大豆,小豆,菜豆の生産生態に関する比較作物学的研究 (7) : エネルギー吸収量ならびにその乾物生産効率からみた生産力の作物間差異

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  • 大豆,小豆,菜豆の生産生態に関する比較作物学的研究 VII  エネルギー吸収量ならびにその乾物生産効率からみた生産力の作物間差異
  • Comparative Studies on Dry Matter Production, Plant Type and Productivity in Soybean, Azuki Bean and Kidney Bean : VII. An analysis of the productivity among the three crops on the basis of radiation absorption and its efficiency for dry matter accumulation
  • ダイズ アズキ サイトウ ノ セイサン セイタイ ニ カンスル ヒカク サクモ

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The differences of productivity among the three crops were analyzed in terms of radiation absorption and its efficiency for dry matter accumulation, using the data obtained in the dry matter production-population density experiments reported previously12, 13, 14). In this experiment, photosynthetically-active radiation (PAR) intercepted by plant canopy (ΔPAR) during the experimental period (t2-t1) was calculated as ΔPAR=Σ^^(<SUB)2</SUB>>__(i=t<SUB)1</SUB>>0.444·Si(1-expKs.LAIi) where 0.444 is the proportion of full spectrum radiation in the range 400 to 700 nm; Si is daily solar radiation; Ks is light-interception coefficient; LAIi is daily value of leaf area index calculated assuming that LAI increased exponentially from t1 to t2. Light-interception coefficient was given by I/I0=exp-Ks.LAI where I0 and I are the light intensities at the top and bottom of canopy, respectively, and the Ks value of each variety was estimated from the data measured three times for five population densities during the middle period of the growing season. The efficiency of dry matter accumulation per unit PAR intercepted (EPAR, dry weight mg/kcal) during the experimental and/or full growing period was defined as EPAR=ΔW/ΔPAR where ΔW is dry matter production and ΔPAR is the amount of PAR intercepted. EPAR also could be described as EPAR=NAR/(ΔPAR/(LAI)^^-·Δt) [(LAI)^^-=LAI2-LAI1/ln (LAI2/LAI1)] where NAR is net assimilation rate; LAI is mean leaf area index; Δt is number of days between t1 and t2; LAI1 and LAI2 are leaf area indices at times t1 and t2, respectively. The main results obtained are summarized as follows: 1. The maximum dry matter production for azuki bean and kidney bean was about 50-60%, on average, of that for soybean (Table 1). The maximum values for CGR, LAI and EPAR during growing season were higher in soybean (Table 2), indicating highly positive correlations with the maximum dry matter production (r≥0.898**). 2. When plotted disregarding crops, varieties and densities, dry matter production hag significantly positive correlations with ΔPAR and EPAR, while it was related positively only with LAD, and negatively with NAR. The regression of dry matter production on ΔPAR differed between two groups, one group's values of EPAR were lower and the other higher than about 9 mg/kcal (Fig. 1). In addition, a simple correlation coefficient between ΔPAR and EPAR was not significant, but a partial correlation between them was highly negative (Table 3). 3. The differences in total and pod+seed dry weight produced during grain filling period were in the same order as that exhibited in thc maximum dry matter production (Table 4). During grain filling both total and pod+seed dry matter production increased curvilinearly with increase of ΔPAR, but linearly with EPAR. Takarashozu differed from this relation because it did not reach the LAI value required for 95% light interception except under the highest density (Fig. 2). 4. The very close regressions of CGR on EPAR were found among the stages with different mean solar radiation, disregarding crops, varieties and densities, for which LAIs are more than the value required for 90% light interception (Fig. 3 and Table 6). A close correlation was also found between CGRmax. calculated by WASTON's method and EPAR (density mean) (Fig. 5). 5. [the rest omitted]

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