有限温度下轻介子的质量

研究有限温度下强子质量谱随温度的演化对于深入理解有限温量子色动力学和夸克胶子等离子体的性质至关重要,特别对它们的研究有助于人们确定QCD手征相变的阶和相变温度.线性σ模型是研究零温和有限温强子性质的重要有效场论模型之一,在U(2)×U(2)线性σ模型下,使用有限温场论的实时公式计算了轻介子σ、π、a、η的质量随温度变化的情况.计算结果表明,π、a、η介子的质量随着温度的升高而增加;σ介子的质量随温度的升高而下降.从质量谱上没有看到手征对称性恢复的迹象.

有限温下重夸克偶素的质量谱

使用薛定谔方程计算粲夸克偶素和底夸克偶素在温度0.8Tc^2Tc时的质量谱.我们的计算表明,随着温度的升高,夸克偶素的质量不断下降,直至分解.粲偶素的s波基态在T^1.2Tc时分解;而底偶素的s波基态直到T^2Tc时仍然处于束缚状态.

有限温各向异性SU(3)格点规范理论相结构研究

本文计算了有限温各向异性耦合 SU( 3 )格点规范模型的 Polyakov线到第三级 ,发现维数 D≥ 3时有层相存在 。

关于有限温SU(3)格点规范理论相结构问题的研究

应用变分累积展开方法研究SU(3)格点规范理论相结构,对有限温各向同性和异性SU(3)格点规范模型的Polyakov线,计算到第三级.结果表明:当维数D3时有层相存在,且在高温下夸克是解禁的.

有限温度下强超子-超子相互作用对中子星的影响

文章在相对论平均场的框架内研究了有限温度下强超子-超子(YY)相互作用对中子星物质的影响.结果表明,包含强YY相互作用后,(1)星体会被进一步的超子化;(2)星体最大质量变小而相应的半径变大.另一方面,随着温度的升高,YY项对中子星物质的主要影响迅速减弱.在高于约46MeV时,强YY项在中子星里的效果是可以忽略的.

浅谈甬温铁路建设与管理体制模式

甬温铁路是东南沿海铁路通道的组成部分,其管理体制关系到资产管理、运输组织方式、运输成本、职工生活等各个方面,直接影响企业的经济效益和经营机制。通过对国内既有铁路管理模式的分析及甬温铁路几种可行管理模式的优缺点分析,认为成立甬温铁路有限责任公司,并由铁道部控股的方案较为有利,但今后杭州—福州沿海大通道的管理模式还有待进一步研讨。

温氏建大型养猪基地

日前，广东华农温氏畜牧股份有限公司与连州市签下合约．计划投资3亿元在连州建设大型养猪基地。

超子-超子相互作用强度对热中子星内强子-夸克相变的影响

在RMFT和MIT口袋模型的框架内研究了超子-超子(YY)相互作用强度对中子星物质内强子-夸克相变的影响.研究发现,中子星内强子-夸克相变与YY相互作用强度是有关联的.弱YY相互作用使得中子星内更容易发生强子-夸克相变.强YY相互作用则使得中子星内超子含量增多.温度升高,YY相互作用强度的影响会减弱.

热白矮星的质量-半径关系

研究了有限温度条件下分别由Fe核和C核构成的热白矮星。结果表明随着温度升高,对应同一质量的白矮星的半径增加。温度对白矮星质量-半径关系的影响强度随着星体质量的增加而减弱。相比于Fe-白矮星,C-白矮星的质量-半径关系对温度的依赖程度较大。存在一个临界质量,当白矮星的质量小于这个临界值时,温度的影响将不能忽略。C-白矮星的临界质量为0.47_(sun),Fe-白矮星的临界质量为0.44M_(sun)。

Relationship between repeated triaxial test and Hamburg wheel tracking test on asphalt mixtures

Both the repeated triaxial test （RTT） and the Hamburg wheel tracking test （HWTT） are adopted to evaluate the high temperature performance of the stone mastic asphalt （SMA） and the mastic asphalt （MA）. The correlation of the permanent deformations of the MA and the correlation of the deformation developments of the SMA between the two tests are analyzed, respectively. Results show that both the two tests can effectively identify the high temperature performance of mixtures, and the correlation between the final results of the two tests as well as that between the deformation developments of the two tests are excellent with R20.9. In order to further prove the correlation, viscoelastic parameters estimated from the RTT results is used to simulate the rutting development in the HWTT slabs by the finite element method （FEM）. Results indicate that the correlation between the two tests is significant with errors less than 10%. It is suitable to predict the rutting development with the viscoelastic parameters obtained from the RTT.

Temperature Characteristics of Bilayer Thin-Film Devices Under Organic Interface Limited Current Conduction

Temperature characteristics are important for the performance of organic thin film devices. On the basis of the hopping theory of Miller-Abrahams,an analytical model of charge transport for bilayer organic devices under the organicorganic interface limited current conduction is developed. The dependence of current, field,and carrier distribution in bilayer organic devices with the structure of ＂injection electrode/Layer Ⅰ/Layer Ⅱ/collection electrode＂ on temperature are numerically analyzed. We conclude that, for a given applied voltage, when temperature is raised, the voltage of LayerⅠ will increase,and the field will be higher. Meanwhile, the voltage of Layer Ⅲ will decrease, the field will become weaker accordingly,and the current of the device will increase.

Calculation of effective temperature for pavement rutting using numerical simulation methods

In order to predict the long-term rutting of asphalt pavement, the effective temperature for pavement rutting is calculated using the numerical simulation method. The transient temperature field of asphalt pavement was simulated based on actual meteorological data of Nanjing. 24-hour rutting development under a transient temperature field was calculated in each month. The rutting depth accumulated under the static temperature field was also estimated and the relationship between constant temperature parameters was analyzed. Then the effective temperature for pavement rutting was determined based on the rutting equivalence principle. The results show that the monthly effective temperature is above 40 t in July and August, while in June and September it ranges from 30 to 40 Rutting development can be ignored when the monthly effective temperature is less than 30 t. The yearly effective temperature for rutting in Nanjing is around 38. 5 t. The long-term rutting prediction model based on the effective temperature can reflect the influences of meteorological factors and traffic time distribution.

有限空间温压共控热模拟油气产物地球化学特征

生烃反应是烃源岩在有限的地层孔隙空间内受温度、上覆地层静岩压力、地层孔隙流体压力等多种因素相互作用的过程,而热模拟实验是正演研究有机质生烃反应的常见手段。但较多的热模拟实验受仪器装置的限制,仅考虑了温度的作用,与实际地质演化存在较大差异。选取泌阳凹陷泌215井古近系核桃园组泥岩样品,分别进行了有限空间温压共控和温控热模拟实验,通过族组分、同位素、GC、GC-MS等方法分析了2种模拟实验条件下的油气产物。结果表明:①有限空间温压共控热模拟残留油饱和烃可以保存至较高的演化阶段;②相同模拟温度下,有限空间温压共控热模拟残留油的饱和烃参数Pr/Ph值、Pr/C17值大于温控热模拟实验,饱和烃生物标志物参数值C2920S/(20S+20R)、C29ββ/(αα+ββ)等小于温控热模拟实验;③有限空间温压共控热模拟的烃类气体δ^13C值大于温控模拟实验。上述现象主要是由于有限空间温压共控热模拟实验中高压孔隙流体的存在延缓了热成熟和原油裂解反应过程。因此,在开展热模拟实验研究时应考虑研究区是否发育超压、地层水等因素,其直接关系着热模拟实验结果的地质适用性。

Finite element analysis of pressure on 2024 aluminum alloy created during restricting expansion-deformation heat-treatment

Metals heat-treated under high pressure can exhibit different properties. The heat-induced pressure on 2024 aluminum alloy during restricting expansion-deformation heat-treatment was calculated by using the ABAQUS finite element software, and the effects of the mould material properties, such as coefficient of thermal expansion （CTE）, elastic modulus and yield strength, on the pressure were discussed. The simulated results show that the relatively uniform heat-induced pressure, approximately 503 MPa at 500 ℃, appears on 2024 alloy when 42CrMo steel is as the mould material. The heat-induced pressure increases with decreasing the CTE and the increases of elastic modulus and yield strength of the mould material. The influences of the CTE and elastic modulus on the heat-induced pressure are more notable.

STUDY OF FLOW AND TEMPERATURE IN RESIN TRANSFER MOLDING PROCESS BY NUMERICAL MODEL

A mathematical model of resin flow and temperature variation in the filling stage of the resin transfer molding (RTM) is developed based on the control volume/finite element method (CV/FEM). The effects of the heat transfer and chemical reaction of the resin on the flow and temperature are considered. The numerical algorithm of the resin flow and temperature variation in the process of RTM are studied. Its accuracy and convergence are analyzed. The comparison of temperature variations between experimental results and model predictions is carried out for two RTM cases. Result shows that the model is efficient for evaluating the flow and temperature variation in the filling stage of RTM and there is a good coincidence between theory and experiment.

Tunneling Conductance in Normal Metal/Insulator/Triplet Superconductor Junction

Tunneling conductance in normal metal/insulator/triplet superconductor junctions is studied theoretically as a function of the bias voltage at zero temperature and finite temperature. The results show there are zero-bias conductance peak, zero-bias conductance dip and double-minimum structures in the spectra for p-wave superconductor junctions. The existence of such structures in the conductance spectrum can be taken as evidence that the pairing symmetry of Sr2RuO4 is p-wave symmetry.

A Two-Dimensional Brans—Dicke Star Model with Exotic Matter and Dark Energy

A two-dimensional Brans-Dicke star model with exotic matter and dark energy is studied in this paper,the field equation and balance equation are derived at finite temperature,the analytic solutions of these equations canbe used to calculate the mass of star.In addition,we find that star's mass has a minimum when matter state parameterγ→0.

Numerical investigation of temperature gradient-induced thermal stress for steel–concrete composite bridge deck in suspension bridges

A3D finite element model(FEM)with realistic field measurements of temperature distributions is proposed to investigate the thermal stress variation in the steel–concrete composite bridge deck system.First,a brief literaturereview indicates that traditional thermal stress calculation in suspension bridges is based on the2D plane structure with simplified temperature profiles on bridges.Thus,a3D FEM is proposed for accurate stress analysis.The focus is on the incorporation of full field arbitrary temperature profile for the stress analysis.Following this,the effect of realistic temperature distribution on the structure is investigated in detail and an example using field measurements of Aizhai Bridge is integrated with the proposed3D FEM model.Parametric studies are used to illustrate the effect of different parameters on the thermal stress distribution in the bridge structure.Next,the discussion and comparison of the proposed methodology and simplified calculation method in the standard is given.The calculation difference and their potential impact on the structure are shown in detail.Finally,some conclusions and recommendations for future bridge analysis and design are given based on the proposed study.

Investigation on temperature field of unidirectional carbon fiber/epoxy composites during drilling process

The phenomenon of heat accumulation and transportation in the composite materials is a very typical and critical issue during drilling process.In this study,a three-dimensional temperature field prediction model is proposed using finite difference method,based on the partly homogenization hypothesis of material,to predict temperature field in the process of drilling unidirectional carbon fiber/epoxy(C/E)composites.According to the drilling feed motion,drilling process is divided into four stages to study the temperature distributing characteristics.The results show that the temperature distribution predicted by numerical study has a good agreement with the experimental results.The temperature increases with increasing the drilling depth,and the burn phenomena is observed due to the heat accumulation,especially at the drill exit.Due to the fiber orientation,an elliptical shape of the temperature field along the direction is found for both numerical and experimental studies of C/E composites drilling process.

Residual stress and welding distortion of Al/steel butt joint by arc-assisted laser welding-brazing

The thermo-elastic.plastic finite element method(FEM)is used to simulate the thermo-mechanical behavior of Al/steel tungsten inert gas(TIG)arc-assisted laser welding-brazing(A-LWB)butt joint.The influence of material nonlinearity,geometrical nonlinearity and work hardening on the welding process is studied,and the differences in the welding temperature field,residual stress and welding distortion by A-LWB and by single laser welding-brazing(SLWB)are analyzed.The results show that the thermal cycle,residual stress distribution and welding distortion by the numerical simulation are in good agreement with the measured data by experiments,which verifies the effectiveness of FEM.Compared with the SLWB,A-LWB can make the high-temperature distribution zone of weld in width direction wider,decrease the transverse tensile stress in the weld and reduce the distribution range of longitudinal tensile stress.And the welding deformation also decreases to some extent.