# WT1190F > space debris that reentered in 2015 **Wikidata**: [Q21210774](https://www.wikidata.org/wiki/Q21210774) **Wikipedia**: [English](https://en.wikipedia.org/wiki/WT1190F) **Source**: https://4ort.xyz/entity/wt1190f ## Summary WT1190F is a piece of space debris that reentered Earth's atmosphere on November 13, 2015. It was discovered on February 18, 2013, by the Catalina Sky Survey and is classified as defunct artificial object in space. ## Key Facts - **Instance of**: Space debris (defunct artificial object or collection of such objects in space) - **Discovery date**: February 18, 2013 (discovered by the Catalina Sky Survey) - **Reentry date**: November 13, 2015 - **Orbital inclination**: 3.19670 degrees - **Mean anomaly**: 6.19095 degrees - **Orbital eccentricity**: 0.9372685 - **Argument of periapsis**: 314.04406 degrees - **Longitude of ascending node**: 311.55613 degrees - **Aliases**: 9U01FF6, UDA34A3, UW8551D, UWAIS - **Provisional designation**: WT1190F (preferred) ## FAQs ### Q: What is WT1190F? A: WT1190F is a piece of space debris that reentered Earth's atmosphere in 2015. It was discovered in 2013 and is classified as defunct artificial object in space. ### Q: When was WT1190F discovered? A: WT1190F was discovered on February 18, 2013, by the Catalina Sky Survey. ### Q: When did WT1190F reenter Earth's atmosphere? A: WT1190F reentered Earth's atmosphere on November 13, 2015. ### Q: What are the orbital characteristics of WT1190F? A: WT1190F has an orbital inclination of 3.19670 degrees, a mean anomaly of 6.19095 degrees, and an orbital eccentricity of 0.9372685. ### Q: What are the aliases of WT1190F? A: WT1190F is also known as 9U01FF6, UDA34A3, UW8551D, and UWAIS. ## Why It Matters WT1190F is significant as it represents a piece of space debris that reentered Earth's atmosphere, contributing to the ongoing study of orbital decay and atmospheric reentry. Its discovery and reentry provide valuable data for understanding the behavior of defunct artificial objects in space. The Catalina Sky Survey's role in its discovery highlights the importance of tracking space debris to ensure the safety of space operations and mitigate potential risks to satellites and spacecraft. ## Notable For - **First recorded reentry in 2015**: WT1190F was one of the first pieces of space debris to reenter Earth's atmosphere in 2015, providing insights into orbital decay. - **Discovered by Catalina Sky Survey**: The Catalina Sky Survey's discovery of WT1190F underscores the importance of ground-based observatories in tracking space debris. - **Orbital characteristics**: WT1190F's high orbital eccentricity and specific orbital parameters offer unique data for studying the dynamics of space debris. - **Multiple aliases**: WT1190F's various aliases reflect the complexity of tracking and identifying space debris in orbital catalogs. ## Body ### Discovery and Classification WT1190F was discovered on February 18, 2013, by the Catalina Sky Survey, a project aimed at discovering and tracking near-Earth objects. It was classified as space debris, specifically a defunct artificial object in space. ### Orbital Parameters WT1190F had an orbital inclination of 3.19670 degrees, a mean anomaly of 6.19095 degrees, and an orbital eccentricity of 0.9372685. These parameters indicate a highly elliptical orbit, typical of space debris. ### Reentry WT1190F reentered Earth's atmosphere on November 13, 2015. Its reentry provided valuable data on the behavior of space debris during atmospheric reentry, contributing to the broader understanding of orbital decay and space debris management. ### Aliases and Designations WT1190F is also known by the provisional designations 9U01FF6, UDA34A3, UW8551D, and UWAIS. These multiple designations reflect the complexity of tracking and identifying space debris in orbital catalogs. ### Significance WT1190F's reentry and discovery highlight the importance of monitoring space debris to ensure the safety of space operations and mitigate potential risks to satellites and spacecraft. Its orbital characteristics and reentry behavior offer unique insights into the dynamics of space debris.