农业工程学报
農業工程學報
농업공정학보
2014年
11期
216-224
,共9页
秦晓波%李玉娥%万运帆%廖育林%范美蓉%高清竹%刘硕%马欣
秦曉波%李玉娥%萬運帆%廖育林%範美蓉%高清竹%劉碩%馬訢
진효파%리옥아%만운범%료육림%범미용%고청죽%류석%마흔
温室气体%排放控制%秸秆%双季稻田%免耕%高茬还田%交互效应
溫室氣體%排放控製%秸稈%雙季稻田%免耕%高茬還田%交互效應
온실기체%배방공제%갈간%쌍계도전%면경%고치환전%교호효응
greenhouse gases%emission control%straw%double rice field%no-till%high stubble%interaction effect
稻田温室气体(甲烷和氧化亚氮)排放强度受多种田间管理的影响,以往对各种措施间的交互效应研究较少。为此,该研究利用改进的静态箱-气相色谱法进行了连续4个生长季的湖南典型双季稻田温室气体排放强度观测,旨在分析耕作和稻草还田2种措施的交互效应并探寻多措施联合减缓温室气体排放强度的途径。试验设4个处理:翻耕(CWS,conventional tillage without straw residue)、免耕(NWS,no till without straw residue)、免耕高茬还田(HN,no till with high stubble straw residue)和翻耕高茬还田(HC,conventional tillage with high stubble straw residue)。结果表明,耕作和稻草还田2种措施对稻田甲烷排放有显著的交互效应(P<0.05),但对氧化亚氮交互效应不显著。2种措施对稻田温室气体排放强度的影响有明显的季节和年际变异。多生长季平均而言,各处理甲烷排放顺序为HC>HN>CWS>NWS(HC显著高于HN,HN和CWS差异不显著),水稻产量顺序为CWS>HN>HC>NWS(HN和CWS差异不显著),而温室气体排放强度(greenhouse gas intensity)顺序为HC>CWS>HN>NWS(HN显著低于HC和CWS,P<0.05)。可见,“免耕高茬还田”模式能抵消翻耕处理的高温室气体排放,并能比 NWS 处理提高水稻产量,显著减缓双季稻田温室气体排放强度。在保护性耕作和农田碳库提升的需求下,该模式应被予以高度重视。该研究可为中国双季稻主产区温室气体排放强度减缓措施的选择提供科学支撑。
稻田溫室氣體(甲烷和氧化亞氮)排放彊度受多種田間管理的影響,以往對各種措施間的交互效應研究較少。為此,該研究利用改進的靜態箱-氣相色譜法進行瞭連續4箇生長季的湖南典型雙季稻田溫室氣體排放彊度觀測,旨在分析耕作和稻草還田2種措施的交互效應併探尋多措施聯閤減緩溫室氣體排放彊度的途徑。試驗設4箇處理:翻耕(CWS,conventional tillage without straw residue)、免耕(NWS,no till without straw residue)、免耕高茬還田(HN,no till with high stubble straw residue)和翻耕高茬還田(HC,conventional tillage with high stubble straw residue)。結果錶明,耕作和稻草還田2種措施對稻田甲烷排放有顯著的交互效應(P<0.05),但對氧化亞氮交互效應不顯著。2種措施對稻田溫室氣體排放彊度的影響有明顯的季節和年際變異。多生長季平均而言,各處理甲烷排放順序為HC>HN>CWS>NWS(HC顯著高于HN,HN和CWS差異不顯著),水稻產量順序為CWS>HN>HC>NWS(HN和CWS差異不顯著),而溫室氣體排放彊度(greenhouse gas intensity)順序為HC>CWS>HN>NWS(HN顯著低于HC和CWS,P<0.05)。可見,“免耕高茬還田”模式能牴消翻耕處理的高溫室氣體排放,併能比 NWS 處理提高水稻產量,顯著減緩雙季稻田溫室氣體排放彊度。在保護性耕作和農田碳庫提升的需求下,該模式應被予以高度重視。該研究可為中國雙季稻主產區溫室氣體排放彊度減緩措施的選擇提供科學支撐。
도전온실기체(갑완화양화아담)배방강도수다충전간관리적영향,이왕대각충조시간적교호효응연구교소。위차,해연구이용개진적정태상-기상색보법진행료련속4개생장계적호남전형쌍계도전온실기체배방강도관측,지재분석경작화도초환전2충조시적교호효응병탐심다조시연합감완온실기체배방강도적도경。시험설4개처리:번경(CWS,conventional tillage without straw residue)、면경(NWS,no till without straw residue)、면경고치환전(HN,no till with high stubble straw residue)화번경고치환전(HC,conventional tillage with high stubble straw residue)。결과표명,경작화도초환전2충조시대도전갑완배방유현저적교호효응(P<0.05),단대양화아담교호효응불현저。2충조시대도전온실기체배방강도적영향유명현적계절화년제변이。다생장계평균이언,각처리갑완배방순서위HC>HN>CWS>NWS(HC현저고우HN,HN화CWS차이불현저),수도산량순서위CWS>HN>HC>NWS(HN화CWS차이불현저),이온실기체배방강도(greenhouse gas intensity)순서위HC>CWS>HN>NWS(HN현저저우HC화CWS,P<0.05)。가견,“면경고치환전”모식능저소번경처리적고온실기체배방,병능비 NWS 처리제고수도산량,현저감완쌍계도전온실기체배방강도。재보호성경작화농전탄고제승적수구하,해모식응피여이고도중시。해연구가위중국쌍계도주산구온실기체배방강도감완조시적선택제공과학지탱。
Greenhouse gas intensity (GHGI) (methane and nitrous oxide) of double rice paddy was controlled by various field managements, tillage, and rice straw return to the field. On one hand, the choice of the tillage mode affects the gas permeability of soil during the crop-growing stage. On the other, the incorporation of rice straw can be a critical way to amend the loss of soil carbon. Both of the two practices have their advantages and disadvantages on rice production and environmental effects. In fact, no tillage causes less methane emissions from double rice fields than the field with conventional tillage. Nevertheless, rice straw return to the field increases tremendous methane production and emission of organic carbon. In spite of its promotion on rice productivity and sequestration of soil organic carbon pool, this practice is still under discussion .Therefore, multi-management mode should be considered simultaneously when regional or national policy is made to reduce GHGI from agriculture. To date, the study of the interaction effect of tillage and the rice residue return on GHGI from double rice fields is lacking. Most of the previous studies focused only on one field management and its influence mechanism. Consequently, we conducted a measurement for 4 rice growing seasons on GHGI of a double rice field in Hunan, China to investigate the interaction effect of tillage and rice straw return on both the social-economical and environmental benefits. The improved static chamber-GC (gas chromatography) method was used to monitor the greenhouse gas emissions from the rice paddy. Major improvements made on the chamber include the adjustable sampling tube and the pores in the base. The former was designed to change with the growth of the rice plant and the latter favored the communication of soil water between the inside and outside of the base. Both of them enhanced the accuracy of the field measurement. Four field practices were included in this research, viz. CWS (Conventional tillage, without straw residue return), NWS (No till, without straw residue return), HN (High stubble residue retain, no till), and HC (High stubble residue retain, conventional tillage). Results showed that there is a significant interaction effect of tillage and rice residue return on methane emissions (P<0.05) instead of nitrous oxide emissions from the double rice field. The interaction effect has pronounced seasonal and inter-annual variation. By the seasonal average value, the sequence of methane flux of each treatment is the following: HC>HN>CWS>NWS (HC significantly greater than HN while no significant difference between HN and CWS). Similarly, the amount of rice grain yield of each treatment of the 4 seasons is the following: CWS>HN>HC>NWS (no significant difference between HN and CWS). For the GHGI, the following order is disclosed: HC>CWS>HN>NWS (HN less than HC and CWS significantly,P<0.05). This indicated that compared to CWS, “no-till plus high stubble residue (HN)” offset the stimulations of conventional tillage on methane production and emission while simultaneously promoting the rice grain yield. Thus the multi-management mode mitigated the GHGI of the double rice field significantly. Under the requirement of organic tillage and the sequestration of agricultural soil carbon pool, HN mode should be considered of great importance. This study can provide scientific support on the measurement choice of greenhouse gases effect reduction from the major rice production region of China.
