interplanetary spacecraft

简明释义

行星际宇宙飞船

英英释义

例句

1.The interplanetary spacecraft is designed to travel between planets in our solar system.

这艘星际飞船旨在在我们太阳系的行星之间旅行。

2.The interplanetary spacecraft will be equipped with advanced technology for deep space exploration.

这艘星际飞船将配备先进技术，用于深空探索。

3.Scientists are studying the data collected by the interplanetary spacecraft to understand other planets better.

科学家们正在研究这艘星际飞船收集的数据，以更好地了解其他行星。

4.An interplanetary spacecraft can take years to reach its destination, depending on the distance.

一艘星际飞船到达目的地可能需要数年时间，这取决于距离。

5.NASA is developing a new interplanetary spacecraft for future missions to Mars.

美国宇航局正在开发一艘新的星际飞船，用于未来的火星任务。

作文

In the vast expanse of our solar system, the exploration of other planets has always been a subject of fascination for scientists and enthusiasts alike. The development of interplanetary spacecraft (星际航天器) has revolutionized our ability to explore these distant worlds. These sophisticated vehicles are designed to travel between planets, enabling us to gather invaluable data about their atmospheres, surfaces, and potential for supporting life.The first successful interplanetary spacecraft (星际航天器) was Mariner 2, which flew by Venus in 1962. This mission marked a significant milestone in space exploration, demonstrating that we could send machines to other planets and receive data back on Earth. Since then, numerous missions have followed, including the Voyager probes, which provided us with a wealth of information about the outer planets and beyond.One of the most remarkable aspects of interplanetary spacecraft (星际航天器) is their ability to operate autonomously. Given the vast distances involved, communication delays can range from minutes to hours. Therefore, these spacecraft must be equipped with advanced technology that allows them to make decisions without immediate input from mission control. This autonomy is crucial for navigating through the harsh environments of space and for conducting scientific experiments.Another important feature of interplanetary spacecraft (星际航天器) is their propulsion systems. Traditional rocket engines are not efficient for long-distance travel, so engineers have developed various innovative propulsion methods. For instance, ion propulsion systems use electricity to accelerate ions, providing a continuous thrust over extended periods. This allows interplanetary spacecraft (星际航天器) to reach high speeds and cover vast distances more efficiently than conventional chemical rockets.The scientific instruments aboard interplanetary spacecraft (星际航天器) are also essential for gathering data. These instruments can include cameras, spectrometers, and environmental sensors, all designed to analyze the composition of planetary surfaces and atmospheres. For example, the Mars rovers, such as Curiosity and Perseverance, are equipped with state-of-the-art tools that allow them to conduct detailed geological studies and search for signs of past life on the Red Planet.As we look to the future, the role of interplanetary spacecraft (星际航天器) will only become more critical. Missions to Mars are already being planned, with the goal of sending humans to the planet within the next few decades. Additionally, the concept of sending interplanetary spacecraft (星际航天器) to other star systems is being explored, although this remains a daunting challenge given the current limitations of our technology.In conclusion, the development of interplanetary spacecraft (星际航天器) has opened up new frontiers in our quest to understand the universe. Through their autonomous capabilities, innovative propulsion systems, and advanced scientific instruments, these spacecraft have provided us with insights into the nature of our solar system and beyond. As we continue to push the boundaries of space exploration, interplanetary spacecraft (星际航天器) will play a pivotal role in unlocking the mysteries of the cosmos and potentially discovering new worlds that may harbor life.

在我们太阳系的广阔空间中，探索其他行星一直是科学家和爱好者的迷人话题。星际航天器（interplanetary spacecraft）的发展彻底改变了我们探索这些遥远世界的能力。这些复杂的飞行器旨在在行星之间旅行，使我们能够收集有关它们的气氛、表面和支持生命的潜力的宝贵数据。第一个成功的星际航天器（interplanetary spacecraft）是1962年飞掠金星的马林纳2号。这次任务标志着太空探索的重要里程碑，证明我们可以将机器送往其他行星并接收回地球的数据。从那时起，许多任务相继开展，包括旅行者探测器，它们为我们提供了关于外行星及更远地区的大量信息。星际航天器（interplanetary spacecraft）最显著的特点之一是它们能够自主操作。考虑到涉及的巨大距离，通信延迟可能从几分钟到几个小时不等。因此，这些航天器必须配备先进技术，使其能够在没有来自任务控制中心的即时输入的情况下做出决策。这种自主性对于在太空恶劣环境中导航和进行科学实验至关重要。星际航天器（interplanetary spacecraft）的推进系统也是收集数据的重要特征。传统的火箭发动机对于长途旅行并不高效，因此工程师们开发了各种创新的推进方法。例如，离子推进系统利用电力加速离子，提供持续的推力。这使得星际航天器（interplanetary spacecraft）能够以更高的速度和效率覆盖更广泛的距离，而不是依赖常规化学火箭。搭载在星际航天器（interplanetary spacecraft）上的科学仪器对于收集数据也至关重要。这些仪器可以包括相机、光谱仪和环境传感器，旨在分析行星表面和大气的成分。例如，火星探测车，如好奇号和毅力号，配备了最先进的工具，使其能够进行详细的地质研究并寻找红色星球上过去生命的迹象。展望未来，星际航天器（interplanetary spacecraft）的作用将变得更加重要。对火星的任务已经在计划中，目标是在未来几十年内将人类送往该星球。此外，向其他恒星系统发送星际航天器（interplanetary spacecraft）的概念正在被探索，尽管鉴于我们当前技术的限制，这仍然是一项艰巨的挑战。总之，星际航天器（interplanetary spacecraft）的发展为我们理解宇宙开辟了新领域。通过它们的自主能力、创新的推进系统和先进的科学仪器，这些航天器为我们提供了关于我们太阳系及更远地区的本质的见解。随着我们继续推动太空探索的边界，星际航天器（interplanetary spacecraft）将在揭示宇宙的奥秘和潜在发现可能拥有生命的新世界方面发挥关键作用。