laboratory scale
简明释义
实验室规模;
英英释义
例句
1.The researchers conducted the experiment on a laboratory scale 实验室规模 to test the new chemical reaction.
研究人员在
2.Before scaling up, it's essential to validate the results obtained at the laboratory scale 实验室规模.
在放大之前,验证在
3.Our team is focused on optimizing processes at the laboratory scale 实验室规模 before moving to industrial production.
我们的团队专注于在
4.They successfully demonstrated the feasibility of the project on a laboratory scale 实验室规模.
他们成功地在
5.The pharmaceutical company developed its drug candidates using laboratory scale 实验室规模 synthesis methods.
制药公司使用
作文
The concept of laboratory scale refers to the small-scale experiments and processes that are conducted in a controlled environment, typically within a laboratory setting. This practice is essential in various fields such as chemistry, biology, and engineering, where researchers aim to understand complex phenomena before scaling up their findings for industrial applications. Conducting experiments on a laboratory scale allows scientists to manipulate variables more easily and observe the effects in a more manageable context.One of the primary advantages of working on a laboratory scale is the ability to minimize costs and resources. For instance, when developing a new pharmaceutical drug, researchers begin by synthesizing compounds in small quantities to test their efficacy and safety. By doing so, they can identify promising candidates without the need for extensive investment in large-scale production facilities. This approach also reduces waste and environmental impact, as only small amounts of materials are used during the initial phases of research.Furthermore, experiments conducted on a laboratory scale allow for greater precision and control. In a laboratory, conditions such as temperature, pressure, and concentration can be meticulously regulated, enabling researchers to isolate specific factors that may influence their results. This level of control is often unattainable in larger-scale operations, where external variables can introduce significant variability into the outcomes.In addition to cost-effectiveness and precision, the laboratory scale enables researchers to innovate and explore new ideas without the constraints typically associated with larger projects. The freedom to experiment with novel concepts or techniques can lead to groundbreaking discoveries that would otherwise remain undiscovered in a more rigid industrial setting. For example, many scientific breakthroughs have emerged from simple experiments conducted at the laboratory scale, ultimately leading to advancements in technology and medicine.However, it is essential to recognize that findings obtained from laboratory scale experiments do not always translate seamlessly to larger-scale applications. While researchers can control many variables in a lab, real-world conditions can be far more complex. Therefore, after successful trials at the laboratory scale, further testing and scaling up are necessary to ensure that the results are applicable in practical scenarios. This transition phase is crucial, as it often reveals challenges that were not apparent during initial experiments.Moreover, the importance of collaboration in research cannot be overstated. Many breakthroughs arise from the collective efforts of interdisciplinary teams who bring diverse perspectives to the table. When working on a laboratory scale, collaboration becomes even more vital, as different expertise can enhance the quality and scope of the research. For example, chemists, biologists, and engineers may work together to develop new materials or processes, leveraging each other's strengths to achieve common goals.In conclusion, the laboratory scale is a fundamental aspect of scientific research that facilitates exploration, innovation, and discovery. By allowing researchers to conduct controlled experiments with minimal resources, it plays a critical role in advancing knowledge across various disciplines. While the transition from laboratory scale to larger applications presents its own set of challenges, the insights gained from these small-scale studies are invaluable in shaping the future of science and technology. As we continue to face global challenges, the significance of research conducted at the laboratory scale will undoubtedly remain a cornerstone of progress.
“实验室规模”的概念指的是在受控环境中进行的小规模实验和过程,通常是在实验室环境中进行。这种做法在化学、生物学和工程等多个领域至关重要,研究人员旨在理解复杂现象,然后将其发现扩大到工业应用。以实验室规模进行实验使科学家能够更轻松地操控变量,并在更易管理的背景下观察效果。在实验室规模工作的一大主要优势是能够最小化成本和资源。例如,在开发新药时,研究人员首先合成少量化合物,以测试其有效性和安全性。通过这样做,他们可以在不需要大量投资于大规模生产设施的情况下识别出有前途的候选药物。这种方法还减少了浪费和环境影响,因为在研究的初始阶段只使用了少量材料。此外,在实验室规模进行的实验允许更高的精确度和控制。在实验室中,可以仔细调节温度、压力和浓度等条件,使研究人员能够隔离可能影响结果的特定因素。这种控制水平在大型操作中往往是无法实现的,因为外部变量可能会为结果引入显著的变异性。除了成本效益和精确性之外,实验室规模还使研究人员能够创新并探索新想法,而不受通常与大型项目相关的限制。自由尝试新概念或技术的机会可以导致突破性的发现,这些发现如果不在更严格的工业环境中进行,可能会被忽视。例如,许多科学突破都是通过在实验室规模进行的简单实验获得的,最终导致技术和医学的进步。然而,必须认识到,从实验室规模实验中获得的发现并不总是无缝地转化为更大规模的应用。虽然研究人员可以控制实验室中的许多变量,但现实世界的条件可能复杂得多。因此,在实验室规模成功试验之后,进一步测试和放大是必要的,以确保结果在实际场景中的适用性。这一过渡阶段至关重要,因为它通常揭示了在初步实验中未明显出现的挑战。此外,研究中合作的重要性不可低估。许多突破源于跨学科团队的集体努力,他们带来了多样的视角。在实验室规模工作时,合作变得更加重要,因为不同的专业知识可以提升研究的质量和范围。例如,化学家、生物学家和工程师可能会共同努力开发新材料或过程,利用彼此的优势来实现共同目标。总之,实验室规模是科学研究的一个基本方面,它促进了探索、创新和发现。通过让研究人员以最小的资源进行受控实验,它在推动各个学科的知识进步中发挥着关键作用。尽管从实验室规模过渡到更大应用呈现出自身的一系列挑战,但从这些小规模研究中获得的见解在塑造科学和技术的未来中是无价的。随着我们继续面临全球挑战,在实验室规模进行的研究的重要性无疑将继续成为进步的基石。
相关单词
