6 research outputs found
The Influence of Political Connection and Institutions to the Performance and Bank Loans of Private Listed Companies
我国有着不同于西方发达国家的制度背景和政治制度,政府对市场的管制力度较大,上市公司的高管具有一定的政治背景,其中国有企业本身大股东的政府背景性质,其政治关联很可能是与生俱来的,而民营企业政治关联的形成则具有主动性。改革开放以来,民营经济不断发展壮大,己成为我国经济增长的主要推动力量,因此,研究政治关联对民营公司的影响这一问题在中国更具有现实启发意义。 本文以民营上市公司的高级管理人员是否是前任或现任的政府官员、人大代表或政协委员来衡量公司是否具有政治关联,选取2004年—2008年中国沪深两市所有A股民营上市公司为样本,实证研究了政治关联与制度环境对民营上市公司经营绩效和银行贷款的影响。研究...Chinese current institution and political system are different from the Western developed countries. Under this system, many executives of private listed companies are relevant to politics. Therefore the study of political influence of private companies related to this issue in China is more realistic instructive. This paper focuses on whether the company has the political connection, which measu...学位:管理学硕士院系专业:管理学院财务学系_财务学学号:1762007115174
Experimental apparatus to study crystal channeling in an external SPS beamline
For the new generation of high intensity hadronic machines as, for instance, LHC, halo collimation is a necessary
issue for the accelerator to operate at the highest possible luminosity and to prevent the damage of superconductor
magnets.1 We propose an experiment aimed to a systematic study of channeling phenomenology and of the
newly observed \volume re
ection" eect. This experiment will be performed in an external SPS beamline and
will make use of a primary proton beam with 400 GeV=c momentum and a very small ( 3 rad) divergence. An
advantage of the proposed experiment is precise tracking of the particles that interacted with the crystal, so that
to determine single-pass eciencies for all the processes involved. For the purpose, a telescope equipped with
high-resolution silicon microstrip detectors will be used. New generation silicon crystals and an extra-precise
goniometer are mandatory issues. Main goal of the experiment is the achievement of precise information on
channeling of relativistic particles and, ultimately, on the feasibility of such technique for halo collimation in the LHC. In this contribution we review the status of the setting-up of the experimental apparatus and its future
development in sight of the planned run in September 2006
Experimental apparatus to study crystal channeling in an external SPS beamline
For the new generation of high intensity hadronic machines as, for instance, LHC, halo collimation is a necessary issue for the accelerator to operate at the highest possible luminosity and to prevent the damage of superconductor magnets. We propose an experiment aimed to systematic study of the channeling phenomenology and of the newly observed "volume reflection" effect. This experiment will be performed for an external SPS beamline and will make use of a primary proton beam with 400 GeV/c momentum and very small ( 3c 3 \u3bc rad) divergence. The advantage of a proposed experiment is precise tracking of particles that interacted with a crystal, so that to determine the single-pass effciency for all the processes involved. For this purpose, a telescope equipped with high-resolution silicon microstrip detectors will be used. New generation silicon crystals and an extra-precise goniometer are mandatory issues. Main goal of the experiment is to get the precise information on channeling of relativistic particles and, ultimately, on the feasibility of such technique for halo collimation at LHC. In this contribution we review the status of the setting-up of experimental apparatus and its future development in sight of the planned run in September 2006
High-EfficiencyVolume Reflection of an Ultrarelativistic Proton Beam with a Bent Silicon Crystal
The volume reflection phenomenon was detected while investigating 400 GeV proton interactions with bent silicon crystals in the external beam H8 of the CERN Super Proton Synchrotron. Such a process was observed for a wide interval of crystal orientations relative to the beam axis, and its efficiency exceeds 95%, thereby surpassing any previously observed value. These observations suggest new perspectives for the manipulation of high-energy beams, e.g., for collimation and extraction in new-generation hadron colliders, such as the CERN Large Hadron Collider