小鼠心肌梗死模型的建立及系统性评价

目的构建小鼠心肌梗死模型,并进行系统性评价。方法42只C57BL/6J小鼠分为两组:假手术组(n=8)和模型组(n=34)。采用挤心脏法结合冠状动脉左前降支(LCA)结扎建立小鼠心梗模型。术后24 h、3 d、7 d分别进行心动超声评价心功能,打开胸腔观察梗死情况;术后24 h留取心脏标本进行TTC染色明确梗死发生;术后3 d检测梗死区炎症标志基因表达情况;术后7 d进行HE染色并检测梗死区纤维化相关基因表达情况。结果与假手术组比,模型组小鼠可明确观察到左室前壁发白,TTC染色明确梗死区域,提示模型建立成功。术后心超可见模型组心功能显著下降,且随时间延长逐渐加重。术后3 d梗死区促炎基因TNF-α和MCP-1表达显著增加(P<0.05)。术后7 d HE染色见梗死区大量炎性细胞浸润,梗死区与非梗死区界线分明;梗死区纤维化基因FN和COL3A1表达显著增加(P<0.01)。结论成功建立小鼠心梗模型及其基本评价体系,可作为模型建立的标志性指标。

2-5 Efforts toward World Best Storage-ring-based Mass Spectrometry

Nuclear mass measurements provide valuable information on the nuclear binding energy which reflects the summed result of all interactions among its constituent protons and neutrons. The systematic and accurate knowledge of nuclear masses have wide application in many areas of subatomic physics ranging from nuclear structure and astrophysics to the fundamental interactions and symmetries depending on the achieved mass precision[1].

2-4 Principle of Isochronous Mass Spectrometry Using Two Time-of-flight Detectors

Isochronous mass spectrometry (IMS) in storage rings is a powerful tool for mass measurements of exotic nucle with very short half-lives down to several tens of microseconds, using a multicomponent secondary beam separated in-ight without cooling. However, the inevitable momentum spread of secondary ions limits the precision of nuclear masses determined by using IMS.

2-4 First Isochronous Mass Measurement in Neutron-rich Region at CSRe

Mass is one of the fundamental properties of atomic nuclei. Isochronous mass spectrometry (IMS), using astorage ring combined with an in-flight separator, has been shown to be a powerful tool for mass measurementof exotic nuclei[1]. Recently, masses of many proton-rich nuclides were accurately determined at the HIRFL-CSRfacility[2]. In this paper, we described the first isochronous mass measurement of neutron-rich nuclides at CSRe.This experiment was performed at the end of 2011. In the experiment, the primary beam of 86Kr28+ ions wasaccumulated and accelerated to an energy of 460.65 MeV/u in the synchrotron CSRm. The 86Kr28+ ions were fastextracted and focused on a 15 mm thick beryllium target which was placed at the entrance of the RIBLL2 (anin-flight fragment separator).

2-9 Half-life Measurement of 94mRu44+ at CSRe

A radioactive nucleus is characterized with an intrinsic half-life. However, for a nuclear species, the half-lives inneutral atoms could be very different from that in highly charged ions. The half-lives of some highly charged ionshave been directly measured at GSI for multiple motivations[1]. In the same case, the nuclear state(i:e the isomer)may be in the range of several tens of microseconds and their half-live can be measured using isochronous massspectrometry. The J = 8+ isomeric state in 94Ru was chosen to test this method. The half-life of this isomer is71 s [2] in neutral atoms, and the excitation energy is 2.64 MeV. The internal conversion coefficient of this decayin neutral atom is 0.335. So its half-life in the bare nucleus would be modified to be 94.78 s when the internalconversion channel is blocked.

2-8 SimCSR Program for the Simulation of the Isochronous Mass Spectrometry at the HIRFL-CSR

Until now, several isochronous mass spectrometry (IMS) experiments have been successfully performed usingvarious primary beams at the HIRFL-CSR and masses of both proton-rich and proton-deficient exotic nuclei havebeen measured. In order to improve the performance of the IMS experiments and to provide a reliable tool fordesigning and preparing the future experiments, a simulation code, named SimCSR is developed.Presently, six-dimension phase-space linear transmission theory is applied to simulate the transmission of ionsin the experimental storage ring (CSRe). The basic algorithm is Bf = MBi. The Bi and Bf are six-dimensionphase-space vectors of ions at the entrance and exit of each element of the CSRe lattice, respectively. M is a6-by-6-dimension first-order transfer matrix of each element. M is calculated using formulas described in Ref.[1]. Inthe simulations, the ring lattice is considered in detail, and the same magnetic setting as in our previous experimentwith 58Ni projectile fragments[2] is considered. The ions are assumed to circulate 300 turns inside the CSRe.

2-6 First Isochronous Mass Measurements with Two Time-of-Flight Detectors at CSRe

In conventional isochronous mass spectrometry (IMS), single time-of-flight (TOF) method is adopted to measurethe ions' revolution times in a storage ring which can then be used to calculate the ions' masses. However, themass-to-charge ratio (m=q) is only related to the revolution time (T) under the condition that is equal to taccording to the following equation:

Precision Velocity Measurement of Stored Ions for IMS at the CSRe

Isochronous mass spectrometry(IMS)at heavy-ion rings is a powerful tool for precision mass measurements of short-lived nuclei.In the conventional IMS,the masses are determined through precision measurements of revolution times.

2-5 Mass Measurements of Neutron-defcient Nuclides 79Y,81,82Zr,83,84Nb

The masses of neutron-defcient nuclides play a critical role in the calculation of astrophysical rapid proton-capture processes[1].Neutron-defcient nuclides with mass number∧around 80 are the last set of nuclides with unknown masses on the pathway of vp-process[2].The mass measurement of nuclides would be very useful.In 2016,masses of neutron-defcient nuclides 79Y,81Zr,82Zr,83Nb and 84Nb nuclei were precisely measured directly by the experimental storage-ring CSRe at Lanzhou.

2-7 Study of Zr-Nb Cycle in Astrophysical rp-process

At a certain high temperature,this cycle will be dominant and end the rp-process to heavier region[2].It provides an upper temperature limit for rp-process along the proton drip line to produce nuclides beyond A=84,including the light p nuclides of 92;94Mo,96;94Ru.The existence of Zr-Nb cycle is an important question in rp-process[2].α-separation energy(Sα)of 84Mo plays an important role in the formation of this cycle.A strong enhancement of 83Nb(p,α)reaction rate is due to a very low Sαof 84Mo[1].

2-6 Mass Prediction of Neutron-defcient N=Z Nuclides 78Y,80Zr,82Nb and 84Mo

We have reported the mass measurements of neutron-deficient nuclides 79Y,81;82Zr,83;84Nb in this year’s Annual Report.However,for the N=Z nuclides close to A=80,the yield is much lower and even if they can be produced,there is still great difficult to identify them because of their quite similar mass-to-charge ratio and revolution times.However,their mass are extremely important for rapid proton capture process,for example,80Zr and 84Mo are waiting points of rp-process.Their masses can greatly effect the reaction flow of proton capture on them and then the abundance of the heavier nuclides.In addition,the separation energy of 84Mo(determined by the mass of 80Zr and 84Mo)has a strong impact on the 83Nb(p,α)reaction rate and plays a key role in the formation of Zr-Nb Fig.

2-8 Direct Mass Measurements of Short-Lived A=2Z+3 Nuclides at CSRe

Nuclear mass is one of the fundamental quantity of atomic nucleus.The total binding energy of a nucleus derived from the related mass values reflects all the interactions among the constituting nucleons.Masses of short-lived A=2Z+3 nuclei of 112Sn projectile fragments have been measured at the experimental cooler storage ring CSRe,employing the Isochronous mass spectrometry(IMS).The experiment was conducted at the Heavy Ion Research Facility in Lanzhou at the beginning of 2016.The primary beam of 112Sn35+was accumulated in the synchrotron CSRm and accelerated to 467.91 MeV/u.Secondary beam were produced by impinging the high intensity 112Sn35+beam onto a 10 mm beryllium target which was located at the entrance of the radioactive beam line RIBLL2.The projectile fragments of 112Sn emerged from the target were then transmitted,separated in flight through RIBLL2 and finally injected into CSRe.

储存环中有效鉴别衰变事件的方法及在^(94m)Ru^(44+)寿命测量中的应用

兰州重离子加速器冷却储存环上的等时性质量谱仪是开展高电荷态、短寿命同核异能态衰变研究的理想装置。在短寿命高电荷态离子^(94m)Ru^(44+)的寿命测量实验中,我们直接观测到了^(94)Ru的8^(+)态isomer衰变到基态的过程。在观测时间窗口(20μs,180μs)范围内,鉴别出了49个衰变事件。为了能够鉴别出更多的衰变事件,研究了一种基于频谱幅度来指认衰变事件的方法。基于模拟结果,该方法可以有效鉴别(15μs,185μs)内的衰变事件。将新的鉴别方法应用到实验数据处理中,在(15μs,185μs)内,鉴别出了54个衰变事件。基于这54个衰变事件,计算得到^(94m)Ru^(44+)在实验室坐标系下的寿命为194(121)μs。新的寿命结果与之前的结果218(148)μs在误差范围内一致。

常规等时性质量测量中系统性偏差的实验研究

基于重离子储存环建立的等时性质谱术(IMS)是测量远离稳定线核素质量的有效工具。但是,采用常规IMS测量缺中子一侧的核素质量时,发现T_(z)=-1/2和T_(z)=-1核素的质量测量结果在宽时域范围内存在系统性偏差。本工作利用CSRe直线段上的双飞行时间(TOF)探测器,同时测量了循环离子的周期和速度。利用这些实验信息,对常规IMS质量测量中出现的系统性偏差进行了研究。发现系统偏差是由于储存的离子动量分布不对称以及储存环能量转变参数γt非恒定造成的。在离线数据处理时,发现通过限制动量接收度的大小,可以消除常规IMS质量测量中的系统偏差。这一结果对采用常规IMS进行质量测量具有重要参考价值和指导意义。

HIRFL-CSR上等时性质量测量进展

基于兰州重离子研究装置冷却储存环(HIRFL-CSR)发展了等时性质谱术(Isochronous mass spectrometry,IMS),高精度测量了一批短寿命原子核的质量并研究了核结构和核天体领域的相关物理问题。本文综述了IMS实验的原理和步骤,重点介绍了目前正在发展的双TOF探测器谱仪。利用双TOF质量谱仪在测量离子回旋周期的同时测量了离子的速度,用来修正实验结果,可以在很宽的动量接收度内实现高质量分辨,并消除离子动量分散带来的系统误差。双TOF等时性质谱术是全新的概念,需要针对性开发相关实验技术。我们建立了基于CSRe的模拟平台,研制了高性能TOF探测器并安装在CSRe直线段,进行了在线束流测试,发展了新的束流光学设置并进行优化,开发了实验数据处理方法并在做进一步优化,并对下一步工作进行了展望。

SiC复合吸波材料的研究进展

为了防治日益严重的电磁干扰问题,吸波材料的研发越来越引起人们的重视。SiC作为一种介电性能优秀的吸波材料,还具有出众的稳定性、高强度、耐腐蚀等优点,但也有着阻抗匹配不佳、吸波机制单一的缺点。将SiC与其他材料复合是进一步提高SiC材料吸波性能的重要手段。本文简要介绍了SiC的结构、吸波机制及影响因素,详细综述了不同维度的SiC复合材料的吸波性能,包括SiC纳米颗粒、SiC纳米线、三维SiC材料与金属材料、碳材料、陶瓷材料、高分子材料等不同种类材料复合,相比于单一的SiC材料,复合材料可以提高其介电性能、丰富吸收机制、优化阻抗匹配,进而提高吸波性能。最后展望了SiC基复合吸波材料的发展方向。

基于HIRFL-CSR测量丰中子重核质量的建议

丰中子重核区有大量原子核质量未知,迫切需要实验测量。我们建议,利用兰州重离子加速器研究装置HIRFL-CSR上的等时性质谱术,高精度测量204Pt等丰中子重核的质量。CSR质量测量实验中,在目标核产额尽可能高的前提下,需要每次注入都有多个离子同时储存到实验环CSRe中,才能针对逐次注入修正磁场晃动的影响,得到高精度测量结果。但在丰中子核区,当目标核产生截面非常低时,每次注入能储存到环中的离子数目太少。为了解决这个问题,我们提出了一种"混合厚度靶"的方法,在不明显改变目标核产额的情况下,显著增加同时储存在CSRe中的离子数,满足实验要求。模拟计算表明,在CSRe测量丰中子重核质量是可行的,并推荐了实验的设置。

放射性核素寿命计算方法的模拟研究

根据几种常用放射性核素的寿命计算方法,通过模拟数据研究了直接拟合法、对数时间法、极大似然法、观测时间受限时的极大似然法等四种寿命计算方法的适用范围。当观测时间不受限时,研究了在不同计数下寿命计算方法的适用范围。当观测时间受限时,研究了在不同观测时间窗口下寿命计算方法的适用范围。模拟中选用全剥离离子^(94m)Ru^(44+)作为目标核素,得到了不同计数及不同观测时间窗口下的寿命及其误差,并给出了四种方法的适用范围。^(94m)Ru^(44+)寿命的模拟结果与在兰州等时性质量谱仪上获得的实验结果在一倍标准偏差范围内一致,从而进一步验证了寿命计算方法的适用范围及模拟数据的可靠性。该模拟结果可为寿命测量实验设计提供理论依据和参考。