Dysnomia

Alternative name: Also known as: S/2005 (2003 UB313) 1

Moon

Dysnomia Radius

Radius of Dysnomia

The radius of Dysnomia is one of its most fundamental physical characteristics. The Dysnomia radius measures approximately 350 km, making it 18.20× smaller than Earth. This measurement represents the average distance from the center of Dysnomia to its surface, providing crucial information about the celestial body's size and volume.

Understanding the Dysnomia radius is essential for calculating other important properties such as surface area, volume, and gravitational characteristics. The radius directly influences how we perceive and study this fascinating object in our Solar System.

Dysnomia Semi-Major Axis

Orbital Radius of Dysnomia

The Dysnomia semi-major axis is a critical orbital parameter that defines the average distance from the Sun. The Dysnomia semi-major axis measures 0.00 AU (approximately 37,273 km), which represents the average orbital radius of Dysnomia. This measurement is fundamental to understanding Dysnomia's position in the Solar System and its relationship with other celestial bodies.

The orbital radius of Dysnomia determines how much solar radiation the planet receives, which directly influences its temperature, climate, and overall environmental conditions. This distance places Dysnomia in a specific region of the Solar System, each with unique characteristics and scientific significance.

When we examine the Dysnomia semi-major axis 0.00 AU, we gain insights into the planet's orbital mechanics, including its orbital period, velocity, and the gravitational forces at play. This parameter is essential for space mission planning and understanding the dynamics of our Solar System.

Dysnomia Mass

Mass of Dysnomia in kg

The Dysnomia mass is a fundamental property that determines many of the planet's physical characteristics. The mass of Dysnomia in kg is approximately 1.45e+20 kg, which is 41186.21× less than Earth's mass. This substantial mass creates a significant gravitational field that influences everything from atmospheric retention to orbital dynamics.

Understanding the Dysnomia mass allows scientists to calculate other critical properties such as surface gravity, escape velocity, and the planet's ability to retain an atmosphere. The mass also plays a crucial role in determining how Dysnomia interacts with other celestial bodies through gravitational forces.

The precise measurement of the mass of Dysnomia in kg is essential for space exploration missions, as it affects spacecraft trajectories, landing procedures, and the design of scientific instruments. This fundamental property helps us understandDysnomia's formation history and its place in the evolution of our Solar System.

Dysnomia Orbital Period

How Long is a Year on Dysnomia?

The Dysnomia orbital period defines the length of one complete revolution around the Sun. The Dysnomia orbital period is 0.00 hours, which is 1999249.26× shorter than Earth's year. This orbital period determines the length of Dysnomia's year and directly influences seasonal patterns, climate cycles, and temperature variations.

The Dysnomia orbital period is directly related to its distance from the Sun, following Kepler's laws of planetary motion. Planets farther from the Sun have longer orbital periods, while those closer complete their orbits more quickly. This relationship helps explain why Dysnomia takes the time it does to complete one full orbit.

Understanding the Dysnomia orbital period is crucial for space mission planning, as it affects launch windows, travel times, and the timing of scientific observations. This fundamental orbital parameter also provides insights into the planet's formation history and its current position in the Solar System's dynamic structure.

How Far is Dysnomia from Earth?

Distance Between Dysnomia and Earth

How far is Dysnomia from Earth? This is a question that fascinates both astronomers and space enthusiasts. The distance between Dysnomia and Earth varies throughout their orbital cycles, but on average, Dysnomia is approximately 1.50e+8 km(1.000 AU) away from Earth. This distance changes as both planets orbit the Sun, with the closest approach (opposition) and farthest separation (conjunction) creating significant variations.

The question "How far is Dysnomia from Earth?" has practical implications for space exploration. This distance determines travel time for spacecraft, communication delays for mission control, and the amount of fuel required for interplanetary missions. Understanding this distance is essential for planning future missions to Dysnomia.

The distance between Dysnomia and Earth is not constant due to the elliptical nature of both planets' orbits. When Dysnomia and Earth are on the same side of the Sun (opposition), they are at their closest, making this the optimal time for observations and potential missions. Conversely, when they are on opposite sides of the Sun (conjunction), they are at their farthest separation, which can exceed the average distance significantly.

Table of Contents

Physical Properties

Mean Radius: 350km
Equatorial Radius: 150km
Polar Radius: 0km
Mass: 1.45e+20 kg
Volume: 0.00e+0 km³
Density: 1g/cm³
Gravity: 0m/s²
Escape Velocity: 0m/s
Flattening: 0
Average Temperature: 0.0 K (-273.1 °C)
Axial Tilt: 0°
Semimajor Axis: 37,273km
Perihelion: 0km
Aphelion: 0km
Eccentricity: 0.006
Inclination: 45.49°
Sidereal Orbit: 0.00 hours
Sidereal Rotation: 0 seconds
Mean Anomaly: 0°
Argument of Periapsis: 0°
Longitude of Ascending Node: 0°

Overview of Dysnomia

Dysnomia is a fascinating moon in our Solar System that has captured the attention of astronomers and space enthusiasts alike. With a Dysnomia radius of 350 km, making it 18.2× smaller than Earth's size, this celestial body presents unique characteristics that distinguish it from other objects in our cosmic neighborhood. Positioned at an average distance of 37,273 km (0.000 AU) from the Sun, Dysnomia occupies a significant place in the Solar System's architecture. As a moon, Dysnomia demonstrates the incredible diversity of natural satellites that orbit larger celestial bodies throughout our Solar System.

Physical Characteristics

The Dysnomia physical characteristics reveal a world of remarkable dimensions and properties. The Dysnomia radius measures 350 km, making it 18.2× smaller than Earth's size. The Dysnomia mass of 1.45e+20 kg represents 41186.2× smaller than Earth's mass, giving this world substantial gravitational influence.

Orbital Properties

The Dysnomia orbit reveals fascinating details about its journey around the Sun and its relationship to other Solar System objects. The Dysnomia orbit has a semimajor axis of 37,273 km (0.000 AU), placing it 4013.6× smaller than Earth's distance from the Sun. The Dysnomia orbit is nearly circular with an eccentricity of 0.006 (2.7× smaller than Earth's orbital eccentricity), resulting in relatively stable solar heating throughout its year. The Dysnomia orbit takes 0.00 hours to complete (1999249.3× smaller than Earth's orbital period), defining the length of its year. The orbital inclination of 45.49° indicates how much the Dysnomia orbit is tilted relative to the Solar System's ecliptic plane. This high inclination suggests Dysnomia may have experienced significant gravitational perturbations or formed in a different region of the Solar System.

Rotation and Tilt

The Dysnomia rotation and axial orientation provide crucial insights into its daily and seasonal cycles, as well as its orbital dynamics. The Dysnomia axial tilt of 0° determines the intensity and nature of seasonal variations. With minimal axial tilt, Dysnomia experiences virtually no seasonal changes, maintaining relatively constant temperatures throughout its year. The orbital orientation parameters reveal additional details about Dysnomia's position in space. The mean anomaly of 0° indicates the planet's current position in its orbit relative to its perihelion. The argument of periapsis of 0° shows how the orbit's orientation changes over time due to gravitational perturbations. The longitude of ascending node of 0° defines the reference point where the orbit crosses the ecliptic plane.

Temperature and Atmosphere

The Dysnomia temperature and atmospheric conditions are fundamental to understanding its habitability and environmental characteristics. The Dysnomia average temperature of 0.0 K (-273.1 °C) (-459.7°F) provides the baseline for understanding its climate. These extremely cold temperatures make Dysnomia inhospitable to life as we know it, with any atmosphere likely frozen solid on the surface. Compared to Earth's average temperature of 15°C (59°F), Dysnomia presents a dramatically different thermal environment. Being closer to the Sun than Earth, Dysnomia receives more intense solar radiation, contributing to its temperature profile.

Escape Velocity & Flattening

The Dysnomia escape velocity and shape characteristics reveal important details about its gravitational field and rotational dynamics. The Dysnomia escape velocity of 0 m/s determines how easily objects can break free from its gravitational pull. This relatively low escape velocity means that gases and light molecules can easily escape into space, making it difficult for Dysnomia to retain a substantial atmosphere. The Dysnomia flattening of 0.0000% indicates how much the planet's rotation affects its shape. This minimal flattening suggests a nearly spherical shape, indicating either slow rotation or a very rigid internal structure.

FAQs About Dysnomia

How big is Dysnomia compared to Earth?

Dysnomia has a radius of 350 km, making it 18.2× smaller than Earth's size. In terms of volume, Dysnomia is 0.0× the size of Earth. This size difference significantly impacts the planet's gravity, atmospheric retention, geological processes, and overall planetary characteristics.

How far is Dysnomia from the Sun?

Dysnomia orbits at an average distance of 37,273 km (0.000 AU) from the Sun, placing it 4013.6× smaller than Earth's distance from the Sun. This distance determines the amount of solar radiation the planet receives and significantly influences its temperature and climate.

How long is a year on Dysnomia?

A year on Dysnomia lasts 0.00 hours (1999249.3× smaller than Earth's orbital period). This orbital period defines the length of the planet's year and affects seasonal patterns, temperature variations, and the overall climate cycle.

What is Dysnomia made of?

Dysnomia has a density of 1 g/cm³ (5.5× smaller than Earth's density). This density provides important clues about the planet's internal composition. The low density indicates a composition dominated by lighter elements, characteristic of gas giants or icy bodies.

Does Dysnomia have seasons?

Dysnomia has an axial tilt of 0°. With minimal axial tilt, the planet experiences virtually no seasonal changes, maintaining relatively constant temperatures throughout its year.

Discovery Information

Discovered By: Michael E. Brown
Discovery Date: ??/09/2005

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