CAJ | 학술논문

为研究水稻茎蘖增长阶段光温要素对茎蘖动态的影响，并验证现有茎蘖动态模拟模型中的光温影响方程，以籼型两系杂交稻陵两优268和两优培九为试验品种，进行了为期2年每年7个播期的大田试验。首先，采用Richards方程对茎蘖观测数据进行拟合，获取茎蘖增长动态的特征参数。然后，分析特征参数与茎蘖增长期内平均光温要素和气候要素的关系，并在此基础上，以光温组合因子为自变量，分别构建2个品种茎蘖增长速率和分蘖率的光温组合影响方程，将获取的方程替换水稻群体茎蘖动态模拟模型中的光温影响方程。最后，验证和比较替换前后模型的模拟结果及与实测茎蘖动态的误差。结果显示，受光温要素的共同作用，平均茎蘖增长速率和最大茎蘖密度均与光温要素显著正相关，表明光温要素不仅影响茎蘖增长速率，也影响实际最大群体茎蘖密度，这在构建的光温组合影响方程中得到了较好的反映。较现有模型，替换后模型在茎蘖增长动态上的模拟误差总体减小，模拟的茎蘖增长速率和最大茎蘖密度与实际吻合较好，但在部分验证数据上仍存在较大误差。然而，本文提出的验证和改进光温影响方程的方法，对了解光温影响机制和完善群体茎蘖动态模拟模型具有一定的参考价值。
위연구수도경얼증장계단광온요소대경얼동태적영향，병험증현유경얼동태모의모형중적광온영향방정，이선형량계잡교도릉량우268화량우배구위시험품충，진행료위기2년매년7개파기적대전시험。수선，채용Richards방정대경얼관측수거진행의합，획취경얼증장동태적특정삼수。연후，분석특정삼수여경얼증장기내평균광온요소화기후요소적관계，병재차기출상，이광온조합인자위자변량，분별구건2개품충경얼증장속솔화분얼솔적광온조합영향방정，장획취적방정체환수도군체경얼동태모의모형중적광온영향방정。최후，험증화비교체환전후모형적모의결과급여실측경얼동태적오차。결과현시，수광온요소적공동작용，평균경얼증장속솔화최대경얼밀도균여광온요소현저정상관，표명광온요소불부영향경얼증장속솔，야영향실제최대군체경얼밀도，저재구건적광온조합영향방정중득도료교호적반영。교현유모형，체환후모형재경얼증장동태상적모의오차총체감소，모의적경얼증장속솔화최대경얼밀도여실제문합교호，단재부분험증수거상잉존재교대오차。연이，본문제출적험증화개진광온영향방정적방법，대료해광온영향궤제화완선군체경얼동태모의모형구유일정적삼고개치。
In order to investigate the effects of light and temperature on rice tillering dynamics in tillering stage and validate the light and temperature effect equation in current dynamic tillering models. We performed two-year field-seeding experiments (2012–2013) using two indica two-line hybrid rice cultivars, Lingliangyou 268 and Liangyoupeijiu. And we collected the obser-vation data in tillering. To fit Richards equation for retrieving characteristic parameters related to the maximum tiller density, ave-rage growth rate of tillers, and duration of the growing period. Moreover, we analyzed the relationships between all these charac-teristic parameters and average data of light, temperature and climatic variables during the growing period for each rice cultivar. Based on the relationships we established co-effect equations for the growth rate of tillers and maximum tiller density as a func-tion of co-effect of light and temperature. The new co-effect functions for each cultivar were substituted for the effect functions of light and temperature in a widely used dynamic tillering model to simulate the dynamic tillering in tillering stage. Finally, valida-tion and comparison were carried out for the models applied observation data in tillers period. The result showed that the light and temperature affected crop growth in tillering period. The growth rate of tillers and the actual maximum tiller density positively correlated with the two meteorological factors significantly. Compared with current dynamic tillering model, the model with the established co-effects of light and temperature functions decreased the error significantly in simulating the growth dynamics of tillers. The simulated rice tillering was well consistent with the observed in both growth rate and maximum tiller density for both rice cultivars. However, the discrepancy could also be found in some seeding periods and validation samples, which may be caused by rice adaptability to different light and temperature environments. In conclusion, the validation and improvement of the light and temperature co-effect functions put forward in this study can be used further for understanding the effects of light and temperature factors on rice tillering and improving dynamic tillering models in the future.