{"title":"不同基质对六月草莓转轮生产的影响。“Senga Sengana”","authors":"V. Avdiu, B. Dragusha, Egzona Hajra, G. Hodolli","doi":"10.17221/27/2022-hortsci","DOIUrl":null,"url":null,"abstract":"Producing high-quality daughter plants of the June-bearing strawberry is very important for fruit production around the year. This study was conducted to investigate the impacts of different substrates on the runner production of the June-bearing strawberry cultivar ‘Senga Sengana’. In April 2019, strawberry mother plants were planted while the daughter plants were examined November 2019. The nursery trial field was separated into four substrate treatments, each included ten strawberry mother plants, approximately homogeneous. The place where the mother plants were planted was with the same substrate (PTS substrate “Pindstrup”) and separated from the field for the rooting of the daughter plants. In the field for the rooting of the daughter plants, four types of substrates were used: The first substrate treatment (S1) (soil 50% – decomposed manure 50%); the second substrate treatment (S2) (PTS substrate “Pindstrup” with modules (pots) with a volume of 200 mL/daughter plant); the third substrate treatment S3 (river sand 50% – soil 50%); lastly, substrate treatment four S4 (sawdust 100%). During the research, several parameters were determined for the mother plants: the crown diameter, number of flowers, number of runners per plant, number of daughter plants per runner and number of daughter plants per plant. The examination of some of the qualitative parameters was also performed on the daughter plants: the crown diameter, root length and number of roots. Based on these parameters, the daughter plants were categorised according to the standards: A++, A+, A, A–, OS (out of the standard). From the examined results, it was concluded that S3 formed the largest number of daughter plants at 123 (A++ 19.1, A+ 45.1, A 28.7, A– 17.8, OS 12.3 plants); S2 formed 69.4 daughter plants, but with the highest standards (A++ 34.7, A+ 33.6, A– 1.1 plants); S4 formed 74.8 daughter plants (A++ 26.2, A+ 30.4, A 14 OS 4.2 plants), while S1 formed 62 daughter plants and showed the worst results for both the number of plants and the standard (A+ 7, A 3.8, A– 0.8, OS 50.4 plants).","PeriodicalId":13110,"journal":{"name":"Horticultural Science","volume":" ","pages":""},"PeriodicalIF":1.0000,"publicationDate":"2022-12-22","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Effects of different substrates on the runner production of the June-bearing strawberry cv. ‘Senga Sengana’\",\"authors\":\"V. Avdiu, B. Dragusha, Egzona Hajra, G. Hodolli\",\"doi\":\"10.17221/27/2022-hortsci\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Producing high-quality daughter plants of the June-bearing strawberry is very important for fruit production around the year. This study was conducted to investigate the impacts of different substrates on the runner production of the June-bearing strawberry cultivar ‘Senga Sengana’. In April 2019, strawberry mother plants were planted while the daughter plants were examined November 2019. The nursery trial field was separated into four substrate treatments, each included ten strawberry mother plants, approximately homogeneous. The place where the mother plants were planted was with the same substrate (PTS substrate “Pindstrup”) and separated from the field for the rooting of the daughter plants. In the field for the rooting of the daughter plants, four types of substrates were used: The first substrate treatment (S1) (soil 50% – decomposed manure 50%); the second substrate treatment (S2) (PTS substrate “Pindstrup” with modules (pots) with a volume of 200 mL/daughter plant); the third substrate treatment S3 (river sand 50% – soil 50%); lastly, substrate treatment four S4 (sawdust 100%). During the research, several parameters were determined for the mother plants: the crown diameter, number of flowers, number of runners per plant, number of daughter plants per runner and number of daughter plants per plant. The examination of some of the qualitative parameters was also performed on the daughter plants: the crown diameter, root length and number of roots. Based on these parameters, the daughter plants were categorised according to the standards: A++, A+, A, A–, OS (out of the standard). From the examined results, it was concluded that S3 formed the largest number of daughter plants at 123 (A++ 19.1, A+ 45.1, A 28.7, A– 17.8, OS 12.3 plants); S2 formed 69.4 daughter plants, but with the highest standards (A++ 34.7, A+ 33.6, A– 1.1 plants); S4 formed 74.8 daughter plants (A++ 26.2, A+ 30.4, A 14 OS 4.2 plants), while S1 formed 62 daughter plants and showed the worst results for both the number of plants and the standard (A+ 7, A 3.8, A– 0.8, OS 50.4 plants).\",\"PeriodicalId\":13110,\"journal\":{\"name\":\"Horticultural Science\",\"volume\":\" \",\"pages\":\"\"},\"PeriodicalIF\":1.0000,\"publicationDate\":\"2022-12-22\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"0\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Horticultural Science\",\"FirstCategoryId\":\"97\",\"ListUrlMain\":\"https://doi.org/10.17221/27/2022-hortsci\",\"RegionNum\":0,\"RegionCategory\":null,\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"Q3\",\"JCRName\":\"HORTICULTURE\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Horticultural Science","FirstCategoryId":"97","ListUrlMain":"https://doi.org/10.17221/27/2022-hortsci","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"HORTICULTURE","Score":null,"Total":0}
引用次数: 0
摘要
生产六月结草莓的优质子株对全年的水果生产非常重要。本研究旨在研究不同基质对六月草莓品种“Senga Sengana”转轮产量的影响。2019年4月,种植了草莓母株,而子株于2019年11月进行了检查。苗圃试验田分为四个基质处理,每个基质处理包括十株草莓母株,大致均匀。种植母株的地方使用相同的基质(PTS基质“Pindstrup”),并与田地分离,以使子株生根。在子植物生根的田地里,使用了四种类型的基质:第一种基质处理(S1)(土壤50%-腐熟肥料50%);第二次基质处理(S2)(PTS基质“Pindstrup”,具有体积为200mL/子植物的模块(盆));第三基质处理S3(河沙50%~土壤50%);最后,基质处理4个S4(木屑100%)。在研究过程中,为母株确定了几个参数:冠径、花数、单株转轮数、单株子株数和单株子株数量。还对子植物的一些定性参数进行了检查:冠径、根长和根数。根据这些参数,根据标准对子植物进行分类:A++、A+、A、A-、OS(不符合标准)。根据检测结果,S3在123株(A++19.1,A+45.1,A28.7,A-17.8,OS12.3株)形成了数量最多的子植物;S2形成69.4个子株,但标准最高(A++34.7,A+33.6,A-1.1株);S4形成74.8个子株(A++26.2,A+30.4,A14 OS 4.2株),而S1形成62个子株,在植物数量和标准方面都表现出最差的结果(A+7,A 3.8,A–0.8,OS 50.4株)。
Effects of different substrates on the runner production of the June-bearing strawberry cv. ‘Senga Sengana’
Producing high-quality daughter plants of the June-bearing strawberry is very important for fruit production around the year. This study was conducted to investigate the impacts of different substrates on the runner production of the June-bearing strawberry cultivar ‘Senga Sengana’. In April 2019, strawberry mother plants were planted while the daughter plants were examined November 2019. The nursery trial field was separated into four substrate treatments, each included ten strawberry mother plants, approximately homogeneous. The place where the mother plants were planted was with the same substrate (PTS substrate “Pindstrup”) and separated from the field for the rooting of the daughter plants. In the field for the rooting of the daughter plants, four types of substrates were used: The first substrate treatment (S1) (soil 50% – decomposed manure 50%); the second substrate treatment (S2) (PTS substrate “Pindstrup” with modules (pots) with a volume of 200 mL/daughter plant); the third substrate treatment S3 (river sand 50% – soil 50%); lastly, substrate treatment four S4 (sawdust 100%). During the research, several parameters were determined for the mother plants: the crown diameter, number of flowers, number of runners per plant, number of daughter plants per runner and number of daughter plants per plant. The examination of some of the qualitative parameters was also performed on the daughter plants: the crown diameter, root length and number of roots. Based on these parameters, the daughter plants were categorised according to the standards: A++, A+, A, A–, OS (out of the standard). From the examined results, it was concluded that S3 formed the largest number of daughter plants at 123 (A++ 19.1, A+ 45.1, A 28.7, A– 17.8, OS 12.3 plants); S2 formed 69.4 daughter plants, but with the highest standards (A++ 34.7, A+ 33.6, A– 1.1 plants); S4 formed 74.8 daughter plants (A++ 26.2, A+ 30.4, A 14 OS 4.2 plants), while S1 formed 62 daughter plants and showed the worst results for both the number of plants and the standard (A+ 7, A 3.8, A– 0.8, OS 50.4 plants).
期刊介绍:
The journal publishes results of basic and applied research from all areas of horticulture, fruit-growing, vegetable-growing, wine-making and viticulture, floriculture, ornamental gardening, garden and landscape architecture, concerning plants that are grown under the conditions of European temperate zone, or field plants that are considered as horticultural cultures. Original scientific papers, short communications and review articles are published in the journal. Papers are published in English (British spelling).
京公网安备 11010802042870号
京ICP备2023020795号-1
分享
求助内容:
应助结果提醒方式:
扫码关注我们
