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Writer's pictureAagam sanghavi

ISRO’s X-ray Polarimeter Satellite

India’s space agency, ISRO, has taken a giant leap forward in the field of X-ray astronomy with the successful launch of the XPoSat mission in January 2024. This blog delves into the key aspects of this groundbreaking mission, drawing upon our recent conversation to provide a comprehensive understanding.

Mission Objectives: Piercing the Veil of X-rays

XPoSat, which stands for X-ray Polarimetry Satellite, isn’t just another satellite orbiting Earth. It’s a dedicated observatory with a focused mission: to study the properties of bright cosmic X-ray sources, particularly black holes and neutron stars. But why X-rays?

These enigmatic objects, the densest and most powerful in the universe, shroud themselves in intense gravity, making direct observation through visible light impossible. X-rays, however, pierce through these veils, offering a window into their behavior.

The Power of Polarization

XPoSat’s secret weapon lies in its ability to measure the polarization of X-rays. Imagine light waves as wiggling strings. In normal light, these strings wiggle in all directions. But when light becomes polarized, the wiggling is restricted to a single plane.

By analyzing the polarization of X-rays from celestial objects, XPoSat can unveil crucial information that would otherwise remain hidden. Here’s how:

  1. Magnetic Fields: The strength and direction of magnetic fields surrounding black holes and neutron stars can influence X-ray polarization. Studying this polarization helps us understand the complex magnetic environments around these objects.

  2. Emission Mechanisms: Different physical processes generate X-rays in these cosmic powerhouses. Analyzing polarization sheds light on these mechanisms, revealing the secrets behind X-ray emission.

  3. Accretion Disks: Black holes and neutron stars often feed on surrounding matter, forming swirling disks of gas and dust called accretion disks. Studying the polarization of X-rays from these disks can reveal their structure and dynamics.

Inside XPoSat: The Scientific Toolkit

To achieve its objectives, XPoSat carries two powerful scientific instruments:

  1. POLIX (Polarimeter Instrument in X-rays): This is the mission’s workhorse, designed to measure the degree and angle of polarization of X-rays in the medium energy range.

  2. XSPECT (X-ray Spectroscopy and Timing): XSPECT acts as a complementary instrument, providing data on the energy distribution of the X-rays. This helps scientists understand the composition of the objects emitting the X-rays.

Current Status and Future Discoveries

As of today (March 31, 2024), XPoSat is likely operational in its low-Earth orbit, diligently collecting data on cosmic X-ray sources. While the mission has a lifespan of about 5 years, it’s still early days for groundbreaking discoveries.

Scientific analysis is a meticulous process, involving data calibration, processing, and interpretation. However, the future looks bright. Here’s what we can expect:

New insights into the behavior of black holes and neutron stars, including their magnetic fields, emission mechanisms, and accretion disks.

Scientific publications detailing the findings from XPoSat, contributing significantly to the field of X-ray astronomy.

Potential discoveries that challenge our current understanding of these extreme objects.

The image of Cassiopia A captured by XPoSat

The Indian Contribution: A Testament to Ingenuity

XPoSat is a testament to ISRO’s growing prowess in space exploration. The mission highlights India’s capability to develop and launch sophisticated scientific satellites, contributing to our collective quest to unravel the mysteries of the universe.

This blog post is just the beginning of the XPoSat story. As the mission progresses and scientific discoveries unfold, we can be certain that XPoSat will continue to be a beacon of Indian scientific achievement, pushing the boundaries of our knowledge about the cosmos.

 
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