The mean lifetime of interstellar molecular clouds

We describe the results of a study of the mean lifetime of molecular clouds based on actual observations. Using the model of growth from cloud-cloud collision and observations of ¹³CO along the galactic equator between longitudes 27°.85 and 40°, we derive a lower limit of 1 × 10⁹ yr for the lifetime of the interstellar molecular clouds     

Detection of individual normal modes of oscillation of the Sun in the period range from 2 hr to 10 min in solar diameter studies

Solar Physics - New observations of solar oscillations are reported. Power density spectra derived from these observations reveal narrow-band oscillations that are spatially global, have spatial...     

奔向全球的经济地理:战略耦合与全球生产网络研究——"全球生产网络与中国战略耦合"专辑序言

进入21世纪以来,全球生产网络(Global Production Net-work,GPN)研究非常深刻地展现了 Peter Dicken所描绘的"全球-地方矛盾".这个概念由Dicken在1994年发表于《Economic Geography》上的Roepke Lecture特邀文章中首次提出[1].作为过去20多年经济地理学的一个主要学术支柱,GPN研究经历了两个重要的理论发展阶段,即从早期的广泛而一般的GPN框架2-4]过渡到更加具备解释性的GPN 2.0理论[5-7].在GPN研究理论快速发展的这个时期里,Coe等首先提出了"战略耦合"这一关键而新颖的概念[4],并由Yeung对其进行了完善[8-10].     

Climate change and soil freezing dynamics: historical trends and projected changes

Changes to soil freezing dynamics with climate change can modify ecosystem carbon and nutrient losses. Soil freezing is influenced strongly by both air temperature and insulation by the snowpack, and it has been hypothesized that winter climate warming may lead to increased soil freezing as a result of reduced snowpack thickness. I used weather station data to explore the relationships between winter air temperature, precipitation and soil freezing for 31 sites in Canada, ranging from the temperate zone to the high Arctic. Inter-annual climate variation and associated soil temperature variation over the last 40 years were examined and used to interpolate the effects of projected climate change on soil freezing dynamics within sites using linear regression models. Annual soil freezing days declined with increasing mean winter air temperature despite decreases in snow depth and cover, and reduced precipitation only increased annual soil freezing days in the warmest sites. Annual soil freeze–thaw cycles increased in both warm and dry winters, although the effects of precipitation were strongest in sites that experience low mean winter precipitation. Overall, it was projected that by 2050, changes in winter temperature will have a much stronger effect on annual soil freezing days and freeze–thaw cycles than changes in total precipitation, with sites close to but below freezing experiencing the largest changes in soil freezing days. These results reveal that experimental data relevant to the effects of climate changes on soil freezing dynamics and changes in associated soil physical and biological processes are lacking.