдали в мае–сентябре.Выводы. Пластичность и стабильность урожайности подсолнечника больше изменяются в зависимости от гибрида и густоты стояния растений, чем от погодных условий года. Коэффициент стабильности урожайности для гибрида ‘Украинский F1’ составил 1,68–2,30; ‘Р63LL06’ – 2,51–3,14; ‘НК Брио’ – 3,15–4,63; ‘НК Ферти’ – 2,70–3,75 при урожайности 2,16–3,11; 2,58–3,52; 3,20–4,12; 2,70–3,79 т/га соответственно.

Pourpose. Establish compliance of heat and moisture resources to biological requirements of sunflower hybrids (Helianthus annuus), reveal criteria for assessing weather conditions in the northern regions of Ukraine; establish links between temperature, precipitation and yield. Methods. Field and mathematical methods were used. Field multifactorial experiment was conducted during 2016–2018 in the Left Bank of Ukraine, on the border of two soil and climatic zones of Ukraine - Forest-Steppe and Polissya. Peculiarities of plant growth and development, formation of "hybrids" yield (factor A) were studied: 'Ukrainskyi F1', 'P63LL06', 'NK Brio', 'NK Ferti' depending on "plant density" (factor B): 50, 55 , 60, 65 thousand pieces/hectare. We calculated and analyzed the sums of active, effective temperatures for two biological minima - 5 and 10 ° C; the sum of thermal units according to the method of Brown and Bootsma, 1993; coefficients of materiality of elements deviations of the agrometeorological mode of the current year from long-term averages; plasticity and yield stability according to the method of Eberthart S.A., Russel W.Q. (1966). Results. To pass the full cycle of sunflower plants development, the sum of active temperatures (t = 10 °C) for hybrid 'Ukrainskyi F1' – 2354.6; P63LL06 – 2306.4; 'NK Brio' – 2401.3; 'NK Ferti' – 2379.7; and the sum of effective temperatures for 'Ukrainskyi F1'- 1081.5; 'P63LL06' – 1056.9; 'NK Brio' – 1104.9; 'NK Ferti' – 1109.1 is required. The sum of temperatures, both at a biological minimum temperature 10 °C and 5 °C, meet biological needs of sunflower plants and is not a limiting factor for this crop growing. The sum of thermal units for the period April–October is 3780 on average for three years. During the period of active sunflower vegetation (April–August) the sum of thermal units is 2868–3258, significantly exceeding the sum of active and effective temperatures at biologically active temperatures 5 °С and 10 °С. The most determined limits of changes in active, effective temperatures and thermal units were observed in May – September. Conclusions. Plasticity and stability of sunflower yield more depending on hybrid and plants density than on conditions of the year. Yield stability coefficient for hybrid 'Ukrainskyi F1' was 1.68 - 2.30; 'P63LL06'- 2.51 - 3.14; 'NK Brio'- 3.15 - 4.63; 'NK Ferti' - 2.70 - 3.75 for yields, respectively: 2.16 - 3.11; 2.58 - 3.52; 3.20 - 4.12; 2.70 - 3.79 t/ha.

Purpose. To reveal the scientific bases of forming the conveyor production of commercial products of lettuce, Lactuca sativa L., varieties in the conditions of the Western Forest-Steppe of Ukraine. Methods. Field research was conducted during 2015–2017 at the research field of the Department of Horticulture and Vegetable Growing of the Lviv National Agrarian University in accordance with the Methodology on Experimental Techniques in Vegetable and Melon Growing (2001) and Methods of Expertise of lettuce, Lactuca sativa L., varieties. Results. It is revealed that the soil and climatic conditions of the Western Forest-Steppe of Ukraine contri­bute to the optimal growth and development of all lettuce varieties of the corresponding types, as evidenced by the structure of conveyor receipt of fresh commodity products to the consumer (first decade of April – first decade of November). The shortest growing season was provided by lettuce varieties var. secalina ‘Zorepad, ‘Malakhit, ‘Dublianskyi’, which have the shortest period from seedlings to technical ripeness (21–42 days). Therefore, varieties of this variation occupy the lar­gest share in the conveyor production of commercial products, which, with early spring sowing in open ground (April 14–20), comes to the consumer in the first decade of May. Winter sowing (21.11) ensured the receipt of fresh produce in the first decade of April. Commercial products by mass of edible organs, shape of the rosette of leaves (heads, stems), color, consistency and taste qualities corresponds to the technical requirements for Lactuca sativa L. Conclusions. The selection of varieties of lettuce for the conveyor production of commercial products should be carried out taking into account the variety of the corresponding type, ripeness group, and timing of sowing. The receipt of fresh lettuce to the consumer is directly dependent on the timing of seeds sowing (early spring, late spring, summer-autumn and winter).

Purpose. To reveal the scientific bases of forming the conveyor production of commercial products of lettuce, Lactuca sativa L., varieties in the conditions of the Western Forest-Steppe of Ukraine. Methods. Field research was conducted during 2015–2017 at the research field of the Department of Horticulture and Vegetable Growing of the Lviv National Agrarian University in accordance with the Methodology on Experimental Techniques in Vegetable and Melon Growing (2001) and Methods of Expertise of lettuce, Lactuca sativa L., varieties. Results. It is revealed that the soil and climatic conditions of the Western Forest-Steppe of Ukraine contri­bute to the optimal growth and development of all lettuce varieties of the corresponding types, as evidenced by the structure of conveyor receipt of fresh commodity products to the consumer (first decade of April – first decade of November). The shortest growing season was provided by lettuce varieties var. secalina ‘Zorepad, ‘Malakhit, ‘Dublianskyi’, which have the shortest period from seedlings to technical ripeness (21–42 days). Therefore, varieties of this variation occupy the lar­gest share in the conveyor production of commercial products, which, with early spring sowing in open ground (April 14–20), comes to the consumer in the first decade of May. Winter sowing (21.11) ensured the receipt of fresh produce in the first decade of April. Commercial products by mass of edible organs, shape of the rosette of leaves (heads, stems), color, consistency and taste qualities corresponds to the technical requirements for Lactuca sativa L. Conclusions. The selection of varieties of lettuce for the conveyor production of commercial products should be carried out taking into account the variety of the corresponding type, ripeness group, and timing of sowing. The receipt of fresh lettuce to the consumer is directly dependent on the timing of seeds sowing (early spring, late spring, summer-autumn and winter).

Цель. Раскрыть научные основы формирования конвейера производства товарной продукции сортов салата посевного Lactuca sativa L. в условиях Западной Лесостепи Украины. Методы. Полевые исследования проводили в течение 2015–2017 гг. на опытном поле кафедры садоводства и овощеводства Львовского национального аграрного университета в соответствии с Методикой исследовательского дела в овощеводстве и бахчеводстве (2001) и Методикой проведения экспертизы сортов салата посевного Lactuca sativa L. на отличимость, однородность и стабильность (2007). Результаты. Установлено, что почвенно-климатические условия Западной Лесостепи Украины способствуют оптимальному росту и развитию растений салата посевного всех разновидностей соответствующих типов о чем свидетельствует структура конвейерного поступления свежей товарной продукции к потребителю (первая декада апреля – первая декада ноября). Самый короткий период вегетации обеспечили сорта салата посевного var. secalina ‘Зорепад’, ‘Малахіт’, ‘Дублянський’, которые имеют самый короткий период от всходов до технической спелости – 21–42 суток. Сорта этой разновидности занимают наибольший удельный вес в конвейерном производстве товарной продукции, которая при ранневесенних сроках посева в открытую почву (14.04–20.04) уже в первой декаде мая поступает к потребителю. Посев под зиму (21.11) обеспечил поступление свежей продукции уже в первой декаде апреля. Товарная продукция по массе продуктовых органов, габитусе розетки листьев (головки, стеблей), окрас­ке, консистенции и вкусовым качествам соответствует техническим требованиям к товарной продукции Lactuca sativa L. Выводы. Подбор сортов салата посевного для конвейерного производства товарной продукции необходимо проводить с учетом разновидности соответствующего типа, группы спелости, сроков посева. Поступление свежей товарной продукции салата посевного к потребителю находится в прямой зависимости от сроков посева семян (ранневесенний, поздневесенний, летне-осенний и под зиму). | Purpose. To reveal the scientific bases of forming the conveyor production of commercial products of lettuce, Lactuca sativa L., varieties in the conditions of the Western Forest-Steppe of Ukraine.Methods. Field research was conducted during 2015–2017 at the research field of the Department of Horticulture and Vegetable Growing of the Lviv National Agrarian University in accordance with the Methodology on Experimental Techniques in Vegetable and Melon Growing (2001) and Methods of Expertise of lettuce, Lactuca sativa L., varieties.Results. It is revealed that the soil and climatic conditions of the Western Forest-Steppe of Ukraine contri­bute to the optimal growth and development of all lettuce varieties of the corresponding types, as evidenced by the structure of conveyor receipt of fresh commodity products to the consumer (first decade of April – first decade of November). The shortest growing season was provided by lettuce varieties var. secalina ‘Zorepad, ‘Malakhit, ‘Dublianskyi’, which have the shortest period from seedlings to technical ripeness (21–42 days). Therefore, varieties of this variation occupy the lar­gest share in the conveyor production of commercial products, which, with early spring sowing in open ground (April 14–20), comes to the consumer in the first decade of May. Winter sowing (21.11) ensured the receipt of fresh produce in the first decade of April. Commercial products by mass of edible organs, shape of the rosette of leaves (heads, stems), color, consistency and taste qualities corresponds to the technical requirements for Lactuca sativa L.Conclusions. The selection of varieties of lettuce for the conveyor production of commercial products should be carried out taking into account the variety of the corresponding type, ripeness group, and timing of sowing. The receipt of fresh lettuce to the consumer is directly dependent on the timing of seeds sowing (early spring, late spring, summer-autumn and winter). | Мета. Розкрити наукові основи формування конвеєру виробництва товарної продукції сортів салату посівного Lactuca sativa L. в умовах Західного Лісостепу України. Методи. Польові дослідження проводили впродовж 2015–2017 рр. на дослідному полі кафедри садівництва та овочівництва Львівського національного аграрного університету відповідно до Методики дослідної справи в овочівництві та баштанництві (2001) та Методики проведення експертизи сортів салату посівного Lactuca sativa L. на відмінність, однорідність і стабільність (2007). Результати. ґрунтово-кліматичні умови Західного Лісостепу України сприяють оптимальному росту й розвитку рослин салату посівного всіх різновидів відповідних типів, про що свідчить структура конвеєрного надходження свіжої товарної продукції до споживача (перша декада квітня – перша декада листопада). Найкоротший період вегетації забезпечили сорти салату посівного var. secalina ‘Зорепад’, ‘Малахіт’, ‘Дублянський’, які мають найкоротший період від сходів до технічної стиглості – 21–42 доби. Тому сорти цієї різновидності займають найбільшу питому частку в конвеєрному виробництві товарної продукції, яка за ранньовесняних строків сівби у відкритому ґрунті (14.04–20.04) вже в першій декаді травня надходить до споживача. Сівба під зиму (21.11) забезпечила надходження свіжої продукції вже в першій декаді квітня. Товарна продукція за масою продуктових органів, габітусом розетки листків (головки, стебла), забарвленням, консистенцією та смаковими якостями відповідає технічним вимогам до товарної продукції Lactuca sativa L. Висновки. Підбір сортів салату посівного для конвеєрного виробництва товарної продукції необхідно проводити з урахуванням різновидності відповідного типу, групи стиглості, строків сівби. Надходження свіжої товарної продукції салату посівного до споживача перебуває у прямій залежності від строків сівби насіння (ранньовесняний, пізньовесняний, літньо-осінній та під зиму).

Purpose. Identifying new scab-resistant apple varieties with high biological potential by the set of agronomic characters and the ability to realize it effectively in various soil and climatic conditions. Methods. Field, laboratory, comparison, generalization, statistical ones. Results. The author presents the results of study of 17 scab-resistant non-irrigated apple varieties on a semi-dwarf rootstock as to their adaptability to biotic and abio­tic stressors as well as their economic productivity. The studied varieties appeared to be winter-hardy, frost- and heat-resistant, but medium drought-tolerant ones. They are characterized by weak and moderate susceptibility to powdery mildew, high resistance to fruit rot and very low amounts of brown spot, except for Gold Rush variety. Such 10 year old varieties as ‘Edera’, Florina’, ‘Amulet’ and ‘Perlyna Kyieva’ and 8 year old ‘Afrodita’, ‘Vitos’, ‘Orlovskoie Polesie’ and ‘Topaz’ formed the highest productivity during the years of study. Due to the pollen quality and high interfertility, ‘Revena’ and ‘Gold Rush’ varieties were identified as universal pollinators for winter scab-resistant apple varieties. Conclusions. Such ecologically resistant winter varieties as ‘Topaz’, ‘Freedom’, ‘Edera’ and autumnal ‘Remo’, ‘Afrodita’, ‘Vitos’, ‘Amulet’ were recognized as promising for new intensive non-irrigated plantations in the Forest-Steppe zone of Ukraine. They can be the basis of new gardens occupying 25–30% of the area where ecologically safe fruits for various target purposes will be grown supplying demands of the population and processing industry.

Purpose. Identifying new scab-resistant apple varieties with high biological potential by the set of agronomic characters and the ability to realize it effectively in various soil and climatic conditions. Methods. Field, laboratory, comparison, generalization, statistical ones. Results. The author presents the results of study of 17 scab-resistant non-irrigated apple varieties on a semi-dwarf rootstock as to their adaptability to biotic and abio­tic stressors as well as their economic productivity. The studied varieties appeared to be winter-hardy, frost- and heat-resistant, but medium drought-tolerant ones. They are characterized by weak and moderate susceptibility to powdery mildew, high resistance to fruit rot and very low amounts of brown spot, except for Gold Rush variety. Such 10 year old varieties as ‘Edera’, Florina’, ‘Amulet’ and ‘Perlyna Kyieva’ and 8 year old ‘Afrodita’, ‘Vitos’, ‘Orlovskoie Polesie’ and ‘Topaz’ formed the highest productivity during the years of study. Due to the pollen quality and high interfertility, ‘Revena’ and ‘Gold Rush’ varieties were identified as universal pollinators for winter scab-resistant apple varieties. Conclusions. Such ecologically resistant winter varieties as ‘Topaz’, ‘Freedom’, ‘Edera’ and autumnal ‘Remo’, ‘Afrodita’, ‘Vitos’, ‘Amulet’ were recognized as promising for new intensive non-irrigated plantations in the Forest-Steppe zone of Ukraine. They can be the basis of new gardens occupying 25–30% of the area where ecologically safe fruits for various target purposes will be grown supplying demands of the population and processing industry.

The article provides summary of post-registration research on Barley varieties in 2008-2009. Best varieties of Winter and Spring Barley for different climatic and soil conditions of Ukraine are specified, as well as their productivity subject to the influence of environmental factors.

The article provides summary of post-registration research on Barley varieties in 2008-2009. Best varieties of Winter and Spring Barley for different climatic and soil conditions of Ukraine are specified, as well as their productivity subject to the influence of environmental factors.

The study of impact of complex application of biological compositions based on fixing nitrogen by microorganisms and plant lectin and nitric fertilizers on productivity and quality of grain of winter wheat on the dark-grey soil in the field terms was conducted. It is shown, that presowing treatment of seed by biological compositions stimulated forming of greater productivity with the best quality.

Purpose. Theoretical and experimental substantiation of introduction of “Romantica” roses originated by Meilland company under the conditions of the Right-Bank Forest-Steppe Zone of Ukraine. Methods. Biometrical, comparative-morphological, statistic ones. Results. Viability, growth and development indices as well as ornamental qualities (tolerance for winter conditions, frost hardiness, drought resistance, complex disease and pest resistance, habit maintenance, shoot formation, flowering, coloration, shape of flowers, petal number etc.) were analyzed for 12 rose cultivars of “Romantica” series planted on the collection and exhibition plots of the National Dendrological Park «Sofiivka» NAS of Ukraine. The investigations were conducted within 2012–2015. The most of the cultivars got the mark of introduction success 41–45 points of 50; so, the cultivars are totally promising for introduction into the conditions of the Right-Bank Forest-Steppe Zone of Ukraine. ‘Leonardo da Vinci’ and ‘Yves Piaget’ cultivars got point number 35–38 and they can be considered promising ones. The acclimatization number for the most of the investigated cultivars was 85–90 points of 100 that means good adaptation of the plants in the conditions of the Right-Bank Forest-Steppe Zone of Ukraine. The adaptation of cv. ‘Leonardo da Vinci’ and cv. ‘Yves Piaget’ roses (point number 75) can be considered satisfactory. The total evaluation of “Romantica” roses ornamental qualities made 76–87 points of 100; so, all the cultivars display high ornamental qualities and deserve to be introduced to the production. Conclusions. The garden roses of “Romantica” series originated by Meilland company being introduced into the conditions of the Right-Bank Forest-Steppe Zone of Ukraine are adapted well in the introduction region and they are promising for the subsequent introduction.

The best cabbage lettuce varieties for seedling and non seedling planting under the conditions of the open soil were defined. The potential productivity of the varieties under research in the conditions of the open soil were grounded from the scientific point of view. The influence of planting methods on plants productivity, produvtivity and quality of fresh lettuce heads was analyzed.

The article performs the requirements to the preparation and Table characteristics content of the holding Test guidelines examination of new varieties to identify the difference, uniformity and stability. It is pointed that the identification of varieties is carried by the morphological characteristics description as presented in the table. Being standard these characteristics comply with ones requirements. An characteristics explanation with an asterisk (*) is given, their importance for the international harmonization of variety descriptions by States UPOV Members is indicated. The article presents an explanation of the grouping characteristics with documented revealing conditions. As it is commonly determined any characteristic begins with the plants or plants parts identification, which after a colon is followed by the body or its part nomination or by observed peculiarity. The requirements to the formulation of characteristics nomination are performed. It should be clear enough for understanding and without conditions determining. The degree of every characteristic nomination manifestation for its defining and making harmonizing descriptions is set. The corresponding numeric code, which facilitates the entry of data, drafting descriptions and their exchanging is given to each revealing degree. The morphological code configuration of variety phenotype is formed by the codes. It is emphasized that the features are divided into qualitative, quantitative and pseudo qualitative. The presentation order of the features in the table corresponds to the botanical or chronological order. It is noted that the Test guidelines should contain all the features suitable for holding examination at BOC and that there should not be any restrictions on their being included into Methods. Every feature can be used from a complete features list.

Purpose. To analyze the divergence of early maturing source material of corn Zea mays L. in heterosis breeding for the genetic base formation at the State Institution the Institute of Grain Crops of the NAAS of Ukraine. Methods. Field (comprehensive assessment of morphobiological and economically valuable characteristics of the source material and maize hybrids) individual selection, cumulative and recurrent selection, backross and testcrosses bree­ding methods; laboratory; analysis and synthesis; statistical. Results. The results of research on the analysis of the divergence of early maturing corn source material in the conditions of the Steppe of Ukraine has become a developed harmonized working collection of corn breeding samples adapted to the stressful conditions of this region. The gradual cyclical improvement of the lines made it possible to form the core of the genetic diversity of FAO 150–290 early maturing specimens of the southern ecotype, which are competitive in heterosis breeding. The complexity of breeding for early maturity in the steppe conditions is due to the lack of material adapted to the stress factors of the South of Ukraine. The available early maturing lines of the world collection F2, F7, Ер1, Ма21, Ма23, Со125, Со255, См7, PLS61, S72, etc., were distinguished by high cold resistance, good starting plant development, intensive accumulation of dry matter during ripening, but not adapted to the deficiency of moisture in the soil and high summer temperatures. According to the results of the experiment, it was revealed that, in terms of breeding, lines of Lancaster plasma (DK427 and DK633) were the most plastic, due to which a number of new mid-early lines were obtained, for example DK2/427, DK267, DK266/417, DK633/266, DK296, etc., which were included in the registered hybrids. Formation of the genetic base of early maturing maize source material for heterosis breeding and systematization accor­ding to different breeding characteristics provided a balance of samples of alternative components, which will be further used to model heterosis hybrids in the early maturing group. Conclusions. The updated basic collection of lines is represented by the samples of plasma Iodent: DK744SVZM, DK216SVZM, DK4173SVZM, DK235zS, DK257zM, SV, DK365SVZM, DK777ZMSV, DK733-7zM,SV, DK315SVZM; Lancaster: DK296zS,VM, DK633/266zS,VM, DK2965ZSZM, DK2953 ZSZM, DK3023 ZSZM, DK236zS,ZM; Raid (SSS): DK232MV, DK2323MV, DK239MV; Mixed: DK253ZSZM, DK273MV, DK272zS, DK281SV, DK233zM,SV, DK959MV, DK9527 ZSZM, DK247MV, DK2442MV, which is the basis of the genetic diversity of early ripening corn samples included in the State register of plant varie­ties suitable for dissemination in Ukraine.

Мета. На основі всебічного дослідження особливостей росту, розвитку, плодоношення та якості плодів рослин спонтанних мутантів яблуні (Malus domestica Borkh.) сорту ‘Jonagold’ виділити такі, що відрізняються від вихідного сорту за силою росту дерев та переважають за врожайністю, товарними якостями, лежкістю плодів та економічною ефективністю виробництва останніх.                    Методи. Польовий, лабораторний, порівняння, узагальнення та математичної статистики. Результати. Подано результати вивчення особливостей росту та плодоношення 20 українських спонтанних клонів сорту ‘Jonagold’ в умовах Західного Лісостепу України. Встановлено, що рослини досліджуваних клонів за строками початку і тривалістю основних фенологічних фаз і вегетаційного періоду не відрізнялись від більшості поширених і добре адаптованих до умов Поділля сортів яблуні. Знімальна стиглість плодів у клонів наставала у другій‑третій декадах вересня, з різницею у сім діб. Дерева більшості клонів (ДП‑4, ДП‑5, ДП‑9, ДП‑10, ДП‑13, ДП‑14 і ДП‑17) були середньорослими. Урожайність п’яти-восьмирічних насаджень клонів становить 12,1–32,3 т/га, що забезпечує економічно ефективне культивування в умовах Поділля, рівень рентабельності виробництва становить 66–242%. Усі спонтанні мутанти формують плоди більші за середній розмір (крім ДП‑20, великі), красиві, ошатні, які, залежно від клону, різняться за інтенсивністю та характером покривного забарвлення. Клони ДП‑1, ДП‑3, ДП‑17, ДП‑18 і ДП‑19 відзначались найбільшим виходом яблук вищого та першого ґатунку і за цією властивістю значно перевищили контрольний сорт. Випробовувані клони поділено на три групи за строками достигання плодів: ранньозимові, зимові, пізньозимові. Висновки. Багаторічне оцінювання об’єктів дослідження дозволило встановити, що біологічні властивості рослин українських клонів сорту ‘Jonagold’ відповідають кліматичним умовам Західного Лісостепу України. За силою росту дерев більшість із них належать до групи середньорослих (ДП‑4, ДП‑5, ДП‑9, ДП‑10, ДП‑13, ДП‑14 і ДП‑17) і характеризуються мішаним типом плодоношення. Клони ДП‑1, ДП‑3, ДП‑17, ДП‑18 і ДП‑19 виділяються високим виходом плодів вищого та першого ґатунку. За основними показниками якості плодів кращими визнано клони ДП‑3, ДП‑8, ДП‑13, ДП‑14, ДП‑16, ДП‑17, ДП‑18 і ДП‑20; найвищу економічну ефективність виробництва яблук на Поділлі забезпечують клони ДП‑14, ДП‑17, ДП‑18 і ДП‑19. Останні рекомендовано для реєстрації у Державному реєстрі сортів рослин, як перспективні для впровадження у насадження з виробництва плодів універсального призначення у зоні Західного Лісостепу України.

Purpose. To evaluate Tartary buckwheat variety ‘Kalyna’ according to morphological, productive and quality indicators in the conditions of the Research Center “State Agra­rian and Engineering University in Podilia”. Methods. The studies were carried out in the field crop rotation of the Research Center “Podillia” of the State Agrarian and Engi­neering University in Podilia (SAEU) in 2015–2020. The soil cover of the experimental field is represented mainly by low-humus, weakly leached soils. Experiment setting, material evaluation, analysis of plants, yield and grain quality were carried out in accordance with the generally accepted methods of state variety testing. An assessment of the Tartary buckwheat variety ‘Kalyna’ was carried out in comparison with the common buckwheat variety ‘Victoriia’. Results. The growing season duration of Tartary buckwheat variety ‘Kalyna’ was 87 days (38 days vegetative and 49 days gene­rative). In the studied variety, a larger number of the 1st order branches up to 5.5 pcs was observed. The number of leaves on the plant was 22–28 pcs./plants. In the studied variety, more than 50% of the grains were located on the main stem and the first order branches, while in common buckwheat this indicator was only 30%. Productivity was 2,28 t/ha, the number of grains in inflorescences was 4,4 grains, in common buckwheat – 0,72 t/ha, and 2.2 grains/inflorescence, respectively. The thousand kernel weight in Tartary buckwheat variety ‘Kalyna’ is 10.2 g less than in common buckwheat variety ‘Victoriia’ and is 17.4 g, with hulls – 19.5%, which is 3.2% less then in common buckwheat variety.Assessment of Tartary buckwheat variety ‘Kalyna’ for resistance to the effects of bio- and abiotic factors indicates that it was at the level of common buckwheat variety ‘Victoriia’.In terms of resistance to abiotic factors, ‘Kalyna’ variety is characterized by high resistance to spontaneous fallof grain (5 scores) and has simultaneous grain ripening (5 scores). Conclusions.The morphological and economic-biological indicators of Tartary buckwheat variety ‘Kalyna’ are significantly higher than the common buckwheat varie­ty ‘Victoriia’. It is recommended to grow Tartary buckwheat variety ‘Kalyna’ as a valuable cereal crop in the Western Forest-Steppe zone.

Purpose. To evaluate Tartary buckwheat variety ‘Kalyna’ according to morphological, productive and quality indicators in the conditions of the Research Center “State Agra­rian and Engineering University in Podilia”. Methods. The studies were carried out in the field crop rotation of the Research Center “Podillia” of the State Agrarian and Engi­neering University in Podilia (SAEU) in 2015–2020. The soil cover of the experimental field is represented mainly by low-humus, weakly leached soils. Experiment setting, material evaluation, analysis of plants, yield and grain quality were carried out in accordance with the generally accepted methods of state variety testing. An assessment of the Tartary buckwheat variety ‘Kalyna’ was carried out in comparison with the common buckwheat variety ‘Victoriia’. Results. The growing season duration of Tartary buckwheat variety ‘Kalyna’ was 87 days (38 days vegetative and 49 days gene­rative). In the studied variety, a larger number of the 1st order branches up to 5.5 pcs was observed. The number of leaves on the plant was 22–28 pcs./plants. In the studied variety, more than 50% of the grains were located on the main stem and the first order branches, while in common buckwheat this indicator was only 30%. Productivity was 2,28 t/ha, the number of grains in inflorescences was 4,4 grains, in common buckwheat – 0,72 t/ha, and 2.2 grains/inflorescence, respectively. The thousand kernel weight in Tartary buckwheat variety ‘Kalyna’ is 10.2 g less than in common buckwheat variety ‘Victoriia’ and is 17.4 g, with hulls – 19.5%, which is 3.2% less then in common buckwheat variety.Assessment of Tartary buckwheat variety ‘Kalyna’ for resistance to the effects of bio- and abiotic factors indicates that it was at the level of common buckwheat variety ‘Victoriia’.In terms of resistance to abiotic factors, ‘Kalyna’ variety is characterized by high resistance to spontaneous fallof grain (5 scores) and has simultaneous grain ripening (5 scores). Conclusions.The morphological and economic-biological indicators of Tartary buckwheat variety ‘Kalyna’ are significantly higher than the common buckwheat varie­ty ‘Victoriia’. It is recommended to grow Tartary buckwheat variety ‘Kalyna’ as a valuable cereal crop in the Western Forest-Steppe zone.

Purpose. Developing technology for clonal micropropagation of peppermint (Mentha piperita L.) plants of Ukrainian breeding based on the complex of methods of isolated tissue and organ culture in vitro. Methods. During the experiment, such methods as isolated tissue and organ culture in vitro, clonal micropropagation, detached scion grafting, chemotherapy with adding of virucide Ribavirin to the nutrient medium, biometric and statistical ones were used. Results. The stepped procedure of sterilization that we have developed allows to receive 88–100% of sterile explants. For M. piperita L. introduction into culture and clonal micropropagation, Murashige and Skoog (MS) nut­rient medium appeared to be optimal supplemented with 6-benzylaminopurine (0.75 mg/l), adenine (0.05 mg/l), indole-3-acetic acid (IAA) (0.05 mg/l) and gibberellic acid (0.5 mg/l) on which the reproduction ratio on the 28th day ranged between 1:7 and 1:15. For recovery of plants from viral infection, virucide Ribavirin at concentration of 10 mg/l was added to the nutrient medium. The proposed nutrient medium for rhizogenesis, that contained IAA (0.5 mg/l) and indole butyric acid (IBA) (0.5 mg/l), allows to obtain the frequency of rhizogenesis up to 84–100%. Regenerated plants were adapted to the conditions in vivo on substrate peat : universal soil : perlite : sand in the ratio 2:1:1:1. The survival rate for peppermint varieties amounted to 96–100%. Conclusions. Biotechnological scheme was developed that permits to get healthy, purebred planting material and intensively propagate plants for supplying breeding programs of the Experimental Station for Medicinal Plants of the Institute of Agroecology and Environmental Management of the National Academy of Agrarian Sciences of Ukraine, among which such varieties as ‘Lebedyna pisnia’ and ‘Ukrainska pertseva’ were selected as the most promising for clonal micropropagation.

β-tubulin, calmodulin, internal transcribed spacer and partial lsu-rDNA, RNA polymerase 2, DNA replication licensing factor Mcm7, and pre-rRNA processing protein Tsr1 were amplified and sequenced from numerous isolates belonging to Aspergillus sect. versicolor. The isolates were analyzed phylogenetically using the concordance model to establish species boundaries. Aspergillus austroafricanus, A. creber, A. cvjetkovicii, A. fructus, A. jensenii, A. puulaauensis, A. subversicolor, A. tennesseensis and A. venenatus are described as new species and A. amoenus, A. protuberus, A. sydowii, A. tabacinus and A. versicolor are accepted as distinct species on the basis of molecular and phenotypic differences. PCR primer pairs used to detect A. versicolor in sick building syndrome studies have a positive reaction for all of the newly described species except A. subversicolor.