simulant

简明释义

[ˈsɪmjʊlənt][ˈsɪmjulənt]

n. 模拟物;相似物

adj. 模拟的

英英释义

A simulant is a substance or material that imitates the appearance or properties of another substance, especially in order to deceive or substitute for the original.

模拟物是一种模仿另一种物质外观或性质的物质,尤其是为了欺骗或替代原物。

单词用法

simulant substance

模拟物质

simulant behavior

模拟行为

simulant model

模拟模型

chemical simulant

化学模拟物

biological simulant

生物模拟物

simulant for testing

测试用的模拟物

同义词

simulator

模拟器

The flight simulator provides a realistic training environment for pilots.

飞行模拟器为飞行员提供了一个真实的训练环境。

replica

复制品

The museum displayed a replica of the ancient artifact.

博物馆展出了古代文物的复制品。

imitation

仿制品

The designer created an imitation of the famous handbag.

设计师制作了一个著名手袋的仿制品。

counterfeit

伪造品

The counterfeit money was detected by the bank's security system.

伪造的钱被银行的安全系统检测出来了。

反义词

real

真实的

The painting was confirmed to be a real masterpiece.

这幅画被确认是一件真实的杰作。

genuine

真正的

She wanted a genuine leather bag, not a fake one.

她想要一个真正的皮革包,而不是一个假的。

例句

1.During the simulant test of gears running - in, the wear type of samples are changed. The rules of the variety are gained.

摘要通过齿轮副跑合的模拟试验,得出齿轮副在跑合过程中磨损形式的转化规律。

2.This paper introduces a manual welding simulant trainer which is developed by the writer in order to provide learners of manual welding an auxiliary training.

本文介绍了一种由作者研制的手弧焊模拟训练装置,目的在于给手弧焊学习者提供辅助练习。

3.Value simulant results by computer show the system can be stabilized into different periodic orbits by using of the method, and testify this method is valid.

计算机仿真模拟结果显示,可以将系统稳定在不同的周期轨道,从而证明了所给方法的有效性。

4.In a Biological Safety Level 2 lab, scientists grow a batch of Erwinia Herbicola, a plant bacteria that is a simulant of a dangerous pathogen, but which itself is not dangerous.

在生物安全二级实验室,科学家成长的草生欧文氏菌,细菌,植物是一个危险的病原体模拟,分批但它本身并不危险。

5.Compared with the simulant control manner, the digital control manner can adopt much more agile control algorithms to control the feeder system.

同模拟控制方式相比,数字控制方式可以采用更加灵活多样的控制算法来对送丝系统进行控制。

6.A simulant platform of random movement of multiple objects is constructed with multiple threads method by the system.

系统采用多线程形式实现多物体随机运动模拟平台。

7.Simulant attenuator has been widely applied in microwave and radio networks with MMICS and PIN diode networks.

模拟衰减器在射频和微波网络中有广泛的应用,可用砷化镓mmics和PIN二极管网络实现。

8.The mathematical-simulant model system dis-cussed in the paper is put to practical use in a regional education programming.

文中提出数学-模拟模型体系,已在重庆地区的教育规划研究项目中得到了实际的应用。

9.The flight simulator is a perfect simulant for pilots to practice emergency procedures.

飞行模拟器是一个完美的模拟物,供飞行员练习紧急程序。

10.In training exercises, military personnel often practice with a simulant that resembles real explosives.

在训练演习中,军事人员通常使用一种与真实炸药相似的模拟物进行练习。

11.The researchers used a chemical simulant to mimic the effects of the actual substance in their experiments.

研究人员使用一种化学模拟物来模拟实际物质在实验中的效果。

12.They developed a simulant for testing the durability of materials under extreme conditions.

他们开发了一种模拟物用于测试材料在极端条件下的耐久性。

13.Using a simulant can help scientists understand how pollutants behave in the environment.

使用模拟物可以帮助科学家了解污染物在环境中的行为。

作文

In recent years, the concept of a simulant has gained significant attention in various fields, particularly in science and technology. A simulant is essentially a substance or object that imitates the properties or behavior of another material. This concept is not only fascinating but also crucial in numerous applications, ranging from research to industrial processes. Understanding the role of simulants can provide valuable insights into how we study complex phenomena and develop new technologies.One of the most prominent examples of simulants can be found in the field of materials science. Researchers often use simulants to replicate the characteristics of rare or expensive materials. For instance, in the study of gemstones, scientists may employ synthetic stones as simulants to analyze how real gems react under certain conditions. This practice not only saves time and resources but also allows for a more ethical approach to research, as it reduces the need for mining natural resources.Moreover, the use of simulants extends beyond just physical materials. In the realm of computer simulations, simulants are crucial for modeling complex systems. For example, climate scientists often rely on simulants to predict weather patterns and assess the impact of climate change. By using these digital representations, researchers can run experiments that would be impossible or impractical in the real world, leading to more informed decisions regarding environmental policies.In healthcare, simulants play a vital role in training medical professionals. Medical schools frequently utilize simulants such as mannequins or virtual reality environments to teach students about surgical procedures and emergency response. These simulants provide a safe and controlled environment for learners to practice their skills without risking patient safety. As technology advances, the realism of these simulants continues to improve, making them even more effective as educational tools.Furthermore, the entertainment industry also utilizes simulants in various ways. In film and video game production, simulants can refer to special effects that mimic real-life phenomena. For instance, filmmakers might use CGI (computer-generated imagery) as a simulant to create explosive scenes or fantastical creatures that would be dangerous or impossible to produce in reality. This not only enhances the visual experience for audiences but also pushes the boundaries of creativity in storytelling.Despite the advantages of using simulants, there are also challenges associated with their application. The accuracy and reliability of a simulant can significantly impact the results of an experiment or simulation. If a simulant does not accurately represent the material or phenomenon it is intended to mimic, the conclusions drawn from studies may lead to erroneous outcomes. Therefore, it is essential for researchers and practitioners to carefully select and validate their simulants to ensure the integrity of their work.In conclusion, the concept of a simulant is integral to many scientific and practical applications. From materials science to medicine and entertainment, simulants allow us to explore, innovate, and learn in ways that would otherwise be impossible. As technology continues to evolve, the development of more sophisticated simulants will undoubtedly enhance our understanding of the world around us and drive progress across various disciplines. Embracing the potential of simulants can pave the way for future advancements and discoveries.

近年来,‘simulant’这一概念在科学和技术等多个领域引起了广泛关注。‘simulant’本质上是一种模仿另一种材料特性或行为的物质或物体。这个概念不仅令人着迷,而且在许多应用中至关重要,从研究到工业过程。理解‘simulants’的作用可以为我们研究复杂现象和开发新技术提供宝贵的见解。在材料科学领域,‘simulants’的一个显著例子是研究人员常常使用‘simulants’来复制稀有或昂贵材料的特性。例如,在宝石研究中,科学家可能会使用合成石作为‘simulants’来分析真实宝石在某些条件下的反应。这种做法不仅节省了时间和资源,还为研究提供了一种更具伦理的方法,因为它减少了对自然资源开采的需求。此外,‘simulants’的使用不仅限于物理材料。在计算机模拟领域,‘simulants’对于建模复杂系统至关重要。例如,气候科学家经常依赖‘simulants’来预测天气模式和评估气候变化的影响。通过使用这些数字表示,研究人员可以进行在现实世界中不可能或不切实际的实验,从而在环境政策方面做出更明智的决策。在医疗保健领域,‘simulants’在培训医疗专业人员中发挥着重要作用。医学院经常利用‘simulants’如模拟人或虚拟现实环境来教授学生外科手术程序和紧急响应。这些‘simulants’为学习者提供了一个安全和受控的环境,让他们可以练习技能而不会危及患者安全。随着技术的进步,这些‘simulants’的真实感不断提高,使其成为更有效的教育工具。此外,娱乐行业也以各种方式利用‘simulants’。在电影和视频游戏制作中,‘simulants’可以指模仿现实生活现象的特效。例如,电影制片人可能使用CGI(计算机生成图像)作为‘simulant’来创造爆炸场景或奇幻生物,这在现实中既危险又不可能。这不仅增强了观众的视觉体验,而且推动了讲故事的创造力界限。尽管使用‘simulants’具有诸多优势,但其应用也面临挑战。‘simulant’的准确性和可靠性会显著影响实验或模拟的结果。如果一个‘simulant’未能准确代表其意图模仿的材料或现象,那么从研究中得出的结论可能会导致错误的结果。因此,研究人员和从业者必须仔细选择和验证他们的‘simulants’,以确保其工作的完整性。总之,‘simulant’的概念对于许多科学和实际应用至关重要。从材料科学到医学和娱乐,‘simulants’使我们能够以其他方式探索、创新和学习。随着技术的不断发展,更复杂的‘simulants’的开发无疑将增强我们对周围世界的理解,并推动各个学科的进步。拥抱‘simulants’的潜力可以为未来的进步和发现铺平道路。