Mingsheng Li , Yifei Sun , Xianguo Xu , Shaozhi Zhang
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引用次数: 0
摘要
过冷液氮和氮浆经常被考虑用于高速冷却,但其制备和维护并不容易。为解决这一问题,我们设计了一种独特的装置,利用液氮制备过冷液态氩(SLA)。对冷却过程进行了数学建模,以预测制备时间。如果液氮和液氩之间的夹层空间充满氮气,液氩可在一小时内冷却到 3.5 K 的过冷度。如果层间充入空气,则需要两个小时才能达到相同的过冷度。制备 600 mL 3.5 K SLA 需要额外的 1000 mL LN。在 3 毫米至 6 毫米的毛细石英管中重复进行了 3 微升微滴的冷却测试,以评估 SLA 的潜力。结果发现,微滴在 3.5 K 过冷 SLA 中的冷却速度与在 3 K 过冷 LN 中的冷却速度非常接近,高于在饱和 LN 中的冷却速度。SLA 易于制备和维护,是生物材料低温保存的理想选择。
Preparation of subcooled liquid argon and test of its cooling ability
Subcooled liquid nitrogen and nitrogen slush are often considered for high-speed cooling, but their preparation and maintenance are not easy. To address this issue, a unique device was designed to prepare subcooled liquid argon (SLA) using liquid nitrogen (LN). The cooling process was mathematically modeled to predict the preparation time. If the interlayer space between LN and liquid argon is filled with nitrogen gas, liquid argon could be cooled to 3.5 K subcooling within 1 h. If the interlayer is filled with air, 2 h are required to achieve the same subcooled state. An additional 1000 mL of LN was required for the preparation of 600 mL of 3.5 K SLA. The cooling tests of 3 μL microdroplets in 3 mm–6 mm capillary quartz tubes were duplicated to evaluate the potential of SLA. It was found that the cooling rate of microdroplet in the 3.5 K subcooled SLA is very close to that in the 3 K subcooled LN, higher than that in the saturated LN. The convenience of preparation and maintenance of SLA can make it good choice of cryogen for cryopreservation of biomaterials.
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