玻璃化

The distinct otherness in glass transition and devitrification temperature of five polyalcohols reflected the feebleness and po

保护剂在玻璃化转变温度和反玻璃化转变温度的明显差异，则反映它们在玻璃化能力方面的强与弱。

The distinct otherness in glass transition and devitrification temperature of five polyalcohols reflected the feebleness and power in the aspects of glass transition ability.

保护剂在玻璃化转变温度和反玻璃化转变温度的明显差异，则反映它们在玻璃化能力方面的强与弱。

Vitrification and devitrification tests of cryoprotectants demonstrated the feasibility of vitrification solution EDT.

在抗冻保护剂溶液的玻璃化与脱玻璃化试验中，证明了乙二醇、葡聚糖和海藻糖配制玻璃化溶液的可行性。

The changes of freezing point and super-cooling point of a series of PM vitrification solutions was investigated in the process of slow freezing at a ratio of 5℃/min. This experiment showed that the vitrification solution over 41% had not freezing point, while the vitrification solution under 40% had freezing point and could ice.

对PM系列玻璃化液在5℃/min慢速降温过程中冰点、过冷点的产生和变化进行研究，发现浓度在41%以上的玻璃化液降温时不产生冰点结晶，而40%以下玻璃化液在慢速降温时在冰点出现了结晶。

This effect is probably related to the interaction between amorphous PE in PP copolymer and PE phase in mPE and EPDM. T〓 of mPE decreases with increasing the octene content, and maximum damping of the glass transition relaxation increases.

PP／SEBS共混物中SEBS的玻璃化温度随SEBS含量的增加而降低，表明共聚PP中的PE相对SEBS中丁二烯嵌段的玻璃化松弛转变影响很小。mPE中的辛烯含量越高，其低温损耗峰的强度越高，玻璃化温度越低，低温韧性越好。

On the basis of the related essential glass transition theory,the main effects on glass transition temperature including composition,molecular weight and plasticization were debated.

在玻璃化转变的相关基础理论上，综述了影响玻璃化转变温度的主要因素，指出了玻璃化转变温度作为建立在动力控制过程的非平衡态基础上的物理化学参数，与水分含量和水分活度两重要指标相结合，可以用来解释干燥食品加工贮藏中引起食品腐败变质的各种动力学过程

The glass transition temperature from DMTA analysis revealed the glass transition temperature of the extragallery cured epoxy resin and was in relation to the curing temperatures. Addition of organophilic montmorillonite led to the disappearance of the α' peak of loss tangent of the nanocomposites.

DMTA测试表明，所测的玻璃化转变温度是层外固化环氧树脂的玻璃化转变温度，并发现二亚乙基三胺固化环氧树脂纳米复合材料的玻璃化转变温度与固化温度紧密相关，且加入蒙脱土后纳米复合材料的低温α'松弛峰消失。

Two-component waterborne polyurethane paint composed of acrylic dispersion and hydrophilically-modified polyisocyanate has fast dry time, good adhesion, flexibility, impact resistance, but poor water and chemical-resistance. The dry time becomes shorter with the increase of glass transition temperature and the decrease of acid value; the gloss of the film decreases with the increases of hydroxyl value, acid value and Tg of emulsion polymer; higher Tg polymer leads to harder film.

将制得的丙烯酸分散体与亲水改性多异氰酸酯组分配制水性双组分聚氨酯涂料，发现漆膜表干和实干比较快，干燥时间随玻璃化温度升高而缩短，随酸值的增加而增加；附着力、柔韧性和冲击强度比较好；光泽随分散体羟值、酸值的增加和玻璃化温度升高而降低；硬度随玻璃化温度升高而升高；较高的酸值使涂料的耐化学品性和耐水性较差，羟值在100mgKOH/g时较好，而酸值应尽可能低。

Based on this relationship, we can change the Tg of starch by changing its molecular weight to meet the pratical needs.The DSC technique is used to estimate the consistence character of starch with different additives. The glass transition behavious of starch blended with water and Xanthan gum are examined respectively. An expirical expression is obtained for the Tg of starch blendee with additives according to the blending model of polymers and verified with the experimental results. This expression can be used as a base to predict the Tg of starch blended with Xanthan gum.

采用DSC曲线分析法进行了各种填加剂与淀粉的相容性试验，考察了淀粉分别与水和黄原胶共混后体系的玻璃化转变行为，并根据高分子聚合物的共混模型对糯米淀粉与黄原胶共混物的玻璃化转变进行拟合，得到适用于此体系的经验关联式，并应用玉米等淀粉与黄原胶共混后的实验值进行验证，得到该关联式的有效性，为预测淀粉与黄原胶共混后的玻璃化温度值提供了理论依据。

The endurance abilities of the embryos of sea perch, flounder and turbot at different developing stages to vitrification solutions were studied. The result showed that sea perch at tail-bud stage, heart-beating stage and pre-hatching stage had more endurance abilities to VSD2, flounder at 4-5 somites, 16-20 somites and tail-bud stage had more endurance abilities to PM3, and turbot at 4-5 somites, 16-20 somites and tail-bud stage had more endurance abilities to PMP1. The feasible equilibration time of three marine fish embryos in vitrification solutions was determined, which guided the dealing process before freezing.

对花鲈、牙鲆、大菱鲆三种鱼类不同时期胚胎分别在玻璃化液中的适应性进行了研究，发现花鲈尾芽胚、心跳胚和出膜前期胚对VSD2的耐受能力较强；牙鲆4-5以肌节胚、16-20对肌节胚、尾芽胚对PM3的耐受能力较强，大菱鲆4—5对肌节胚、16—20对肌节胚、尾芽胚对PMP1的耐受能力较强，较适合于进行玻璃化液处理和冷冻保存；并且确定了三种鱼类各时期的胚胎在玻璃化液中的适宜平衡时间，为胚胎在玻璃化液中处理和冷冻提供了一定的参数。

semivitreous：半玻璃化/半玻璃化的/半玻璃态

semivalent /半正常价的/ | semivitreous /半玻璃化/半玻璃化的/半玻璃态/ | semivocal /半元音的/

semivitreous：半玻璃化的

semivitreous 半玻璃化 | semivitreous 半玻璃化的 | semivitreous 半玻璃态

glass transition temperature：玻璃化温度

(53)玻璃化温度(Glass transition temperature)无定形或半结晶聚合物从粘流态或高弹态向玻璃态转变(或相反的转变)的较窄温度范围的近似中点,称为玻璃化温度,通常以Tg表示,是耐热性的一个指标.

glass transition temperature：玻璃化转变温度

glass test tube 玻璃试管 | glass transition temperature 玻璃化转变温度 | glass transition 玻璃化转变

vitrifaction：玻璃化/透明化

vitrics /玻璃制品/玻璃状物质/ | vitrifaction /玻璃化/透明化/ | vitrifiable /可玻璃化的/

vitrification：玻璃化

玻璃化(vitrification)是指利用物理学原理将高浓度的抗冻保护剂急速降温后,由液态转化为外形类似玻璃状的稳定而透明的非晶体化固体状态的过程.玻璃化的固体保留了液体正常的分子和离子分布,可以视为一种无序黏稠的超冷液体,

vitrification point：玻化温度,玻璃化温度

vitrification 玻璃化 | vitrification point 玻化温度,玻璃化温度 | vitrification range 玻化范围

devitrifying glass：反玻璃化玻璃,消失透明玻璃

devitrify || 析晶,失透,反玻璃化 | devitrifying glass || 反玻璃化玻璃,消失透明玻璃 | devitroceram || 微晶玻璃,玻璃陶瓷

vitrified bond：玻璃化熔结

"vitrification","非晶质化,玻璃化" | "vitrified bond","玻璃化熔结" | "vitrified process","玻璃化熔结法"

vitrifying point：玻璃化点,玻化点

涂釉电阻器 vitrified resistor | 玻璃化 vitrify | 玻璃化点,玻化点 vitrifying point