Reducing Vulnerability to Climate Variability in Southern Africa: The Growing Role of Climate Information

Since the devastating southern Africa drought of 1991/92 awareness has grown of the potential to better manage climate variability in the region through seasonal climate forecasting and monitoring of El Niño and the Southern Oscillation (ENSO). While other factors besides ENSO affect southern Africa's climate, and climate forecasting for the region is not based exclusively on ENSO, a major El Niño beginning in 1997 captured the attention of policy-makers and the public. Awareness of drought risks associated with the 1997/98 event was greater than during previous El Niños in 1991/92 and 1994/95. Mitigation and planning efforts also began earlier, with drought early warnings widely available and being taken seriously prior to the 1997/98 agricultural season. Actions taken include issuance of guidance to the public, on-going monitoring and preparedness efforts including the development of national preparedness plans in some countries, pre-positioning of food stocks, donor coordination, and greater reliance on the private-sector for meeting regional food needs. Although 1998 regional crop production was slightly below average, a major drought did not materialize. Nonetheless the experience is likely to ultimately strengthen capacity within the region to manage climate variability over the long term.     

农业对气候变化的脆弱性

随着对气候变化研究的不断深入,气候变化脆弱性问题也得到了更多的关注。相对于水资源、森林等其他自然生态系统,农业受气候变化的影响最大,科学地评价其对气候变化的脆弱性,对于制定合理有效的适应对策具有重要意义。从气候变化脆弱性与农业对气候变化脆弱性的定义、研究内容和评价方法等角度综述了研究进展,在此基础上分析了目前该领域存在的问题,包括情景应用、方法和不确定性等方面,并展望了未来脆弱性评价的发展方向。     

Assessing the Role of Adaptation in Evaluating Vulnerability to Climate Change

Three types of adaptation can influence significantly a system's prospective longevity in the face of climate change. The ability to cope with variation in its current environment can help a system adapt to changes over the longer term. The ability to take advantage of beneficial changes that might coincide with potentially harmful ones can play an even larger role; and focusing attention on maximizing a system's sustainable lifetime can highlight the potential for extending that time horizon and increasing the likelihood that an alternative structure might be created. A specific economic approach to adaptation demonstrates that research can serve two functions in this regard. Research can play an important role in diminishing future harm suggested by standard impact analyses by focusing attention on systems where adaptation can buy the most time. It can help societies learn how to become more robust under current conditions; and it can lead them to explore mechanisms by which they can exploit potentially beneficial change. Research can also play a critical role in assessing the need for mitigating long-term change by focusing attention on systems where potential adaptation in both the short and long runs is so limited that it is almost impossible to buy any time at all. In these areas, switching to an alternative system or investing in the protection of existing ones are the last lines of defense. Real "windows" of tolerable climate change can be defined only by working in areas where these sorts of adaptive alternatives cannot be uncovered.     

Reducing Vulnerability of Agriculture and Forestry to Climate Variability and Change: Workshop Summary and Recommendations

The International Workshop on Reducing Vulnerability of Agriculture and Forestry to Climate Variability and Climate Change held in Ljubljana, Solvenia, from 7 to 9 October 2002 addressed a range of important issues relating to climate variability, climate change, agriculture, and forestry including the state of agriculture and forestry and agrometeological information, and potential adaptation strategies for agriculture and forestry to changing climate conditions and other pressures. There is evidence that global warming over the last millennium has already resulted in increased global average annual temperature and changes in rainfall, with the 1990s being likely the warmest decade in the Northern Hemisphere at least. During the past century, changes in temperature patterns have, for example, had a direct impact on the number of frost days and the length of growing seasons with significant implications for agriculture and forestry. Land cover changes, changes in global ocean circulation and sea surface temperature patterns, and changes in the composition of the global atmosphere are leading to changes in rainfall. These changes may be more pronounced in the tropics. For example, crop varieties grown in the Sahel may not be able to withstand the projected warming trends and will certainly be at risk due to projected lower amounts of rainfall as well. Seasonal to interannual climate forecasts will definitely improve in the future with a better understanding of dynamic relationships. However, the main issue at present is how to make better use of the existing information and dispersion of knowledge to the farm level. Direct participation by the farming communities in pilot projects on agrometeorological services will be essential to determine the actual value of forecasts and to better identify the specific user needs. Old (visits, extension radio) and new (internet) communication techniques, when adapted to local applications, may assist in the dissemination of useful information to the farmers and decision makers. Some farming systems with an inherent resilience may adapt more readily to climate pressures, making long-term adjustments to varying and changing conditions. Other systems will need interventions for adaptation that should be more strongly supported by agrometeorological services for agricultural producers. This applies, among others, to systems where pests and diseases play an important role. Scientists have to guide policy makers in fostering an environment in which adaptation strategies can be effected. There is a clear need for integrating preparedness for climate variability and climate change. In developed countries, a trend of higher yields, but with greater annual fluctuations and changes in cropping patterns and crop calendars can be expected with changing climate scenarios. Shifts in projected cropping patterns can be disruptive to rural societies in general. However, developed countries have the technology to adapt more readily to the projected climate changes. In many developing countries, the present conditions of agriculture and forestry are already marginal, due to degradation of natural resources, the use of inappropriate technologies and other stresses. For these reasons, the ability to adapt will be more difficult in the tropics and subtropics and in countries in transition. Food security will remain a problem in many developing countries. Nevertheless, there are many examples of traditional knowledge, indigenous technologies and local innovations that can be used effectively as a foundation for improved farming systems. Before developing adaptation strategies, it is essential to learn from the actual difficulties faced by farmers to cope with risk management at the farm level. Agrometeorologists must play an important role in assisting farmers with the development of feasible strategies to adapt to climate variability and climate change. Agrometeorologists should also advise national policy makers on the urgent need to cope with the vulnerabilities of agriculture and forestry to climate variability and climate change. The workshop recommendations were largely limited to adaptation. Adaptation to the adverse effects of climate variability and climate change is of high priority for nearly all countries, but developing countries are particularly vulnerable. Effective measures to cope with vulnerability and adaptation need to be developed at all levels. Capacity building must be integrated into adaptation measures for sustainable agricultural development strategies. Consequently, nations must develop strategies that effectively focus on specific regional issues to promote sustainable development.     

农业生产对气候变化的脆弱性研究方法初探

在总结脆弱性的定义与介绍相关研究方法的基础上，提出了农业生产对气候变化的脆弱性的初步定义、研究思路、指标体系及计算方法，并讨论了区域农业生产对气候变化影响的适应对策应遵循的有关原则。     

对搞好农用气象服务的思考

搞好农用气象服务工作,要做到熟悉和掌握当地的基本情况、基本气候特征、气象灾害和病虫害发生情况、作物生理生态特点、作物气候生态适应性等5个方面的内容。要做到服务形式灵活多样,服务产品针对性强。同时要加强4个基本建设和4个体系建设工作。     

农业气象教育和培训的现状与未来需求

<正>农业气象学是研究农业与气象条件之间相互关系及其规律的科学,它既是应用气象学的一个分支,又是农学的一门基础学科。其基本任务就在于研究这些农业自然资源和农业自然灾害的时空分布规律,为农业的区划和规划、作物的合理布局、人工调节小气候和     

Climate Variability over the Maritime Continent and Its Role in Global Climate Variation: A Review

The Maritime Continent(MC) consists of multiple islands with varying sizes and topography, and surrounding seas. It is characterized by rainfall(convection) variability on multiple spatial and temporal scales. Various largescale atmospheric, oceanic, and coupled climate systems, such as the El Ni?o–Southern Oscillation(ENSO), Indian Ocean Dipole(IOD), Madden–Julian Oscillation(MJO), and cold surge, exert significant influences on the spatiotemporal complexity of the MC climate and climate variability. As a major tropical heat source located within the warmest oceanic area(the western Pacific warm pool), the MC has been identified as a region of great importance for climate variation on the global scale. However, prediction of climate variability over the MC and its surrounding areas and the relationships to large-scale atmospheric circulation patterns are big challenges, even for state-of-the-art climate models. In this paper, we provide a thorough review on current understanding of the spatiotemporal complexity and prediction of climate variability over this important region, and its influence on global climate variation.     

美国年代际气候变率研讨会简介

2005年10月16～20日在美国弗吉尼亚州埃尔利中心召开了年代际气候变率研讨会。这个会议由美国CLIVAR/WCRP/IPCC办公室联合NOAA、NASA、NSF等单位共同举办。与会代表共约40位科学家，多数来自美国，少数代表来自德国、英国、中国和日本。会议由美国地球系统变化研究中心(CRCES)承办。     

Seasonal and Inter-Annual Climate Forecasting: The New Tool for Increasing Preparedness to Climate Variability and Change In Agricultural Planning And Operations

Climate variability and change affects individuals and societies. Within agricultural systems, seasonal climate forecasting can increase preparedness and lead to better social, economic and environmental outcomes. However, climate forecasting is not the panacea to all our problems in agriculture. Instead, it is one of many risk management tools that sometimes play an important role in decision-making. Understanding when, where and how to use this tool is a complex and multi-dimensional problem. To do this effectively, we suggest a participatory, cross-disciplinary research approach that brings together institutions (partnerships), disciplines (e.g., climate science, agricultural systems science, rural sociology and many other disciplines) and people (scientist, policy makers and direct beneficiaries) as equal partners to reap the benefits from climate knowledge. Climate science can provide insights into climatic processes, agricultural systems science can translate these insights into management options and rural sociology can help determine the options that are most feasible or desirable from a socio-economic perspective. Any scientific breakthroughs in climate forecasting capabilities are much more likely to have an immediate and positive impact if they are conducted and delivered within such a framework. While knowledge and understanding of the socio-economic circumstances is important and must be taken into account, the general approach of integrated systems science is generic and applicable in developed as well as in developing countries. Examples of decisions aided by simulation output ranges from tactical crop management options, commodity marketing to policy decisions about future land use. We also highlight the need to better understand temporal- and spatial-scale variability and argue that only a probabilistic approach to outcome dissemination should be considered. We demonstrated how knowledge of climatic variability (CV), can lead to better decisions in agriculture, regardless of geographical location and socio-economic conditions.     

Potential Role of Solar Variability as an Agent for Climate Change

Numerical experiments have been carried out with a two-dimensional sector averaged global climate model in order to assess the potential impact of solar variability on the Earth's surface temperature from 1700 to 1992. This was done by investigating the model response to the variations in solar radiation caused by the changes in the Earth's orbital elements, as well as by the changes intrinsic to the Sun. In the absence of a full physical theory able to explain the origin of the observed total solar irradiance variations, three different total solar irradiance reconstructions have been used. A total solar irradiance change due to the photospheric effects incorporated in the Willson and Hudson (1988) parameterization, and the newly reconstructed solar total irradiance variations from the solar models of Hoyt and Schatten (1993) and Lean et al. (1995). Our results indicate that while the influence of the orbital forcing on the annual and global mean surface temperature is negligible at the century time scale, the monthly mean response to this forcing can be quite different from one month to another. The modelled global warming due to the three investigated total solar irradiance reconstructions is insufficient to reproduce the observed 20th century warming. Nevertheless, our simulated surface temperature response to the changes in the Sun's radiant energy output suggests that the Gleissberg cycle (88 years) solar forcing should not be neglected in explaining the century-scale climate variations. Finally, spectral analysis seems to point out that the 10- to 12-year oscillations found in the recorded Northern Hemisphere temperature variations from 1700 to 1992 could be unrelated to the solar forcing. Such a result could indicate that the eleven-year period which is frequently found in climate data might be related to oscillations in the atmosphere or oceans, internal to the climate system.     

县级农业气象常规业务软件设计

介绍了县级农业气象常规业务软件的总体设计思路及具体功能模块的实现方法,并对现行的业务运作模式进行了思考.     

县级农业气象常规业务软件设计

介绍了县级农业气象常规业务软件的总体设计思路及具体功能模块的实现方法，并对现行的业务运作模式进行了思考。     

Theory and Practice in Assessing Vulnerability to Climate Change andFacilitating Adaptation

We discuss approaches to the assessment of vulnerability to climatevariability and change andattempt to clarify the relationship between the concepts of vulnerability andadaptation. In searchof a robust, policy-relevant framework, we define vulnerability in terms ofthe capacity ofindividuals and social groups to respond to, that is, to cope with, recoverfrom or adapt to, anyexternal stress placed on their livelihoods and well-being. The approach thatwe develop placesthe social and economic well-being of society at the centre of the analysis,focussing on thesocio-economic and institutional constraints that limit the capacity torespond. From thisperspective, the vulnerability or security of any group is determined byresource availability andby the entitlement of individuals and groups to call on these resources. Weillustrate theapplication of this approach through the results of field research in coastalVietnam, highlightingshifting patterns of vulnerability to tropical storm impacts at the household-and community-levelin response to the current process of economic renovation and drawingconclusions concerningmeans of supporting the adaptive response to climate stress. Four prioritiesfor action areidentified that would improve the situation of the most exposed members ofmany communities:poverty reduction; risk-spreading through income diversification; respectingcommon propertymanagement rights; and promoting collective security. A sustainable response,we argue, mustalso address the underlying causes of social vulnerability, including theinequitable distributionof resources.     

Climate Variability and Urbanization in Athens

Summary  The effects of urbanization on the Athens National Observatory (NOA) long records are investigated, in the present study, examining the mean monthly maximum and minimum air temperature for the period 1925–1996, for NOA and the corresponding time series for Aliartos (ALI), a rural station located 70 km NW of Athens. The existing small urbanization effect in NOA before the second world war period increased after the war and up to about 1990, when the effect became stationary. The urbanization effect in NOA referred mainly to maximum temperature and to the warmer seasons of the year. It is attributed to the extensive building of Athens after the war around NOA site and up to the sea which increases the temperature of the sea breeze. The effect is also attributed to the rapid increase of the population and the number of motor vehicles mainly after 1970. Moreover the decreasing trend of precipitation during the period 1970–1990 may have contributed to the increase of maximum air temperature. The urbanization effect on maximum temperatures of NOA amounts about 2 °C in spring, summer and less in fall, while no urbanization effect is clear in winter. Received March 25, 1998 Revised October 7, 1998     

An Anatomy of Adaptation to Climate Change and Variability

Adaptation to climate variability and change is important both for impact assessment (to estimate adaptations which are likely to occur) and for policy development (to advise on or prescribe adaptations). This paper proposes an "anatomy of adaptation" to systematically specify and differentiate adaptations, based upon three questions: (i) adapt to what? (ii) who or what adapts? and (iii) how does adaptation occur? Climatic stimuli include changes in long-term mean conditions and variability about means, both current and future, and including extremes. Adaptation depends fundamentally on the characteristics of the system of interest, including its sensitivities and vulnerabilities. The nature of adaptation processes and forms can be distinguished by numerous attributes including timing, purposefulness, and effect. The paper notes the contribution of conceptual and numerical models and empirical studies to the understanding of adaptation, and outlines approaches to the normative evaluation of adaptation measures and strategies.     

The 12th Workshop on Antarctic Meteorology and Climate

正1.Overview The 12th Workshop on Antarctic Meteorology and Climate(WAMC),formerly known as the Antarctic Meteorological Observation,Modeling,and Forecasting(AMOMF)Workshop(AMOMFW),was held at the National Center for Atmospheric Research(NCAR)in Boulder,Colorado,USA on 26–28 June 2017.The annual workshop dates from 2006,and recent meetings have been the 10th AMOMF Workshop held in 2015 in Cambridge,United Kingdom(Colwell et al.,2016)and the     

Vulnerability of the Asian Typical Steppe to Grazing and Climate Change

The vulnerability of grassland vegetation in Inner Mongolia to climate change and grazing was examined using an ecosystem model. Grazing is an important form of land use in this region, yet there are uncertainties as to how it will be affected by climate change. A sensitivity analysis was conducted to study the effects of increased minimum and maximum temperatures, ambient and elevated CO₂, increased or decreased precipitation, and grazing on vegetation production. Simulations showed that herbaceous above ground net primary production was most sensitive to changes in precipitation levels. Combinations of increased precipitation, temperature, and CO₂ had synergistic effects on herbaceous production, however drastic increases in these climate scenarios left the system vulnerable to shifts from herbaceous to shrub-dominated vegetation when grazed. Reduced precipitation had a negative effect on vegetation growth rates, thus herbaceous growth was not sustainable with moderate grazing. Shifts in temporal biomass patterns due to changed climate have potentially significant implications for grazing management, which will need to be altered under changing climate to maintain system stability.     

Vulnerability Assessment of the Maize and Sorghum Crops to Climate Change in Botswana

This study examines the sensitivity of maize and sorghum crops to global warming in Botswana, a country with arid climatic conditions and shortfalls in locally produced grain. The vulnerability of the maize and sorghum crops to climate change were studied using crop simulation models while climate change scenarios were generated from Global Circulation Models. Simulated yields indicated that rain-fed crop production under the observed climate was a small fraction of what could be produced under optimal conditions. The gap was attributed to both physical (especially lack of rain) and socio-economic constraints. Using the southern African core climate change scenario, simulated yields declined by 36% in the case of maize and 31% for sorghum in the sand veldt region. Yield reductions from thehard veldt region were in the order of 10% for both maize and sorghum. The growing season became shorter, the average reduction in days in the sand veldt region being 5 and 8 days for maize and sorghum respectively, and correspondingly, 3 and 4 days over the hard veldt region. The food security option currently followed in Botswana was found to be a good adaptive strategy under a changed climate.