Final answer:
The Spitzer and Hubble Space Telescopes have significantly enhanced our understanding of star formation, showing it as a dynamic process that often involves interactions within stellar neighborhoods and disruption of the surrounding space.
Step-by-step explanation:
The study of star formation as observed through advanced telescopes such as the Hubble Space Telescope (HST) and the Spitzer Space Telescope (SST) is an aspect of astrophysics, a sub-discipline of physics. These telescopes have revolutionized our understanding of the universe. The HST, launched in 1990 and named after Edwin Hubble, offers observations of distant galaxies, identifying infancy structures with bright, clumpy star-forming regions, and providing a clearer view of the universe thanks to its corrected optics and lack of atmospheric distortion. The SST, launched in 2003, uses infrared imaging to show details like composition and temperature of various celestial phenomena, including regions of star formation, remnants of exploded stars, and regions where old stars are shedding their outer layers.
While early models assumed stars formed in isolation, the disruption seen through these space telescopes shows that stellar formation is a dynamic process. Stars form in clouds of gas and dust which collapse under gravity, often resulting in binary or multiple star systems due to fragmentation or gravitational binding. This corrected understanding highlights the interaction of stars with others in their stellar neighborhood, influenced by turbulent processes as evident in observations from these telescopes. SST's infrared data and HST's discoveries, such as MACHOs, circumstellar disks, and black hole candidates, underscore the complexities of star formation.