Changes in Barents Sea Ice Edge Positions in the Last 442 Years. Part 2: Sun, Moon and Planets

This is the second paper in a series of two, which analyze the position of the Barents Sea ice-edge (BIE) based on a 442-year long dataset to understand its time variations. The data have been collected from ship-logs, polar expeditions, and hunters in addition to airplanes and satellites in recent times. Our main result is that the BIE position alternates between a southern and a northern position followed by Gulf Stream Beats (GSBs) at the occurrence of deep solar minima. We decompose the low frequency BIE position variations in cycles composed of dominant periods which are related to the Jose period of 179 years, indicating planetary forcings. We propose that the mechanism transferring planetary signals into changes in BIE position is the solar wind (SW), which provides magnetic shielding of the Earth in addition to geomagnetic disturbances. Increase in the solar wind produces pressure which decelerates the Earth’s rotation. It also transfers electrical energy to the ring current in the earth’s magnetosphere. This current magnetizes the earth’s solid core and makes it rotate faster. To conserve angular momentum the earth’s outer fluid mantle rotates slower with a delay of about 100 years. In addition will geomagnetic storms, initiated by solar coronal mass ejections (CMEs) penetrate deep in the Earth’s atmosphere and change pressure pattern in the Arctic. This effect is larger during solar minima since the magnetic shielding then is reduced. The Arctic may then experience local warming. The transition of solar activities to a possibly deep and long minimum in the present century may indicate Arctic cooling and the BIE moving south this century. For the North Atlantic region, effects of the BIE expanding southward will have noticeable consequences for the ocean bio-production from about 2040.

Hydraulic and volume change behaviors of compacted highly expansive soil under cyclic wetting and drying

The wide engineered application of compacted expansive soils necessitates understanding their behavior under field conditions.The results of this study demonstrate how seasonal climatic variation and stress and boundary conditions individually or collectively influence the hydraulic and volume change behavior of compacted highly expansive soils.The cyclic wetting and drying(CWD)process was applied for two boundary conditions,i.e.constant stress(CS)and constant volume(CV),and for a wide range of axial stress states.The adopted CWD process affected the hydraulic and volume change behaviors of expansive soils,with the first cycle of wetting and drying being the most effective.The CWD process under CS conditions resulted in shrinkage accumulation and reduction in saturated hydraulic conductivity(k sat).On the other hand,CWD under CV conditions caused a reduction of swell pressure while has almost no impact on k sat.An elastic response to CWD was achieved after the third cycle for saturated hydraulic conductivity(k sat),the third to fourth cycle for the volume change potential under the CV conditions,and the fourth to fifth cycle for the volume change potential under the CS conditions.Finally,both swell pressure(s s)and saturated hydraulic conductivity(k sat)are not fundamental parameters of the expansive soil but rather depend on stress,boundary and wetting conditions.

Changes in Barents Sea ice Edge Positions in the Last 440 years: A Review of Possible Driving Forces

This is the first report of the Barents Sea Ice Edge (BIE) project. The BIE position has varied between latitude 76°N and above 82°N during the last 440 years. During the period 10,000 to 6000 years ago, Arctic climate was significantly warmer than today. We review various oceanic and atmospheric factors that may have an effect on the BIE position. The Gulf Stream beat with respect to alternations in flow intensity and N-S distribution plays a central role for the changes in climate and BIE position during the last millennium. This occurred in combination with external forcing from total solar irradiation, Earth’s shielding strength, Earth’s geomagnetic field intensity, Earth’s rotation, jet stream changes;all factors of which are ultimately driven by the planetary beat on the Sun, the Earth and the Earth-Moon system. During the last 20 years, we see signs of changes and shifts that may signal the end of the late 20th century warm period. The BIE position is likely to start advancing southward in next decade.

The Comparative Effects of Cyclic Inquiry Model, Conceptual Change Text, and Traditional Instruction on Students' Understanding of Pho- tosynthesis and Respiration in Plants

The aim of this study was to explore the effects of the cyclic inquiry model,conceptual change texts,and traditional instructions on promoting understanding of photosynthesis and respiration in plants.The data were obtained from 33 students in the first experimental group taught with cyclic inquiry model(CIM),34 students in the second experimental group taught with conceptual change texts(CCT),and 34 students in the control group taught with traditional instruction(TI).After instruction,data were analyzed with analysis of covariance(ANCOVA)using pre-test scores and logical thinking scores as covariates.The results indicated the cyclic inquiry model(CIM)and conceptual change texts(CCT)treatment groups significantly outperformed the traditional instruction(TI)group in understanding the photosynthesis and respiration in plants.A statistically significant difference between two experimental groups was found in favor of the of cyclic inquiry model CIM.

Molecular Mechanisms of Cyclic Nucleotide-Gated Ion Channel Gating

Cyclic nucleotide-gated ion channels （CNGs） are distributed most widely in the neuronal cell. Great progress has been made in molecular mechanisms of CNG channel gating in the recent years. Results of many experiments have indicated that the stoichiometry and assembly of CNG channels affect their property and gating. Experiments of CNG mutants and analyses of cys- teine accessibilities show that cyclic nucleotide-binding domains （CNBD） bind cyclic nucleotides and subsequently conformational changes occurred followed by the concerted or cooperative conformational change of all four subunits during CNG gating. In order to provide theoretical assistances for further investigation on CNG channels, especially regarding the disease pathogenesis of ion channels, this paper reviews the latest progress on mechanisms of CNG channels, functions of subunits, processes of subunit assembly, and conformational changes of subunit regions during gating.

水电机组摆度周期性波动问题的分析和研究

本文针对某水电站机组上导轴承摆度峰峰值持续呈正弦周期性波动的问题,通过增加临时探头测量机组动态和静态时上机架支臂和基坑的间隙,以及不同方向支臂的间隙和机组运行参数等,发现支臂和基坑间隙一一对应,且间隙随环境温度的增加而增加,该间隙的变化规律符合因大部件金属构件蠕变传递至基座传感器引起的上导摆度周期波动的特征。因此可以确定机组摆度周期性波动是因为大部件金属随着温度变化而出现较大的位移蠕变,且该蠕变为非对称蠕变,以上过程量逐级传递至基座传感器位置,同时该文建议采用该结构形式的机架时应充分考虑支臂蠕变方向和限位措施。

近疲劳强度循环荷载下粉砂岩强度变化机制

通过开展不同循环次数的循环加卸载转单调加载试验,结合声发射和CT扫描技术,揭示了近疲劳强度循环荷载作用下泥质石英粉砂岩的细观破裂演化规律、裂隙扩展特征与强度变化机制.结果表明:(1)泥质石英粉砂岩的损伤应力小于疲劳强度,可称损伤应力与疲劳强度之间的应力水平为近疲劳强度.(2)随着循环次数增加,粉砂岩峰值强度先小幅下降后持续增加最终趋于稳定,当一次循环后轴向(体积)变形从压缩(膨胀)转为几乎不变时,可认为粉砂岩的强度从劣化转为强化.(3)单调加载阶段应力接近峰值强度时,粉砂岩中、低频区的声发射信号大幅增加,可将其视为岩石受压破坏的先兆.(4)当循环次数较低时,循环过程中粉砂岩的弱胶结结构断裂,有效承载面积减小,转单调加载后岩石破裂尺度增大、内部裂纹局部集中,发生劣化,呈单斜面剪切破坏.(5)当循环次数较高时,循环过程中粉砂岩胶结强度增加、细观结构更为致密与均匀,有效承载面积增大,岩石内部在泊松效应的影响下持续产生横向拉应力,转单调加载后岩石裂隙尺寸、裂隙密度和破碎程度降低,发生强化,呈张拉–剪切的复合裂隙网络.

LA-MA/陶粒相变储能材料热物性试验与分析

目的为拓宽相变材料在建筑节能领域中的应用,针对单一相变材料难以满足建筑热工性能要求的问题。方法以十二醇(LA)和十四酸(MA)为复合相变材料、页岩陶粒为载体,制备一种新型相变储能骨料。采用差式扫描量热仪(DSC)、傅里叶红外光谱仪(FT-IR)、热重分析仪(TG)等对相变储能骨料的热物性和不同封装方式下的相变循环稳定性进行分析。结果经复合后相变材料、相变储能骨料的相变温度和相变潜热分别为22.08℃、22.92℃和182.1J/g、22.33J/g。LA-MA复合相变材料和页岩陶粒之间仅存在物理嵌合关系,相变储能骨料在70℃以下未发生物质分解。苯丙乳液封装相变储能骨料在5℃~45℃范围内经历100次相变循环后,质量损失率为0.80%。结论LA-MA/陶粒相变储能骨料的热物性满足建筑节能要求,化学结构稳定,热稳定性好,具有优异的循环耐久性,可应用到建筑围护结构中,研究结论对相变储能材料在建筑围护结构中的应用具有参考价值。

添加膨胀石墨的二十二烷-十二醇复合定形相变材料的性能研究

针对于太阳能PV/T系统相变材料热导率低、易泄漏的问题,本工作制备了二十二烷-十二醇/膨胀石墨复合定形相变材料并对其性能进行实验研究。本工作首先按照6∶4的比例制备了二十二烷-十二醇相变材料,然后采用熔融共混法制备了一系列膨胀石墨含量不同的复合定形相变材料。实验借助场发射扫描电子显微镜观察其微观结构,利用热流型差示扫描量热仪、热导率测量仪等仪器测量其潜热、热导率等参数,研究了材料的物理相容性、吸附性、循环稳定性,探究了膨胀石墨和二十二烷-十二醇的最佳配比及其各项性能。结果表明,当膨胀石墨质量分数为15%时,复合定形相变材料性能最佳,此时膨胀石墨足以将相变材料吸附,渗漏率仅为3.85%且无明显渗出,其熔化和凝固相变潜热分别为203.8 kJ/kg和-196.6 kJ/kg;在经过50次冷热循环后,其相变温度及潜热变化较小,热导率基本保持稳定,波动幅度仅为5.9%,质量损失较少,仅为0.0495 g,表现出良好的循环稳定性。研究为后续定形相变材料在太阳能PV/T系统中的应用提供理论数据支撑。

中国东部及西北太平洋地区边界层高度变化特征

利用19792019年ERA5逐月大气边界层高度(ABLH,Atmospheric boundary layer height)资料,采用气候态分析、距平分析、极值分析、经验正交(EOF)分析及小波分析等方法,研究了中国东部及西北太平洋区域大气边界层高度的变化特征。结果表明:(1)太阳辐射对边界层高度有重要影响,边界层高度的季节变化存在显著的海陆差异,大陆(海洋)上,夏季时边界层高度最高(低),而在冬季时最低(高)。(2)边界层高度的海陆差异随季节改变,春秋季海陆差异较小,冬夏季时最明显。(3)大陆上边界层高度极大值出现在夏半年的月份,极小值出现在冬半年的月份;海洋上的相反。(4)41年边界层高度场的EOF分析得到两个模态,第一模态表现为南北经向和海陆差异,第二模态为自西北至东南的“+-+-”相位分布,第一模态的时间系数以3~7 a的周期最显著,第二模态同时存在4~7 a和9~11 a的振荡周期。

全新世气候变化与中国北方沙漠化

气候变化是中国北方地区荒漠化形成发展的主要控制因素。新生代以来伴随着青藏高原的隆升和内陆盆地的下降逐渐形成的气候格局造就了北方地区荒漠化土地的分布。北方西部内陆盆地以干旱气候为主要特征,中部高原是受季风系统中夏季风和冬季风的消长变化影响最为显著的地区,东部地区则以暖湿气候为主,受夏季风控制。第四系以来气候的波动则控制着沙漠化的发展或逆转。末次间冰期以来一直持续的大约以1500a为周期的气候振荡对中国北方地区的沙漠化有重要的影响或控制作用。全新世以来,北方地区约在10000aBP、8000aBP、5500aBP、4000aBP、3000aBP、1500aBP的沙漠化过程分别与北大西洋第7、5、4、3、2和1次的浮冰事件相应,沙漠化扩大过程与全球气候变化的主要事件相一致。十年尺度上气候变化的周期性振荡对沙漠化有一定的影响,至少在生态环境脆弱的敏感地带对沙漠化可以起到控制作用。年际尺度上,6.7a和3.38a气候变化周期控制着我国北方地区沙尘暴的发生。此外,北方不同地区近150a以来的人类活动对沙漠化的扩大起到了重要作用。

皖南网纹红土的粒度分布特征及古环境意义

安徽宣城向阳剖面高分辨率粒度分析结果表明 :1)网纹红土含有较高的胶结性很强的次生氧化铁 ,样品前处理时单颗粒的分散效果将会显著地影响粒度测试结果。向阳剖面不含 >2mm的砾石 ,砂粒 ( >6 3μm)的含量也很低 ,粘粒 ( <2 μm)和粗粉砂 ( 10～ 5 0 μm)明显富集 ;2 )除底部外 ,向阳剖面粒度组成特征反映了明显的风成特性 ,但不能因此忽视其强风化特征的存在 ,尤其是剖面中、下部的网纹红土。应肯定向阳网纹红土的风成特性 ,但不能简单地称其为风积成因 ;3)向阳剖面磁化率值与粘粒和细颗粒含量无显著正相关性 ,说明磁化率值不能指示网纹红土的风化强度 ;4 )向阳剖面粒度分布特征无法提供该剖面存在多个“沉积—成土”过程旋回的证据。向阳网纹红土更多地体现了其具有原始风成沉积和后期强烈风化的双重特性。

塔里木盆地巴楚地区石炭系高频旋回层序分析

高频旋回层序是海平面高频振荡的结果和产物。通过对塔里木盆地巴楚地区石炭系地面、钻井剖面的详细解析，首次总结出７个高频旋回层序类型，识别出５０余个五级（或六级）高频旋回层序，它们在纵向上有规律地组合、叠加，组成８个四级旋回层序，３个三级旋回层序及２个二级旋回层序，构成了塔里木盆地巴楚地区石炭系的层序地层格架，同时也反映了该区石炭纪海平面的变化规律及其沉积响应。

pH不同处理时间的周期性变动对凡纳滨对虾生长的影响

探讨不同的pH变动模式对对虾生长的影响,设计2个独立的实验,分别研究pH值为8.9和4.0的不同时间的处理条件下,酸碱度的周期性变化对凡纳滨对虾的生长的影响,实验1设置了2个恒定pH组(7.9±0.15和4.0±0.10)和5个pH周期性变动的处理:对虾每2天在pH=(4.0±0.10)下分别处理0.5,1,2,4或12 h,其它时间处在正常pH=7.9中。结果表明,每2天1 h以上的pH=4.0的处理就能显著阻碍对虾的生长,而每2天12 h以上的pH=4.0的处理就能显著影响对虾的成活率。实验2设置了两个恒定pH组(分别为7.9±0.15和8.9±0.10)和6个pH周期性变动的处理:对虾每天在pH=8.9±0.10下分别处理0.5,1,2,4,8或12 h,其它时间处在正常pH中(7.9)。结果表明恒定的高pH(8.9±0.10)显著抑制了对虾的生长,而每天给予凡纳滨对虾2 h和4 h的pH=8.9的刺激则能提高其摄食率和食物转化率,并显著促进其生长。总之,pH值周期性地向酸性环境方向波动会明显妨碍对虾的生长,而向碱性环境方向的波动则会促进对虾的生长,而且这一影响的强度与波动持续的时间长短有关。

Fischer图解及其在旋回层序研究中的应用──以北京西山张夏组为例

Ｆｉｓｃｈｅｒ图解（又称为容纳空间图解）为人们研究沉积旋回在空间上的叠置规律、相对海平面变化、层序级次的划分以及地层层序对比等提供了一种客观实用的方法。本文较详细地讨论了该图解的绘制方法及应注意的问题。运用该图解，将北京西山下苇甸剖面张夏组划分为１个大的三级旋回层序和４个四级旋回层序，根据图解反映的相对海平面变化讨论了旋回层序与构造运动间的关系，提出华北板块晚寒武世之前的＂翘翘板运动＂应始于中寒武世张夏期之早期到中期。

可溶性聚酰亚胺的电化学行为

The electrochemical behaviour of five soluble polyimides was studied in organic solution using cyclic voltammetry. The relationship between the electrochemical behaviour and the molecular structure was discussed. It was found that the colours of polyimides can be changed due to the electrochemical redox reactions.

新疆阿克苏—巴楚地区寒武—奥陶纪海平面变化与旋回层序的形成

通过研究新疆阿克苏巴楚地区寒武奥陶系沉积特征、层序地层序列及其海平面变化规律，首次识别出２个二级旋回层序、４个三级旋回层序和９个四级旋回层序。重点对三级旋回层序的层序界面性质及其体系域特点进行了深入、细致的分析。研究表明，每一旋回层序的形成，理论上均由海平面相对快速上升、缓慢上升、静止、缓慢下降和快速下降所引起，但实际情况较之复杂。海平面上升的最大幅度发生在丘里塔格晚期—吐木休克早期，之后由于构造运动和全球海平面下降，该区海平面亦快速下降，海水迅速退出本区。

卵胎生硬骨鱼褐菖鲉卵巢的周期发育研究

经组织学观察表明 ,褐菖鲉 (Sebastiscusmarmoratus)的卵巢由卵巢壁、卵巢绒毛和卵巢腔构成。卵巢壁的肌层较厚 ,卵巢上皮具分泌功能。卵巢绒毛位于卵巢腔中 ,呈树枝状。在卵巢绒毛上分布着滤泡。滤泡由卵母细胞和滤泡膜构成。滤泡膜包括内层的颗粒层和外层的鞘膜层。鞘膜层上有丰富的毛细血管。滤泡靠滤泡柄悬挂在卵巢绒毛上。卵巢发育分 7个时期。成熟卵排放在卵巢腔中受精。胚胎浸置在卵巢液中发育。卵巢发育、卵巢成熟系数和卵巢壁厚度随季节呈年周期变化。

重型颅脑损伤合并缺血缺氧后氨基酸谱改变

目的 :研究重型颅脑损伤 (SHI)合并缺血、缺氧时脑组织谷氨酸 (Glu)及环核苷酸代谢的改变及临床意义。方法 :在 SD大鼠弥漫性脑损伤模型基础上 ,制成 SHI合并低血压及脑缺血模型。通过氨基酸分析仪与放射免疫法测定伤后不同时间脑组织 Glu、c AMP和 c GMP含量。结果 :SHI后 10分钟 ,Glu明显增加〔(19.0±0 .9)μmol/ g(P<0 .0 1)〕,随后逐渐下降 ,并于 2 4小时达最低点〔 (6 .5± 1.0 )μmol/ g〕,72小时组出现回升趋势 ,但仍维持低水平 ;SHI后 2 4小时 c AMP下降至 (5 .7± 1.9) nm ol/ g(P <0 .0 5 ) ,c GMP则升高到 (1.1±0 .3) nm ol/ g(P<0 .0 1) ,c AMP/ c GMP比值下降到 (5 .0± 1.0 ,P<0 .0 5 ) ;SHI合并缺血、缺氧后 ,上述指标变化更加明显。结论 :在 SHI合并缺血、缺氧后 ,脑组织 Glu、c AMP和 c GMP含量发生显著变化 ,上述氨基酸谱的改变所引起的神经细胞兴奋毒性和代谢性应激反应是加重继发性脑损害的关键因素。

塔里木盆地K_2-E旋回层序与海平面变化

塔里木盆地西南缘Ｋ２－Ｅ海相含碳酸盐岩地层中可识别出七种类型的高频旋回层序，主要有潮下缓坡型、台地型、台地边缘型碳酸盐旋回层序及以碎屑岩为主的潮间－潮上型旋回层序。平面上，不同类型高频旋回层序成为特定古地理背景下台地碳酸盐沉积体系、滨岸沉积体系和冲积沉积体系沉积层序的代表。纵向上，各类高频旋回层序的有序叠加，其类型的变化反映了沉积环境、沉积相的演变过程。研究结果表明，研究区各类高频旋回层序下部单元至上部单元微相的转变是受高频率海平面变化的影响，低频率海平面升降控制了高频旋回层序的叠加形式，造成沉积环境由下至上滨岸→碳酸盐台地→滨岸→河流的变化。正是由于不同周期海平面变化旋回的叠加形成了塔里木盆地西南缘Ｋ２－Ｅ的复合海平面变化旋回层序。