Cosmic Composition: According to the Lambda-CDM (Lambda-Cold Dark Matter) model, the universe is composed of approximately 68% dark energy, 27% dark matter, and only 5% ordinary (baryonic) matter.

Evidence for Dark Matter: Inferred from several phenomena, including anomalous galaxy rotation curves, gravitational lensing effects (bending of light around massive objects), the large-scale structure of the universe, and anisotropies in the Cosmic Microwave Background (CMB).

Role of Dark Matter: Provides the additional gravitational pull needed to hold galaxies and galaxy clusters together, and acts as a 'scaffolding' for the formation of cosmic structures.

Candidates for Dark Matter: Hypothetical particles such as Weakly Interacting Massive Particles (WIMPs), axions, or sterile neutrinos are leading candidates, but none have been directly detected yet.

Evidence for Dark Energy: Primarily derived from the accelerating expansion of the universe, observed through the redshift of distant Type Ia supernovae, which appear dimmer than expected.

Role of Dark Energy: Acts as a repulsive force, counteracting gravity and causing the universe's expansion to speed up over time. It is thought to be a property of space itself.

Nature of Dark Energy: Most commonly modeled as a cosmological constant (Einstein's 'Lambda' term, representing vacuum energy) or a dynamic field called quintessence.

Impact on Cosmology: Both dark matter and dark energy are essential components of the Standard Model of Cosmology, necessary to explain observed phenomena like the CMB, large-scale structure, and the universe's expansion history.

Ongoing Research: Numerous experiments worldwide (e.g., LUX, XENON, LHC) are dedicated to the direct detection of dark matter particles. Space missions (e.g., Euclid, Roman Space Telescope) are designed to map the distribution of dark energy and dark matter.

Cosmic Composition: According to the Lambda-CDM (Lambda-Cold Dark Matter) model, the universe is composed of approximately 68% dark energy, 27% dark matter, and only 5% ordinary (baryonic) matter.

Evidence for Dark Matter: Inferred from several phenomena, including anomalous galaxy rotation curves, gravitational lensing effects (bending of light around massive objects), the large-scale structure of the universe, and anisotropies in the Cosmic Microwave Background (CMB).

Role of Dark Matter: Provides the additional gravitational pull needed to hold galaxies and galaxy clusters together, and acts as a 'scaffolding' for the formation of cosmic structures.

Candidates for Dark Matter: Hypothetical particles such as Weakly Interacting Massive Particles (WIMPs), axions, or sterile neutrinos are leading candidates, but none have been directly detected yet.

Evidence for Dark Energy: Primarily derived from the accelerating expansion of the universe, observed through the redshift of distant Type Ia supernovae, which appear dimmer than expected.

Role of Dark Energy: Acts as a repulsive force, counteracting gravity and causing the universe's expansion to speed up over time. It is thought to be a property of space itself.

Nature of Dark Energy: Most commonly modeled as a cosmological constant (Einstein's 'Lambda' term, representing vacuum energy) or a dynamic field called quintessence.

Impact on Cosmology: Both dark matter and dark energy are essential components of the Standard Model of Cosmology, necessary to explain observed phenomena like the CMB, large-scale structure, and the universe's expansion history.

Ongoing Research: Numerous experiments worldwide (e.g., LUX, XENON, LHC) are dedicated to the direct detection of dark matter particles. Space missions (e.g., Euclid, Roman Space Telescope) are designed to map the distribution of dark energy and dark matter.