生态环境学报
生態環境學報
생태배경학보
ECOLOGY AND ENVIRONMENT
2013年
3期
428-431
,共4页
水稻%小气候%CO2%光合
水稻%小氣候%CO2%光閤
수도%소기후%CO2%광합
rice%microclimate%CO2%photosynthesis
在中科院桃源农业生态试验站,选择了3个不同类型水稻品种(常规稻、一般杂交稻和超级杂交稻)为材料,利用稻田中部(距稻田边界6 m)和近边界(距稻田边界1 m)小气候的差异,研究了田间小气候对水稻产量和生物量的影响.稻田中部与近边界相比,在光合盛期(10:00-14:00),CO2含量低10~15μmol·mol-1,日平均温度低0.081℃,日平均相对湿度高10%.近边界水稻产量和生物量均显著高于稻田中部.稻田中部和近边界0.081℃的温度差异对光合速率的影响微小.稻田中部较高的相对湿度有利于缓解光合“午休”,促进光合作用.因此,温度和湿度差异均不是近边界水稻产量和生物量均显著高于稻田中部的原因.通过Li-6400光合仪测定发现水稻叶片光合速率与250~400μmol·mol-1的CO2含量内成线性正相关.在1200μmol·m-2·s-1光强下,如果 CO2含量增加10~15μmol·mol-1,水稻光合速率将增加0.6523~0.9785μmol·m-2·s-1.所以 CO2含量差异是近边界产量和生物量高于稻田中部的主要原因.最后建议通过一些栽培措施,改善群体通风状况,增加冠层内CO2含量,从而增加水稻产量和生物量.
在中科院桃源農業生態試驗站,選擇瞭3箇不同類型水稻品種(常規稻、一般雜交稻和超級雜交稻)為材料,利用稻田中部(距稻田邊界6 m)和近邊界(距稻田邊界1 m)小氣候的差異,研究瞭田間小氣候對水稻產量和生物量的影響.稻田中部與近邊界相比,在光閤盛期(10:00-14:00),CO2含量低10~15μmol·mol-1,日平均溫度低0.081℃,日平均相對濕度高10%.近邊界水稻產量和生物量均顯著高于稻田中部.稻田中部和近邊界0.081℃的溫度差異對光閤速率的影響微小.稻田中部較高的相對濕度有利于緩解光閤“午休”,促進光閤作用.因此,溫度和濕度差異均不是近邊界水稻產量和生物量均顯著高于稻田中部的原因.通過Li-6400光閤儀測定髮現水稻葉片光閤速率與250~400μmol·mol-1的CO2含量內成線性正相關.在1200μmol·m-2·s-1光彊下,如果 CO2含量增加10~15μmol·mol-1,水稻光閤速率將增加0.6523~0.9785μmol·m-2·s-1.所以 CO2含量差異是近邊界產量和生物量高于稻田中部的主要原因.最後建議通過一些栽培措施,改善群體通風狀況,增加冠層內CO2含量,從而增加水稻產量和生物量.
재중과원도원농업생태시험참,선택료3개불동류형수도품충(상규도、일반잡교도화초급잡교도)위재료,이용도전중부(거도전변계6 m)화근변계(거도전변계1 m)소기후적차이,연구료전간소기후대수도산량화생물량적영향.도전중부여근변계상비,재광합성기(10:00-14:00),CO2함량저10~15μmol·mol-1,일평균온도저0.081℃,일평균상대습도고10%.근변계수도산량화생물량균현저고우도전중부.도전중부화근변계0.081℃적온도차이대광합속솔적영향미소.도전중부교고적상대습도유리우완해광합“오휴”,촉진광합작용.인차,온도화습도차이균불시근변계수도산량화생물량균현저고우도전중부적원인.통과Li-6400광합의측정발현수도협편광합속솔여250~400μmol·mol-1적CO2함량내성선성정상관.재1200μmol·m-2·s-1광강하,여과 CO2함량증가10~15μmol·mol-1,수도광합속솔장증가0.6523~0.9785μmol·m-2·s-1.소이 CO2함량차이시근변계산량화생물량고우도전중부적주요원인.최후건의통과일사재배조시,개선군체통풍상황,증가관층내CO2함량,종이증가수도산량화생물량.
Based on the microclimate difference between central-field (6 meters from field boundary ) and near-boundary area (1 meter from field boundary), we analyzed the effect of field microclimate on the rice yield and biomass in Taoyuan Station of Agro-ecology Research, Chinese Academy of Science. We chose 3 rice varieties including conventional, hybrid and super hybrid rice. In central-field, compared with those in near-boundary area, CO2 content was 10~15μmol·mol-1 lower during high photosynthetic rate duration (10:00-14:00), daily average temperature was 0.081 ℃ lower, and daily average relative humidity was 10% higher. Both rice yield and biomass production in near-boundary area were significantly higher than those in central-field. The temperature difference of 0.081 ℃ had little effect on the photosynthetic rate. Higher relative humidity in central-field contributes to photosynthesis for reducing the midday depression of photosynthesis. So the temperature and relative humidity differences were not the reason for higher yield and biomass in near-boundary area. Leaf photosynthetic rate under different CO2 content was determined by Li-6400 portable photosynthesis system. There was a linear positive correlation between photosynthetic rate and CO2 content within 250~400 μmol·mol-1. Under 1 200 μmol·m-2·s-1 photosynthetic photon flux density, If CO2 content increased 10~15μmol·mol-1, photosynthetic rate would increase 0.652 3~0.978 5 μmol·m-2·s-1. Therefore, CO2 content difference was the main reason that led to higher yield and biomass production in near-boundary area than those in central-field. Some cultivation measures should be taken to better air diffusion, improve CO2 content in canopy, thus to increase rice production.