浙江省油菜花期降水量风险评估

对浙江省66个县市(区)1971—2014年油菜花期降水量及油菜产量资料进行统计分析,并基于信息扩散的风险评估模型,对浙江省油菜花期降水量在各级降水量下的超越概率进行计算分析,评估各地油菜花期面临的旱涝风险;同时分析了浙江省油菜花期各级降水量风险值与油菜产量变化之间的关系。结果表明:油菜花期降水量严重过剩的风险高值区主要位于浙西南地区,降水量短缺风险高值区主要位于浙江省沿海岛屿及宁波的部分县市;浙江省油菜花期降水量短缺基本可以通过灌溉得到改善,但油菜减产与花期降水量过多显著相关,油菜花期降水量300 mm是油菜是否减产的阈值。该结果可为油菜种植合理布局及农业保险政策提供科学依据。     

光箨篌竹笋期生长规律初步研究

本文对光箨篌竹笋期的出笋规律、成竹规律以及竹笋的生长发育规律进行了研究。初步认为,光箨篌竹林分的母竹立竹度一般应保持在2500株/亩左右、Ⅰ～Ⅱ级母竹株数保持在40％以上时,才能保证林分的优质高产与稳产;抽枝成竹历期长短受竹笋笋级大小、出土早晚或立地环境条件的影响可相应延长或推迟2～4d左右,一般历时25d,竹笋开始抽枝成竹时的高度一般为5m左右;竹笋在生长发育高峰期明显受到气候因子的影响,尤其是对气温更为敏感。     

马尾松基因库无性系花期观察分析

在福建省沙县官庄林场石景山工区进行马尾松基因库无性系开花习性、花量、花期的观察。观察结果表明：不同无性系着生球花量的差异显著，始花期也有明显的差异，但也存在一定的同步性，大部分无性系雌花开放时间比雄花早４─９天。     

奎屯地区气象要素对玉米播种及苗期的影响

奎屯地区农七师位于天山北麓,准噶尔盆地的西南缘,总面积5986km2,其中作物种植面积120万亩,随着农七师产业结构的调整,2003年实施了“万头澳牛引进工程”,养牛业的发展使农七师畜牧业对玉米的需求量增加,尤其是澳牛养殖业对青贮玉米需求量更大,因此,研究分析气象要素对玉米播种及苗期的影响是重要工作之一。     

除污器堵塞对供暖系统的影响

作者结合工程实例,分析除污器堵塞现象对供暖系统的影响,提出应定期清理。     

灌水量对不同类型晚稻生育及产量影响的初步研究

采取盆栽遮雨人工定量灌水的方法,探讨了常规晚稻和杂交晚稻前后两大生育时期不同灌水量对生育和产量的影响.结果表明:两类型晚稻品种前后两个生育时期节水灌溉都能达到高产之目的,但不同类型和不同生育时期的最佳灌水量和节水效果不同.     

Sporulation of Pyrenopeziza brassicae (light leaf spot) on oilseed rape (Brassica napus) leaves inoculated with ascospores or conidia at different temperatures and wetness durations

In controlled environment experiments, sporulation of Pyrenopeziza brassicae was observed on leaves of oilseed rape inoculated with ascospores or conidia at temperatures from 8 to 20°C at all leaf wetness durations from 6 to 72 h, except after 6 h leaf wetness duration at 8°C. The shortest times from inoculation to first observed sporulation ( l ₀), for both ascospore and conidial inoculum, were 11–12 days at 16°C after 48 h wetness duration. For both ascospore and conidial inoculum (48 h wetness duration), the number of conidia produced per cm² leaf area with sporulation was seven to eight times less at 20°C than at 8, 12 or 16°C. Values of Gompertz parameters c (maximum percentage leaf area with sporulation), r (maximum rate of increase in percentage leaf area with sporulation) and l ₃₇ (days from inoculation to 37% of maximum sporulation), estimated by fitting the equation to the observed data, were linearly related to values predicted by inserting temperature and wetness duration treatment values into existing equations. The observed data were fitted better by logistic equations than by Gompertz equations (which overestimated at low temperatures). For both ascospore and conidial inoculum, the latent period derived from the logistic equation (days from inoculation to 50% of maximum sporulation, l ₅₀) of P. brassicae was generally shortest at 16°C, and increased as temperature increased to 20°C or decreased to 8°C. Minimum numbers of spores needed to produce sporulation on leaves were ≈25 ascospores per leaf and ≈700 conidia per leaf, at 16°C after 48 h leaf wetness duration.     

Leaf, floret and seed infection of wheat by Pyrenophora semeniperda

Infection processes of Pyrenophora semeniperda on seedling and adult wheat leaves and wheat ears were investigated. Almost 100% germination of conidia occurred on seedling leaves, compared with 20–30% on adult leaves. Appressoria formed over the anticlinal epidermal cell walls and haloes always accompanied infection. Sometimes papillae formed within the leaves as a resistance mechanism. Infection hyphae ramified through the intercellular spaces of the mesophyll resulting in cellular disruption. The infection processes on floral tissues were similar to those observed on leaves; however, no infection occurred on anther, stigmatic or stylar tissues. Infection of ovarian tissue occurred both with and without appressoria formation. Hyphae grew mainly in the epidermal layers and appeared unable to breach the integumental layer as no growth was observed in endosperm or embryo tissues. The optimum dew period temperature for conidial germination was 23·6°C, compared with 19·9°C for lesion development, 20·4°C for the production of infection structures on seedling leaves and 23·7°C for floret infection. Leaf disease development occurred in a logistic manner in response to dew period, with maximum infection observed after 21 h compared with > 48 h in seeds. An initial dark phase during the dew period was necessary for infection and temperature after the dew period had an effect, with significantly more numerous and larger lesions being formed at 15°C compared with 30°C. Seedling leaves were found to be more susceptible than older leaves, under both field and controlled environment conditions. Infection of wheat seeds following inoculation of ears, or after harvest burial of inoculated disease-free seeds, was demonstrated. In the latter, 3-week-old seedlings were slightly stunted, whereas older plants were unaffected. The apparent unimportance of this plant pathogen as a cause of leaf disease in relation to its poor adaptation to dew periods and dew period temperature is discussed, along with the importance of its seed borne characteristics.     

Resistance to Leveillula taurica in the genus Capsicum

One hundred and sixty-two Capsicum genotypes were evaluated for powdery mildew (Leveillula taurica) resistance, following inoculations with a suspension of 5 × 10⁴ conidia mL⁻¹ on 10-leaved to 12-leaved plants. Genotypes were graded into five resistance classes, based on the areas under the disease progress curves calculated from disease incidence (percentage infected leaves per plant) and severity (total number of colonies per plant). Results revealed a continuum from resistance to susceptibility, with the majority (70%) of C. annuum materials being classified as moderately to highly susceptible to L. taurica. Conversely, C. baccatum, C. chinense and C. frutescens were most often resistant, indicating that resistance to L. taurica among Capsicum species is found mainly outside the C. annuum taxon. Nevertheless, some resistant C. annuum material was identified that may be useful for resistance breeding. Eight genotypes were identified as immune to the pathogen: H-V-12 and 4638 (previously reported), and CNPH 36, 38, 50, 52, 279 and 288. Only H-V-12 and 4638 are C. annuum, while all others belong to the C. baccatum taxon. Latent period of disease on a set of commercial sweet pepper genotypes varied, indicating diverse levels of polygenic resistance. The latent period progressively reduced with plant maturity, from 14·3 days in plants at the mid-vegetative stage to 8·6 days in plants at the fruiting stage. Young plants of all commercial genotypes tested at the early vegetative stage were immune, irrespective of the reaction of the genotype at later stages, demonstrating widespread juvenile resistance to L. taurica in the Capsicum germplasm. Inoculation of plants of different botanical taxa with a local isolate indicated a wide host range. Some hosts, including tomato (Lycopersicon esculentum), artichoke (Cynara scolymus) and poinsettia (Euphorbia pulcherrima), produced large amounts of secondary inoculum. Other hosts included okra (Abelmoschus esculentus), eggplant (Solanum melongena), cucumber (Cucumis sativus), Solanum gilo, Chenopodium ambrosioides and Nicandra physaloides.     

华北地区夏玉米田马唐治理的生态经济杀除阈期研究

作者于1992～1994年研究夏玉米田马唐(Digitaria sanguinalis L.)治理的生态经济阈期,借助计算机进行数学模拟,建立夏玉米的相对产量与马唐的相对干扰生长时间、相对出苗时间的函数关系。苗后马唐干扰生长的相对时间即相对天数(Xu)与夏玉米相对产量(Yu)的关系式为: Yu=101.5/{1.0 0.01756EXP[—(—0.0876Xu 0.0004888Xu~2)]}…………(1)苗后马唐出苗的相对时间与玉米相对产量的关系式为: Yd=100.73/{1.0 0.96EXP[—(0.06346Xd-0.00006859Xd~2)]}……………(2) 根据生态经济杀除阈期的定义和(1)、(2)两公式计算可知:夏玉米田马唐防除的生态经济杀除阈期的始期应从夏玉米苗后生育期总天数的11.8％开始,结束于夏玉米苗后生育期总天数的53.9％。例如华北地区夏玉米全生育期总天数一般是95天,夏玉米苗后生育期总天数(T)约为88天,故夏玉米田马唐防除的生态经济杀除阈期约在夏玉米苗后10.6—47.5天之间。