聚变温度

The gaseous impurities in the alloys were well controlled with the sum of C, N and O less than 500wppm. For the first time it was found the strong interaction between Cr-Ti-CON, which reduces the mobility of Ti and CON, enhancing high-temperature strength and the aging-hardening property, and keeping the cold-work induced hardening at higher temperature. Aging-hardening could increase the tensile strength of V-4Cr-4Ti by 30% and could be utilized at 00 C for better economical performane of a vanadium structure. Hydrogen release will occur for the alloys tensile loaded at room temperature, which will affect the safety of a vanadium structure due to the resulting dimensional instability. For hydrogen embrittlement, impact toughness and fracture toughness of the alloy showed higher sensitivity than the tensile test elongation,so the toughness should be used as a new standard for the assessment of the embrittlement. Vanadium alloys were easily oxidized in air.

合金的气体杂质含量得到有效控制，C、N、O总量低于500wppm；首次发现Cr-Ti-CON之间的强相互作用，它使Ti、CON的高温可移动性降低，提高合金的高温强度、增强时效强化特性、使冷加工强化保持到更高温度；时效强化可使V-4Cr-4Ti的强度提高30%，可在低温（00C）下应用，提高构件的经济性；室温下，钒合金在拉应力的作用下，存在着氢释放，带来部件使用中的尺寸不稳定性，影响构件安全；氢脆是钒合金聚变应用的一个关键问题，合金的冲击韧性和断裂韧性表现出比拉伸延伸率更强的氢脆敏感性，应作为评价合金氢脆行为的新标准。

The operating temperature range of the proton beam windows of future liquid metal spallation sources will be lower than that of the first wall of a fusion reactor.

操作温度范围内的质子束窗未来液态金属裂源将低于对第一壁的聚变反应堆。

A nuclear fusion reaction taking place at very high temperatures.

在极高温度下发生的一种核聚变反应。

By a theoretical model, influences from electron temperature, ion temperature, plasma flow and secondary electron emission are mainly analyzed.

主要讨论了电子温度、离子温度、等离子体流动以及二次电子发射对尘埃带电的影响；数值计算研究了尘埃带电的弛豫时间；在考虑了离子拖拽力作用下，估算了尘埃粒子在聚变装置中的运动速度；针对碳材料的尘埃理论计算得到了粒子的寿命。

Based on the source terms and fusion burn-up equations,a three-temperature plasma model is founded in which the electrons,ions,and the radiation filed are represented by separate temperatureskT_e,kT_i and kT_r,respectively,where kT_r is characterized by a Planckian distribution.

第四章建立了考虑α粒子慢化的两温模型和三温模型，首先导出了考虑慢化的α粒子对等离子体的能源项，替换已有的两温模型的等离子体能量密度方程中的能源项，将其改进为考虑α粒子慢化过程的两温模型，与瞬时沉积能量的两温模型作了对比，在不同的初始温度密度条件下考察了α粒子慢化对等离子体聚变燃烧的影响。

The study of the fusion-welding process covers various important aspects such as the metallurgical properties of the weldments, the effect of arc temperature on the development of post-weld residual stresses, distortion in the base material, the physics and behaviour of the arc with the formation and maintenance of the weld pool.

研究聚变-焊接过程涉及各种重要的方面，如冶金性能该焊接，其效果的电弧温度对发展焊后残余应力，变形在基地的材料，物理和行为电弧与形成和维持该焊缝池。

ABSTRACT In the experimental investigations of inertial confinement fusion , the laser-produced high-temperature plasmas contain very abundant information, such as the electron temperature, density, ionization, etc.

在惯性约束聚变实验研究中，激光打靶产生的高温等离子体包含着十分丰富的信息，如电子的温度、密度和离化度等。

A planet on the other hand is built up out of the dust that surrounds a star. When a star is formed there is still a disk of gas surrounding it. As this gas cools, it condenses and forms solid grains. These grain particles accrete into large bodies called planetesimals, which then collide and accrete to make protoplanets. These protoplanets evolve into planets like the planets in our own solar system.

行星演化与恒星不同：恒星形成之后，周边的气体尘埃云冷却之后凝结形成，成为行星雏形，众多小行星雏形聚合碰撞，演化成成熟的行星；没有内部的核聚变；质量超过木星13.6倍，就会产生核聚变，如果还未至木星86倍，尚处于棕矮星的阶段，将会向恒星演化；持久的核聚变需要足够大的质量来支撑，温度也不足支撑氢向氦的转变。

fusing point：熔化点,熔化温度点,聚变温度,聚变温度,熔点=>融点

fusing mixture 融剤 | fusing point 熔化点,熔化温度点,聚变温度,聚变温度,熔点=>融点 | fusing point test 熔点测定

fusion point：聚变温度

fusion plasma analysis 聚变等离子体分析 | fusion point 聚变温度 | fusion power 聚变能量

fusion reactor：热核反应堆

fusion reaction 热核反应 | fusion reactor 热核反应堆 | fusion temperature 聚变温度

fusion reactor：热核堆

fusion reaction 聚变反应 | fusion reactor 热核堆 | fusion temperature 聚变温度

fuzziness：不清晰

fusion temperature 聚变温度 | fuzziness 不清晰 | gaas 砷化镓

ignition：点火

惯性约束聚变的科学可行性研究走向聚变能源要历经三个里程碑阶段:* 得失相当(breakeven):聚变释放的能量等于触发聚变反应所输入的能量;* 点火(ignition):聚变能产生的速率足够快使等离子体维持在所要求的温度而不需要附加加热;

fusion piercing：热力穿孔,熔化穿孔

fusion phenomenon 融合现象 | fusion piercing 热力穿孔,熔化穿孔 | fusion point 熔点,核聚变温度,熔融点

thermonuclear reaction：热核反应

由于聚变反应须在极高温度下才能进行,故聚变反应又称热核反应(thermonuclear reaction)3.中子弹(neutron bomb)是利用氘氚聚变反应,产生高能中子杀伤人员的战术核武器.