Chandrayaan-2
Chandrayaan-2 is a spacecraft for lunar surface. It is
luched in 22nd Aug 2019 from ISRO center Krantak, India for get the
information of south pol Lunar “moon”.
Chandrayaan-2 traveled distance from earth to moon 3,84,000 km.
In spacecraft have three segments
In spacecraft have three segments
#Orbiter – 8 payloads
1. Terrain mapping camera 2 (TMC 2) - TMC 2 is a miniature
version of the Terrain Mapping Camera used onboard the Chandrayaan 1 mission.
Its primary objective is mapping the lunar surface in the panchromatic spectral
band (0.5-0.8 microns) with a high spatial resolution of 5 m and a swath of 20
km from 100 km lunar polar orbit. The data collected by TMC 2 will give us
clues about the Moon's evolution and help us prepare 3D maps of the lunar
surface.
2. X-ray Monitoring - CLASS measures the Moon's X-ray
Fluorescence (XRF) spectra to examine the presence of major elements such as
Magnesium, Aluminium, Silicon, Calcium, Titanium, Iron, and Sodium. The XRF
technique will detect these elements by measuring the characteristic X-rays
they emit when excited by the Sun's rays.
3. Large Area Soft X-ray Spectrometer (CLASS) - CLASS
measures the Moon's X-ray Fluorescence (XRF) spectra to examine the presence of
major elements such as Magnesium, Aluminium, Silicon, Calcium, Titanium, Iron,
and Sodium. The XRF technique will detect these elements by measuring the
characteristic X-rays they emit when excited by the Sun's rays.
4. Orbiter High-Resolution Camera (OHRC) - OHRC provides
high-resolution images of the landing site — ensuring the Lander's safe
touchdown by detecting any craters or boulders prior to separation. The images
it captures, taken from two different look angles, serve dual purposes.
Firstly, they are used to generate DEMs (Digital Elevation Models) of the
landing site. Secondly, they are used for scientific research, post-lander
separation. OHRC's images will be captured over the course of two orbits,
covering an area of 12 km x 3 km with a ground resolution of 0.32 m.
5. Imaging IR Spectrometer (IIRS) - Global mineralogical and
volatile mapping of the Moon in the spectral range of ~0.8-5.0 µm for the first
time, at the high resolution of ~20 nm
Ø
Complete characterization of water/hydroxyl
feature near 3.0 µm for the first time at high spatial (~80 m) and spectral
(~20 nm) resolutions
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IIRS will also measure the solar radiation
reflected off the Moon's surface in 256 contiguous spectral bands from 100 km
lunar orbit.
6. Dual Frequency Synthetic Aperture Radar (DFSAR) - The
dual frequency (L and S) SAR will provide enhanced capabilities compared to
Chandrayaan 1's S-band miniSAR in areas such as:
Ø
L-band for greater depth of penetration (About
5m — twice that of S-band)
Ø
Circular and full polarimetry — with a range of
resolution options (2-75 m) and incident angles (9°-35°) — for understanding
scattering properties of permanently shadowed regions
The main scientific objectives of this payload are:
Ø
High-resolution lunar mapping in the polar
regions
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Quantitative estimation of water-ice in the
polar regions
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Estimation of regolith thickness and its
distribution
7. Chandrayaan-2 Atmospheric Compositional Explorer 2 (CHACE
2) - CHACE 2 will continue the CHACE experiment carried out by Chandrayaan 1.
It is a Quadrupole Mass Spectrometer (QMA) capable of scanning the lunar
neutral exosphere in the mass range of 1 to 300 amu with the mass resolution of
~0.5 amu. CHACE 2's primary objective is to carry out an in-situ study of the
composition and distribution of the lunar neutral exosphere and its
variability.
8. Dual Frequency Radio Science (DFRS) - To study the
temporal evolution of electron density in the Lunar ionosphere. Two coherent
signals at X (8496 MHz), and S (2240 MHz) band are transmitted simultaneously
from satellite and received at ground based deep station network receivers.
#Vikram – 4 payloads
1. Radio Anatomy of moon Bound Hypersensitive ionosphere and
Atmosphere (RAMBHA) - The lunar ionosphere is a highly dynamic plasma
environment. Langmuir probes, such as RAMBHA, have proven to be an effective
diagnostic tool to gain information in such conditions. Its primary objective
is to measure factors such as:
Ø
Ambient electron density/temperature near the
lunar surface
Ø
Temporal evolution of lunar plasma density for
the first time near the surface under varying solar conditions
2. Chandra's Surface Thermo-physical Experiment (ChaSTE) -
ChaSTE measures the vertical temperature gradient and thermal conductivity of
the lunar surface. It consists of a thermal probe (sensors and a heater) that
is inserted into the lunar regolith down to a depth of ~10 cm. ChaSTE operates
in two modes:
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Passive mode operation in which continuous
in-situ measurements of temperature at different depths are carried out
Ø
Active mode operation in which temperature
variations in a set period of time, and the regolith's thermal conductivity
under contact, are estimated
3. Instrument for Lumar Seismic Activity (ILSA) - ILSA is a
triple axis, MEMS-based seismometer that can detect minute ground displacement,
velocity, or acceleration caused by lunar quakes. Its primary objective is to
characterise the seismicity around the landing site. ILSA has been designed to
identify acceleration as low as 100 ng /√Hz with a dynamic range of ±0.5 g and
a bandwidth of 40 Hz. The dynamic range is met by using two sensors — a
coarse-range sensor and a fine-range sensor.
#Praygan – 2
payloads.
1. Alpha Particle X-Ray Spectrometer (APXS) - APXS' primary
objective is to determine the elemental composition of the Moon's surface near
the landing site. It achieves this through X-ray fluorescence spectroscopy
technique, where X-ray or alpha particles are used to excite the surface. APXS
uses radioactive Curium (244) metal that emits high-energy, alpha particles —
as well as X-rays — enabling both X-ray emission spectroscopy and X-ray
fluorescence spectroscopy. Through these techniques, APXS can detect all major
rock-forming elements such as Sodium, Magnesium, Aluminium, Silica, Calcium,
Titanium, Iron, and some trace elements such as Strontium, Yttrium and
Zirconium.
2. Laser Induced Breakdown Spectroscope (LIBS) - LIBS' prime
objective is to identify and determine the abundance of elements near the
landing site. It does this by firing high-powered laser pulses at various
locations and analysing the radiation emitted by the decaying plasma.
#Passive Experiment – 1 Payload
1. Laser Retroreflector Array (LRA) - To understand the
dynamics of Earth's Moon system and also derive clues on the Lunar interior.

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