Responding to Global Warming: Mitigation Policies and Actions of Stakeholders in China’s Tourism Industry

China’s tourism industry has witnessed rapid progress in recent years, and is now an important part of global tourism in dealing with climate change. Within a framework of Pressure-State-Response (PSR), this paper focuses on the emission reduction pressure, carbon emission status, and responses of stakeholders in China’s tourism industry. Findings include: 1) The central government’s strategy and rapid growth of the industry scale exert rising pressure on China’s tourism to reduce carbon emissions. 2) Carbon emissions of China's tourism account for 13%-14.6% of global tourism, and about 3% of China’s emissions overall. Chinese tourists’ per capita carbon emission is lower than half of the global level. 3) The Chinese government attaches great importance to energy-saving and carbon emission reduction. In the tourism industry, documents, standards and other regulative measures have been issued to ensure that business practitioners set up green operational and managerial systems. In the field of tourism transportation, China's high-speed rail, new energy vehicles, and urban shared bicycles, have developed very rapidly in recent years, and they have effectively reduced the carbon emissions in traveling. Furthermore, this paper finds that Chinese tourists already have awareness and willingness for low-carbon tourism.     

Response of Microbial Communities in Soil to Multi-level Warming in a Highland Barley System of the Lhasa River

No studies have examined the effect of experimental warming on the microbial biomass and community composition of soil in agricultural ecosystem on the Qinghai-Tibet Plateau. Thus it is unclear whether the influences of experimental warming on microbial communities in soil are related to warming magnitude in croplands on this Plateau. This study performed warming experiment (control, low- and high-level) in a highland barley system of the Lhasa River in May 2014 to examine the correlation between the response of microbial communities in soil to warming and warming magnitude. Topsoil samples (0-10 and 10-20 cm) were collected on September 14, 2014. Experimental warming at both low and high levels significantly increased soil temperature by 1.02 ℃ and 1.59 ℃, respectively at the depth of 15 cm. Phospho lipid fatty acid (PLFA) method was used to determine the microbial community in soil. The low-level experimental warming did not significantly affect the soil’s total PLFA, fungi, bacteria, arbuscular mycorrhizal fungi (AMF), actinomycetes, gram-positive bacteria (G⁺), gram-negative bacteria (G^-), protozoa, the ratio of fungi to bacteria (F/B ratio), and ratio of G⁺ to G^- (G⁺/G^- ratio) at the 0-10 and 10-20 cm depth. The low-level experimental warming also did not significantly alter the composition of microbial community in soil at the 0-10 and 10-20 cm depth. The high-level experimental warming significantly increased total PLFA by 74.4%, fungi by 78.0%, bacteria by 74.0%, AMF by 66.9%, actinomycetes by 81.4%, G⁺ by 67.0% and G^- by 74.4% at the 0-10 cm depth rather than at 10-20 cm depth. The high-level experimental warming significantly altered microbial community composition in soil at the 0-10 cm depth rather than at 10-20 cm depth. Our findings suggest that the response of microbial communities in soil to warming varied with warming magnitudes in the highland barley system of the Lhasa River.     

热带东印度洋SST对气候变暖和变冷的响应

The response of the eastern tropical Indian Ocean(ETIO) to heat fluxes of equal amplitude but opposite sign is investigated using the Community Earth System Model(CESM). A significant positive asymmetry in sea surface temperature(SST) is found over the ETIO—the warming responses to the positive forcing exceeds the cooling to the negative forcing. A mixed layer heat budget analysis is carried out to identify the mechanisms responsible for the SST asymmetry. Results show that it is mainly ascribed to the ocean dynamical processes, including vertical advections and diffusion. The net surface heat flux, on the contrary, works to reduce the asymmetry through its shortwave radiation and latent heat flux components. The former is due to the nonlinear relationship between SST and cloud, while the latter is resulted mainly from Newtonian damping and air-sea stability effects. Changes in the SST skewness are also evaluated, with more enhanced negative SST skewness over the ETIO found for the cooling than heating scenarios due to the asymmetric thermocline-SST feedback.     

气候变化对植物多样性的影响研究综述

植物多样性是生态系统结构和功能的基础,气候变化已对其产生了深刻的影响,甚至于严重威胁.植物多样性的减少或丧失必然会影响生态系统结构和功能的稳定性,导致严重的生态、经济和社会后果.植物多样性对气候变化的响应受控于气温和水分的动态平衡.本文系统总结了气候变暖和降水格局变化对植物多样性的影响,分析了气候变化对不同生态系统、群...     

1980—2018年黄河上游气候变化及其对生态植被和径流量的影响

黄河上游是黄河流域最重要的水源涵养地和产流区,对黄河流域的水资源安全、生态环境和粮食安全有决定性的意义。近年来在西北地区气候暖湿化的背景下,黄河上游气候生态水文等问题受到了各方的高度关注。本文利用卫星遥感数据、格点融合数据和水文监测数据,分析了黄河上游气候的多尺度变化特征及其对植被和径流量的影响。结果表明：1）1980-2018年黄河上游暖湿化趋势呈现全区域较一致的气候特征,温度增加率为0.023℃/a,降水增加率为1.09 mm/a,但同时又存在明显的区域差异性,湟水流域至甘肃中部降水增加最显著,宁蒙荒漠地带增温趋势最明显,2000年以来整个黄河上游降水明显增加。2000年后汇流区与流径区的蒸散发明显增加,但源头区南部波动减少。2）当前的暖湿化有利于黄河上游植被生长,1999年以来汇流区和源头区部分区域的植被增加率达到0.04/（10 a）;从长期趋势看,源头区、汇流区植被指数与上年降水呈显著正相关关系,而流径区植被指数与当年降水相关性显著;降水对黄河上游流域植被具有明显的改善作用,而温度对其影响较复杂,各区域不同的植被类型是导致降水、温度、蒸散影响存在差异的可能原因。3）1980-2018年唐乃亥站和兰州站的年径流量均呈减少趋势,但1998年以来两站的年径流量明显增加,兰州站年径流量的增加率是唐乃亥站的近3倍。长期趋势表明,唐乃亥站年径流量与当年降水呈显著正相关关系,兰州站年径流量与当年降水、蒸散的相关系数均明显低于唐乃亥站;从年际波动看,降水是决定年径流量的最主要影响因子,而生态植被、冻土退化、水储量变化及社会活动等因素对径流量的影响也不容忽视。该研究为科学应对黄河上游生态保护及实现黄河流域高质量发展提供了参考依据。     

2012年1月、2016年1月东亚两次极端严寒事件及其与北极增暖的可能联系

自20世纪80年代后期以来,我国频繁出现暖冬,直到2004年以后这种状况出现明显的变化,冷冬出现的频次明显增多了。在全球增暖、北极海冰减少明显的背景下,冬季极端严寒的强度非但没有减弱反而似乎还在增强,造成灾害性的影响也越发引人关注。在上述背景下,2012年1月、2016年1月在东亚发生了两次极端严寒事件。本文的目的就是通过合成和相关分析,研究这两次极端严寒事件演变的主要特征,及其与北极增暖的可能联系。这两次极端严寒事件的环流演变截然不同。对于2012年1月的极端严寒事件,海平面气压异常主要呈现由东向西传播,在演变过程中,阿留申区域海平面气压超前西伯利亚高压,因此大气环流的下游效应起主要作用。对于2016年1月的极端严寒事件,冷空气主要由西北向东南传播。两次极端事件的主要降温区域的移动路径截然不同。2012年1月冷空气爆发以后主要在亚洲大陆中、高纬度维持并向西传播,其南传影响亚洲低纬度区域明显弱于2016年的冷事件。而2016年1月的主要降温区以沿东亚向南移动为主,强降温区直接南下至热带区域。两次极端严寒事件爆发前期大气环流演变的共同点:中、高纬度区域环流能量交换活跃,表现为中纬度高度脊加强北伸,从而把较低纬度的暖空气输送至北极区域,高纬度区域对流层中层呈现多极结构。这种多极空间结构是亚洲冷空气向南爆发的重要前兆信号。冬季北极阶段性增暖过程首先是中纬度高度脊加强北伸的结果。对影响东亚的极端严寒过程,乌拉尔附近区域的高压脊以及位于北美西部的高压脊加强北上、协同演变是至关重要的。2016年1月东亚极端严寒过程与2015年12月末北极快速增暖没有必然联系。     

2022年夏季中国高温干旱气候特征及成因探讨

2022年夏季,中国中东部发生了极端高温干旱气候异常,给经济、农业、人民生活造成了严重影响。本文回顾了此次高温干旱气候异常的时空特征,分析了其主要成因。2022年夏季,中国中东部区域平均的极端高温频次、日最高温度平均值、高温日数等指标均达到了1979年以来的最大值,区域平均降水则达到了1979年以来的最低值。此次气候异常主要是由于夏季中国中东部受强大的高压系统控制,与偏强的西太副高、中纬度的西风带扰动以及热带海温的影响有关。此外,本文探讨了全球增暖趋势对极端高温事件增多的影响,以及未来中国地区高温和干旱事件的可能变化。     

Intraseasonal oscillation intensity over the western North Pacific:Projected changes under global warming

本文利用8个CMIP5模式的日资料,预估了RCP4.5和RCP8.5情景下全球增温达1.5℃和2.0℃时西北太平洋夏季30～60天和10～20天季节内振荡(ISO)强度的变化情况.大多数模式都认为,无论增温水平或情景如何,预估结果均显示从中南半岛南部到菲律宾以东的带状区域内ISO强度增加,并且关键气象要素背景的变化会对...     

Future Changes in Extreme High Temperature over China at 1.5℃-5℃ Global Warming Based on CMIP6 Simulations

Extreme high temperature(EHT)events are among the most impact-related consequences related to climate change,especially for China,a nation with a large population that is vulnerable to the climate warming.Based on the latest Coupled Model Intercomparison Project Phase 6(CMIP6),this study assesses future EHT changes across China at five specific global warming thresholds(1.5℃-5℃).The results indicate that global mean temperature will increase by 1.5℃/2℃ before 2030/2050 relative to pre-industrial levels(1861-1900)under three future scenarios(SSP1-2.6,SSP2-4.5,and SSP5-8.5),and warming will occur faster under SSP5-8.5 compared to SSP1-2.6 and SSP2-4.5.Under SSP5-8.5,global warming will eventually exceed 5℃ by 2100,while under SSP1-2.6,it will stabilize around 2℃ after 2050.In China,most of the areas where warming exceeds global average levels will be located in Tibet and northern China(Northwest China,North China and Northeast China),covering 50%-70%of the country.Furthermore,about 0.19-0.44 billion people(accounting for 16%-41%of the national population)will experience warming above the global average.Compared to present-day(1995-2014),the warmest day(TXx)will increase most notably in northern China,while the number of warm days(TX90p)and warm spell duration indicator(WSDI)will increase most profoundly in southern China.For example,relative to the present-day,TXx will increase by 1℃-5℃ in northern China,and TX90p(WSDI)will increase by 25-150(10-80)days in southern China at 1.5℃-5℃ global warming.Compared to 2℃-5℃,limiting global warming to 1.5℃ will help avoid about 36%-87%of the EHT increases in China.     

基于大数据分析下的气候模型

为研究全球变暖与极寒天气间的关系,对加拿大13个省代表性测站10年的观测数据进行时空变化趋势分析,采用经验正交函数（EOF）寻找海洋表面温度历史数据的变化规律。另外利用BP神经网络建立了年平均温度、日降水量与地球吸热、散热、海表面温度、当地纬度间的关系,预测未来25年气候的变化,并建立了“极寒天气”与气候变化的关系模型。研究表明：高纬度地区温度、降水量普遍较低,同经度地区的温度差异较小且降水量变化不大;加拿大地区温度呈周期性变化,符合北半球的季节变化特征;北大西洋的东部与其他海洋的温度是反相关的,西太平洋南北回归线附近的海洋表面温度升高;“极寒天气”出现频率与气候变化有一定关系,局地极寒现象与全球变暖的大趋势并不矛盾。本研究为人们认识和理解“全球变暖”提供了一个新的思路。