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1.
极端干旱事件频发对中亚棉花生产具有重要影响。本文利用乌兹别克斯坦赞格阿塔实验站棉花大田试验数据评估了APSIM-Cotton模型的适用性,根据CMIP6气候模式模拟的SSP1-2.6、SSP3-7.0和SSP5-8.5等3种共享社会经济路径下的气候变化数据集,分析了2021—2090年SPEI-3干旱指数的变化特征,进而利用APSIM-Cotton模型模拟了考虑CO2肥效作用的气象干旱对棉花产量的影响。结果表明:APSIM-Cotton模型能够准确模拟乌兹别克斯坦塔什干地区的生育期和产量变化趋势;未来塔什干地区呈现温度明显升高、干旱发生频率明显增加的特征;气象干旱将导致棉花产量下降,SSP1-2.6、SSP3-7.0和SSP5-8.5等3种排放情景下,严重气象干旱导致2021—2050年棉花产量较1961—1990年分别下降28.0%、29.6%和32.1%,2061—2090年棉花分别减产31.5%、33.1%和35.7%,在SSP3-7.0和SSP5-8.5情景下,极端气象干旱导致2061—2090年棉花产量分别下降41.3%和54.2%;CO2浓度升高可提高棉花产量,贡献率为14.9%~25.0%,但浓度达到750 µmol/mol以上时,棉花增产幅度将不再持续增加。 相似文献
2.
Population,urbanization and economic scenarios over the Belt and Road region under the Shared Socioeconomic Pathways 总被引:1,自引:0,他引:1
Jing Cheng Tao Hui Jiang Tong Wang Yanjun Zhai Jianqing Cao Lige Su Buda 《地理学报(英文版)》2020,30(1):68-84
The countries throughout the Belt and Road region account for more than 60% of the world's population and half of the global economy. Future changes in this area will have significant influences on the global economic growth, industrial structure and resource allocation. In this study, the proportion of the urban population to the total population and the gross domestic product were used to represent the levels of urbanization and economic development, respectively. The population, urbanization and economic levels of the Belt and Road countries for 2020–2050 were projected under the framework of the IPCC's shared socioeconomic pathways(SSPs), and the following conclusions are drawn.(1) The population, urbanization and economic levels in the Belt and Road region will likely increase under all five pathways. The population will increase by 2%–8%/10 a during 2020–2050 and reach 5.0–6.0 billion in 2050. Meanwhile, the urbanization rate will increase by 1.4%–7.5%/10 a and reach 49%–75%. The GDP will increase by 17%–34%/10 a and reach 134–243 trillion USD.(2) Large differences will appear under different scenarios. The SSP1 and SSP5 pathways demonstrate relatively high urbanization and economic levels, but the population size is comparatively smaller; SSP3 shows the opposite trend. Meanwhile, the economy develops slowly under SSP4, but it has a relatively high urbanization level, while SSP2 exhibits an intermediate trend.(3) In 2050, the population will increase relative to 2016 in most countries, and population size in the fastest growing country in Central Asia and the Middle East countries will be more than double. Urbanization will develop rapidly in South Asia, West Asia and Central Asia, and will increase by more than 150% in the fastest growing countries. The economy will grow fastest in South Asia, Southeast Asia and West Asia, and increase by more than 10 times in some counties with rapid economic development. 相似文献
3.
未来情景下中国高温的人口暴露度变化及影响因素研究 总被引:3,自引:0,他引:3
基于RCP 8.5气候情景下21个高分辨率全球气候模式的日最高气温数据和A2r社会经济发展情景下的人口数据,以高温日数和人口数量的乘积构建高温的人口暴露度指标,采用多个气候模式集合平均的方法从网格单元尺度分析未来不同时段中国高温和强危害性高温的人口暴露度变化,并从全国和气象地理分区两种空间尺度研究人口暴露度变化的影响因素。研究表明:未来情景下,中国高温的人口暴露度明显增加,2021-2040年、2041-2060年、2061-2080年和2081-2100年相比基准时段1981-2010年分别增加了1.3、2.0、3.6和5.9倍,强危害性高温的人口暴露度增加更为显著,相比基准时段分别增加了2.0、8.3、24.2和82.7倍。高温的人口暴露度在华北、黄淮、华南、江南、江淮、西南和江汉地区增加较为明显,其中华北、黄淮、华南和江南最为显著;强危害性高温的人口暴露度在华北、黄淮、江南、江淮、西南和江汉等区域增加较为明显,其中华北、黄淮、江南和江淮最为显著;未来情景下人口暴露度的变化主要受气候因子的影响,其次受人口和气候因子的共同影响,单独人口因子的影响很小。全国尺度上,气候因子对未来不同时段人口暴露度变化的影响逐渐减弱,贡献率由70.0%左右逐渐减至60.0%左右。人口和气候因子的共同作用逐渐增强,贡献率由20.0%左右逐渐增至40.0%左右。 相似文献
4.
如何实现自然与人文双重驱动下的特大城市群地区土地覆被变化的情景模拟,不仅是当前土地覆被变化研究领域的热点问题,也是城镇化可持续发展研究的核心主题之一。本文在对现有土地覆被变化情景模型缺陷进行分析和修正的基础上,构建了自然要素与人文要素耦合驱动的土地覆被情景曲面建模(SSMLC)方法。结合IPCC 2020年发布的共享社会经济路径(SSPs)与典型浓度路径(RCPs)组合的CMIP6 SSP1-2.6、SSP2-4.5和SSP5-8.5的气候情景数据,以及人口、GDP、交通、政策等人文参数,分别实现了SSP1-2.6、SSP2-4.5和SSP5-8.5情景下的京津冀土地覆被变化的情景模拟。模拟结果表明:SSMLC对京津冀地区土地覆被变化模拟的总体精度为93.52%;京津冀地区的土地覆被在2020—2040时段内的变化强度最高(3.12%/10a),2040年以后的变化强度将逐渐减缓;在2020—2100年间,建设用地增加速度最快,增加率为5.07%/10a。湿地的减少速度最快,减少率为3.10%/10a。2020—2100时段内的京津冀土地覆被在SSP5-8.5情景下的变化强度整体高于在SSP1-2.6和SSP2-4.5情景下的变化强度;GDP、人口、交通和政策等人文因子对京津冀地区耕地、建设用地、湿地和水体的影响强度高于对其他土地覆被类型的影响强度。研究结果证实了SSMLC模型能够有效模拟和定量刻画京津冀地区土地覆被空间分布格局在未来不同情景的时空变化趋势和强度,模拟结果可为京津冀协同一体化的国土空间优化配置与规划、以及生态环境建设提供辅助依据和数据支撑。 相似文献
5.
In this study, the spatial distribution and changing trends of agricultural heat and precipitation resources in Northeast China were analyzed to explore the impacts of future climate changes on agroclimatic resources in the region. This research is based on the output meteorological data from the regional climate model system for Northeast China from 2005 to 2099, under low and high radiative forcing scenarios RCP4.5 (low emission scenario) and RCP8.5 (high emission scenario) as proposed in IPCC AR5. Model outputs under the baseline scenario, and RCP4.5 and RCP8.5 scenarios were assimilated with observed data from 91 meteorological stations in Northeast China from 1961 to 2010 to perform the analyses. The results indicate that: (1) The spatial distribution of temperature decreases from south to north, and the temperature is projected to increase in all regions, especially under a high emission scenario. The average annual temperature under the baseline scenario is 7.70°C, and the average annual temperatures under RCP4.5 and RCP8.5 are 9.67°C and 10.66°C, respectively. Other agricultural heat resources change in accordance with temperature changes. Specifically, the first day with temperatures ≥10°C arrives 3 to 4 d earlier, the first frost date is delayed by 2 to 6 d, and the duration of the growing season is lengthened by 4 to 10 d, and the accumulated temperature increases by 400 to 700°C·d. Water resources exhibit slight but not significant increases. (2) While the historical temperature increase rate is 0.35°C/10a, the rate of future temperature increase is the highest under the RCP8.5 scenario at 0.48°C/10a, compared to 0.19°C/10a under the RCP4.5 scenario. In the later part of this century, the trend of temperature increase is significantly faster under the RCP8.5 scenario than under the RCP4.5 scenario, with faster increases in the northern region. Other agricultural heat resources exhibit similar trends as temperature, but with different specific spatial distributions. Precipitation in the growing season generally shows an increasing but insignificant trend in the future, with relatively large yearly fluctuations. Precipitation in the eastern region is projected to increase, while a decrease is expected in the western region. The future climate in Northeast China will change towards higher temperature and humidity. The heat resource will increase globally, however its disparity with the change in precipitation may negatively affect agricultural activities. 相似文献
6.
气候是影响植被类型和分布的关键因素,植被类型和分布格局也能反映气候的地域差异。随着气候变暖,全球气温和降水格局都将发生变化,植被类型和分布格局也将随之改变。而植物对气候变化的响应存在一定的滞后性,因此仅用气候指标研究亚热带北界及其移动具有一定的局限性。以青冈(Cyclobalanopsis glauca (Thunberg) Oersted)为研究对象,应用最大熵模型(Maxent),研究了其对气候变化的响应并探讨了气候变化情景下青冈分布格局变化对中国亚热带北界移动的指示意义。结果表明:影响青冈分布的主导环境因子为年降水量、最冷季降水量、气温年变化范围和最冷月最低气温;随着气候变暖,青冈分布北界将向北移动,其分布质心亦向西北移动,预示着在气候变暖的背景下,到21世纪中叶中国亚热带北界将向北移动约1个纬度。 相似文献
7.
Projected changes in population exposure to extreme heat in China under a RCP8.5 scenario 总被引:1,自引:0,他引:1
Overall population exposure is measured by multiplying the annual average number of extremely hot days by the number of people exposed to the resultant heat. Extreme heat is also subdivided into high temperature (HT) and extremely high temperature (EHT) in cases where daily maximum temperature exceeds 35°C and 40°C, respectively. Chinese population exposure to HT and EHT over four periods in the future (i.e., 2021–2040, 2041–2060, 2060–2081 and 2081–2100) were projected at the grid cell level in this study using daily maximum temperature based on an ensemble mean of 21 global climate models under the RCP8.5 scenario and with a population projection based on the A2r socio-economic scenario. The relative importance of population and climate as drivers of population exposure was evaluated at different spatial scales including national and meteorological geographical divisions. Results show that, compared with population exposure seen during 1981–2010, the base period, exposure to HT in China is likely to increase by 1.3, 2.0, 3.6, and 5.9 times, respectively, over the four periods, while concomitant exposure to EHT is likely to increase by 2.0, 8.3, 24.2, and 82.7 times, respectively. Data show that population exposure to HT is likely to increase significantly in Jianghuai region, Southwest China and Jianghan region, in particular in North China, Huanghuai region, South China and Jiangnan region. Population exposure to EHT is also likely to increase significantly in Southwest China and Jianghan region, especially in North China, Huanghuai, Jiangnan, and Jianghuai regions. Results reveal that climate is the most important factor driving the level of population exposure in Huanghuai, Jianghuai, Jianghan, and Jiangnan regions, as well as in South and Southwest China, followed by the interactive effect between population and climate. Data show that the climatic factor is also most significant at the national level, followed by the interactive effect between population and climate. The rate of contribution of climate to national-level projected changes in exposure is likely to decrease gradually from ca. 70% to ca. 60%, while the rate of contribution of concurrent changes in both population and climate is likely to increase gradually from ca. 20% to ca. 40% over the four future periods in this analysis. 相似文献
8.
CMIP3气候模式对北疆气候变化模拟评估及未来情景预估 总被引:3,自引:0,他引:3
利用北疆地区1961~2000年气温、降水观测数据和CMIP3(phase 3of the CoupledModel Inter-comparison Project)提供的20个海气耦合模式在该地区的模拟结果,评估了各气候模式对北疆地区降水、气温的模拟效果。结果表明:各气候模式对气温、降水模拟效果差异较大。从对气候平均态的模拟来看,有5个模式对降水的模拟相对较好,2个模式对气温的模拟相对较好;所有模式均能模拟出气温的年内变化特征,其中MPI_ECHAM5模式结果与观测数据结果最为接近;但各模式对降水的模拟效果均较差。在月尺度上,一些模式结果与降水观测数据呈负相关性,但对于月气温,大多数模式与其相关性较好,且各模式间月气温均方根误差变化幅度相对较小。综合来看,大部分气候模式在该地区模拟能力比中国东部地区要弱;气候模式的降水数据包括多模式集合数据还不适合用于未来北疆地区降水变化预估分析。最后,采用累计分布函数法(CDFS)仅对北疆地区2011~2050年时段的气温进行偏差校正与预估分析,结果表明未来40年北疆地区气温在三种排放情景下均呈上升趋势。 相似文献
9.
北海公园冰上运动是北京传统体育文化遗产的重要组成内容以及冬季休闲旅游的代表性符号,强化其气候变化影响与适应研究,对于应对全球变化的挑战、践行“大力发展冰雪经济”的指示具有重要意义。本文从多源文献中提取分析了其冰场多年启闭日期(间接指示冰层厚15 cm)的变化特征,并结合气温器测数据以及4种气候情景数据(SSP1-2.6、SSP2-4.5、SSP3-7.0和SSP5-8.5),利用留一交叉验证法探讨了不同温度指标和拟合方程的预测效果差异,进而对未来冰上运动季的变化、潜在影响与适应对策进行分析。结果表明:① 1989—2018年冰上运动季始日、末日和持续长度的均值分别为1月1日、2月5日和36 d,对应的趋势表现为不显著的推迟(1.00 d/10a)、提前(-0.77 d/10a)和延长(1.11 d/10a),时序变化可区分为1989—2000年、2001—2013年和2014—2018年3个阶段。② 冰上运动季始、末日分别对其日期前59 d的日最低温和前94 d的日最高温有较好响应,利用这两个指标和玻尔兹曼函数可更好预测冰上运动季变化。③ 2021—2099年冰上运动季始日、末日和持续长度的均值分别较1989—2018年晚1 d、早1 d和缩短2 d,3个指标变幅一致缩小,对应的0.14 d/10a、-0.21 d/10a和-0.34 d/10a的趋势均达到0.01的显著性水平。④ 未来79 a内冬季两大节庆中元旦冰上运动的适宜性要大于春节,其中春节的适宜性在4种气候情景下相差不大,而元旦的适宜性则在4种情景下有一定差别。⑤ 在相关预估结果上,BCC-CSM2-MR、CanESM-5和UKESM这3种区域气候模式并没有太大差异,而热岛效应影响尚待深入研究。⑥ 为了在气候变暖背景下促进体旅融合消费、保障冰上运动产业高质量发展,运营企业应采取强化游客安全保障、扩展旅游产品谱系、购买冰量保险等全方位主动适应措施,研究者应加强研究气候变化影响的复杂性、改进旅游流的预测效果,而管理部门应大力推动产业风险管理报告的编制,充分重视气候变化风险的动态评估。 相似文献
10.
三江源地区气候变化及其对径流的驱动分析(英文) 总被引:6,自引:3,他引:3
Based on the precipitation and temperature data of the 12 meteorological stations in the "Three-River Headwaters" region and the observed runoff data of Zhimenda in the headwater sub-region of the Yangtze River, Tangnaihai in the headwater sub-region of the Yellow River and Changdu in the headwater sub-region of the Lancang River during the period 1965-2004, this paper analyses the trends of precipitation, temperature, runoff depth and carries out significance tests by means of Mann-Kendall-Sneyers sequential trend test. Makkink model is applied to calculate the potential evaporation. The runoff model driven by precipitation and potential evaporation is developed and the influence on runoff by climate change is simulated under different scenarios. Results show that during the period 1965-2004 the temperature of the "Three-River Headwaters" region is increasing, the runoff of the three hydrological stations is decreasing and both of them had abrupt changes in 1994, while no significant trend changes happen to the precipitation. The runoff model suggests that the precipitation has a positive effect on the runoff depth, while the potential evaporation plays a negative role. The influence of the potential evaporation on the runoff depth of the Lancang River is found to be the significant in the three rivers; and that of the Yellow River is the least. The result of the scenarios analysis indicates that although the precipitation and the potential evaporation have positive and negative effects on runoff relatively, fluctuated characteristics of individual effect on the runoff depth in specific situations are represented. 相似文献
11.
三江源气候变化及其对径流的驱动分析 总被引:14,自引:3,他引:11
以1965-2004 年三江源地区12 个气象台站的降水和气温资料以及长江源区直门达、黄河源区唐乃亥和澜沧江源区昌都水文站的径流资料为基础,分析三江源地区的降水、气温和径流的变化趋势,并采用Mann-Kendall-Sneyers 方法进行趋势显著性检验;采用Makkink 公式计算三江源区12 个气象站点的潜在蒸发,建立三江源区降水和潜在蒸发对径流的驱动模型,并对气候变化(降水和气温的变化) 对径流的驱动进行情景分析。研究表明:1965-2004 年三江源区气温升高,径流减少,并且气温和径流都在1994 年发生突变,但降水的变化趋势不明显。降水和潜在蒸发对径流深的驱动模型表明三江源区降水对径流起正向的驱动作用,潜在蒸发对径流起负向的驱动作用,具体来说,澜沧江源区潜在蒸发对径流的驱动力最大,长江源区次之,黄河源区最小。借助驱动模型对三江源气候变化(降水和气温的变化) 对径流的影响进行情景分析,结果显示,降水和气温对径流的驱动在总体上虽然分别是正、负方向上的驱动,但在具体情景下其各自的驱动作用又呈现出波动的特征。 相似文献
12.
RCPs情景下未来青海高原气候变化趋势预估 总被引:2,自引:1,他引:1
利用 CMIP5(Coupled Model Intercomparison Project Phase 5)耦合模式结果对 RCPs(Representative Concentration Pathways)情景下的青海高原气温、降水变化趋势及极端气候事件2011-2100年演变特征进行了预估。结果表明:在21世纪,青海高原年平均气温显著升高,RCP2.6、RCP4.5 和 RCP8.5排放情景下增温速率分别为0.06 ℃/10a、0.24 ℃/10a和0.61 ℃/10a。年降水量将明显增加,幅度1.4~7.0 mm/10a。青海高原21世纪与气温、降水有关的事件都有趋于极端化的趋势,极端冷指标下降,极端暖指标均明显上升。极端降水频次增加,强度加重,且变化幅度与排放强度成正比。 相似文献
13.
东北地区未来气候变化对农业气候资源的影响 总被引:5,自引:1,他引:4
为探求未来气候变化对东北地区农业气候资源的影响,本文基于区域气候模式系统输出的东北地区IPCC AR5提出的低辐射和高辐射强迫RCP_4.5(低排放)、RCP_8.5(高排放)情景下2005-2099年气象资料,通过与东北地区1961-2010年91个气象站点观测资料同化,分析了历史资料(Baseline)、RCP_4.5、RCP_8.5情景下东北地区农业热量资源和降水资源空间分布及其变化趋势。结果表明:① 年均温度空间分布自南向北降低,未来各地区温度均有升高,RCP_8.5情景下升温更明显,Baseline情景年均温度为7.70 ℃,RCP_4.5和RCP_8.5年均温度分别为9.67 ℃、10.66 ℃;其他农业热量资源随温度变化一致,具体≥ 10 ℃初日提前3 d、4 d,初霜日推迟2 d、6 d,生长季日数延长4 d、10 d,积温增加400 ℃·d、700 ℃·d;水资源稍有增加,但不明显。② 历史增温速率为0.35 ℃/10a,未来增温速率最快为RCP_8.5情景0.48 ℃/10a,高于RCP_4.5的0.19 ℃/10a。21世纪后期,RCP_8.5增温趋势明显快于RCP_4.5,北部地区增温更加速。其他农业热量资源随温度变化趋势相一致,但具体空间分布有所不同。生长季降水总体呈增加趋势,但不显著,年际间变化较大;东部地区降水增加,西部减少。未来东北地区总体向暖湿方向发展,热量资源整体增加,但与降水的不匹配可能将会对农业生产造成不利的影响。 相似文献
14.
基于模式优选的21世纪中国气候变化情景集合预估 总被引:1,自引:1,他引:0
未来气候变化情景预估是制定气候变化应对和适应策略的科学基础。本文利用参与耦合模式比较计划第五阶段(CMIP5)的30个气候模式的模拟数据,通过评估各模式对历史气候变化的模拟能力,筛选出模拟区域气候变化的最优模式组合,进而建立偏最小二乘回归(PLS)集合预估模型,据此利用最优模式模拟结果预估区域温度和降水变化情景。通过与历史数据的对比,研究发现本文基于最优模式建立的PLS集合预估模型不仅优于传统的多模式集合平均,而且也优于利用全部模式建立的PLS集合预估模型,体现了模式优选过程的重要性。本文基于优选模式的PLS集合预估模型预估结果表明:① 21世纪各区域温度将持续上升,且冬半年升温速率总体大于夏半年,北方地区升温速率总体高于南方地区;RCP 4.5排放情景下温度上升先快后慢,转折点出现在21世纪中期,RCP 8.5排放情景下,呈持续增加趋势,至21世纪末的升温幅度约为RCP 4.5情景的2倍。② 21世纪各区降水变化均呈显著增加趋势,并表现出高排放情景大于低排放情景,少雨区大于多雨区的特征,但是降水增加过程伴有明显的年代际波动。对比发现,传统的等权重集合平均全部模式(EMC)方法预估的中国夏季变暖速率高于冬季,且降水基本呈线性增加,有悖于全球变暖的基本特征及中国降水具有鲜明的年代际变化特征的基本认识。因而,本文预估的温度和降水变化特征均更符合中国气候变化的基本规律。 相似文献
15.
气候变化情景下油茶生长的适宜性特征 总被引:1,自引:0,他引:1
基于气候情景数据与油茶标本,运用MaxEnt模型分析全新世中期、当代与未来阶段油茶生长的气候适宜性特征,将概率分布结果由不适宜到最适宜分为4个等级,分析了各时段空间分布变化与最适宜区北界变化、几何中心变化及位移情况。结果如下:1)MaxEnt模型的AUC值为0.848,评估结果达到“好”的标准,说明该模型可用;年降水量、最湿季降水量、最暖季平均温、温度季节性变化的标准差、最干月降水量、最湿季平均温和最冷季平均温等是7个主要环境因子。2)中国油茶主要适宜生长于长江以南、云贵高原以东,经纬度范围为30°N以南、107°E以东地区;适宜及以上等级占研究区面积的34.9%~61%;适宜性变化,空间上西南地区波动明显,面积上稳定和降低类占比较高。3)油茶最适宜区北界位于亚热带中部,不同年代、不同地区北界各异,长江中下游地区变化较小,而秦岭、渝、贵和桂等地变动较大,整体趋势为全新世中期至1980s向南推移,未来情景下2050s和2070s缓慢向北推移;几何中心在全新世中期时位于湖南郴州,至1980s时向东南方位移至广东韶关,至2050s时向东北位移至江西吉安,并相对稳定。4)基于气候情景数据和MaxEnt物种分布模型分析中国南方地区油茶气候适宜性时空分布与变化特征结果可靠。 相似文献
16.
气候变化对淮河流域水资源及极端洪水事件的影响 总被引:2,自引:0,他引:2
利用法国国家气象研究中心气候模型(Centre National de Recherches Météorologiques Climate Model, CNRM)典型代表性浓度路径(Representative Concentration Pathway, RCP)情景资料和可变下渗容量模型(Variable Infiltration Capacity Model,VIC),分析了淮河流域未来气温、降水、水资源及可能洪水的变化趋势。结果表明,淮河流域未来气温将持续升高,RCP2.6、RCP4.5和RCP8.5情景下未来2021~2050年较基准期(1961~1990年)升幅分别约为1.13℃、1.10℃和1.35℃;流域降水可能呈现略微增加趋势,3种排放情景下2021~2050年降水较基准期将分别增加5.81%、8.26%和6.94%;VIC模型在淮河流域具有较好的适用性,能较好地模拟淮河流域的水文过程,在率定期和检验期,模型对王家坝站和蚌埠站模拟的水量相对误差都在5%以内,日径流过程的Nash-Sutcliffe模型效率系数(NSE)在0.70以上,月径流过程的NSE达到0.85以上。气候变化将导致淮河流域水文循环强度增加,流域水资源总体将可能呈增加趋势,王家坝站和蚌埠站断面洪水事件的发生可能性将增大。 相似文献
17.
RCP8.5气候变化情景下21世纪印度粮食单产变化的多模式集合模拟 总被引:1,自引:0,他引:1
基于跨部门影响模型比较计划(ISI-MIP)中20种气候模式与作物模型组合的模拟结果,预估了RCP 8.5排放情景下21世纪印度小麦和水稻单产变化。研究发现:① 多模式集合模拟结果基本再现了印度小麦和水稻单产的空间差异;同时,再现了小麦和水稻单产对温度和降水变化的响应特征:与温度呈负相关,与降水呈正相关。② RCP 8.5情景下,水稻和小麦生长季温度和降水均呈增加趋势,小麦生长季的温度、降水增加幅度大于水稻。空间上,温度增加幅度自北向南逐渐减小,降水增幅则逐渐增加,并且小麦种植区升温幅度大于非种植区,降水增幅则少于非种植区,水稻种植区升温幅度小于非种植区,降水增幅则多于非种植区。③ RCP 8.5情景下,小麦和水稻单产均呈下降趋势,21世纪后半叶尤为明显。小麦单产的下降速度明显大于水稻,其中21世纪前半叶小麦和水稻单产下降速度约分别为1.3%/10a (P < 0.001)和0.7%/10a (P < 0.05),后半叶分别增至4.9%/10a (P < 0.001)和4.4%/10a (P < 0.001)。小麦和水稻单产变化存在明显的空间异质性,小麦单产的最大下降幅度出现在德干高原西南部,降幅约60%,水稻单产最大下降幅度出现在印度河平原北部,降幅约50%。这意味着未来气候变化情景下印度粮食供给将面临较大的挑战。 相似文献
18.
为了揭示陕北黄土高原红枣种植区水热资源变化特征,给当地红枣产业适应气候变化提供科学依据,利用陕北黄土高原红枣种植区8个气象站1971-2019年的气温、降水资料,及中等(RCP4.5)和高等(RCP8.5)排放气候情景下2021-2050年的气候变化预估数据,采用线性倾向估计、M-K检验、Morlet小波分析方法对气温、降水变化特征进行分析。结果显示:近49 a,红枣种植区年和生长季平均气温呈显著上升趋势,分别在1991年和1993年发生突变,存在44 a的周期变化。年和生长季降水量呈不显著增加趋势,存在31 a左右的周期变化,未发生突变。2021-2050年,RCP4.5、RCP8.5两种情景模式下,年和生长季平均气温呈上升趋势,RCP8.5排放情景下升温更显著,年平均气温在2027年发生了突变。两种排放情景下,年和生长季平均气温存在31 a左右的周期变化。年和生长季降水量在RCP4.5排放情景下呈不显著减少趋势,在RCP8.5排放情景下呈不显著增加趋势;降水量没有发生突变现象。RCP4.5情景下,年和生长季降水存在23~31 a周期变化;RCP8.5情景下存在7 a的变化周期。陕北红枣种植区应积极适应气候变化,调整种植布局,选择适宜的红枣品种,促进陕北红枣产业可持续健康发展。 相似文献
19.
FAN Zemeng 《地理学报(英文版)》2021,31(4):497-517
Explicitly identifying the spatial distribution of ecological transition zones(ETZs) and simulating their response to climate scenarios is of significance in understanding the response and feedback of ecosystems to global climate change. In this study, a quantitative spatial identification method was developed to assess ETZ distribution in terms of the improved Holdridge life zone(iHLZ) model. Based on climate observations collected from 782 weather stations in China in the T0(1981–2010) period, and the Intergovernmental Panel on Climate Change Coupled Model Intercomparison Project(IPCC CMIP5) RCP2.6, RCP4.5, and RCP8.5 climate scenario data in the T1(2011–2040), T2(2041–2070), and T3(2071–2100) periods, the spatial distribution of ETZs and their response to climate scenarios in China were simulated in the four periods of T0, T1, T2, and T3. Additionally, a spatial shift of mean center model was developed to quantitatively calculate the shift direction and distance of each ETZ type during the periods from T0 to T3. The simulated results revealed 41 ETZ types in China, accounting for 18% of the whole land area. Cold temperate grassland/humid forest and warm temperate arid forest(564,238.5 km~2), cold temperate humid forest and warm temperate arid/humid forest(566,549.75 km~2), and north humid/humid forest and cold temperate humid forest(525,750.25 km~2) were the main ETZ types, accounting for 35% of the total ETZ area in China. Between 2010 and 2100, the area of cold temperate desert shrub and warm temperate desert shrub/thorn steppe ETZs were projected to increase at a rate of 4% per decade, which represented an increase of 3604.2, 10063.1, and 17,242 km~2 per decade under the RCP2.6, RCP4.5, and RCP8.5 scenarios, respectively. The cold ETZ was projected to transform to the warm humid ETZ in the future. The average shift distance of the mean center in the north wet forest and cold temperate desert shrub/thorn grassland ETZs was generally larger than that of other ETZs, with the mean center moving to the northeast and the shift distance being more than 150 km during the periods from T0 to T3.In addition, with a gradual increase of temperature and precipitation, the ETZs in northern China displayed a shifting northward trend, while the area of ETZs in southern China decreased gradually, and their mean center moved to high-altitude areas. The effects of climate change on ETZs presented an increasing trend in China, especially in the Qinghai-Tibet Plateau. 相似文献
20.
IPCC-AR4模式对中国21世纪气候变化的情景预估 总被引:41,自引:3,他引:38
利用政府间气候变化委员会(IPCC)第四次评估报告提供的13个新一代气候系统模式的模拟结果,分析了不同情景下(高排放SRES A2、中等排放A1B、低排放B1)中国区域未来100年的气候变化。结果表明,21世纪中国气候预估显著变暖、变湿,世纪末变暖范围在1.6℃~5℃之间,年降水量增加1.5%~20%。在A2、A1B和B1情景下,21世纪末期增暖幅度依次为5.3℃、4.3℃和2.8℃,平均3.5℃,年降水量预估增加依次为11%、9.6%和6.4%,平均达7.5%。气温和降水变化的地理分布显示:北方增温幅度大于南方,降水的增加也主要集中在北方。冬季变暖最明显,降水则在冬、春季增加较显著。模式预估结果的不确定性分析表明,新一代全球系统模式对21世纪中国气候变化预估的可靠性得到了提高。 相似文献