No, an orbital is a region in space where there is a high probability of finding an electron in an atom. The shape and size of an orbital can vary depending on the energy level and type of orbital (s, p, d, f). It does not have uniform density like a solid sphere.
Measure the diameter and from that calculate the volume, then determine the mass of the sphere on a weighing device. Then it's just density = mass/volume ========================== It again depends on the sphere whether its hollow or its a solid sphere
If the volume of the sphere is less than 1 cm3, then the sphere will sink in the liquid as its density is greater than that of the liquid.
The orbital circumference of a planet is determined by both the mass and size of a planet. Although a planet will orbit the sum in an eliptical sphere shaped orbit, the circumference of these are almost always relative to the mass and density of the planet. It is also determined on how far away it is from the sun. The orbital circumference of a planet is determined by both the mass and size of a planet. Although a planet will orbit the sum in an eliptical sphere shaped orbit, the circumference of these are almost always relative to the mass and density of the planet. It is also determined on how far away it is from the sun.
To find the volume of the sphere, you need to know the density of the material the sphere is made of. With just the mass provided (75 grams), you cannot calculate the volume without this additional information.
Density is the mass per unit volume. e.g. kg/m3. But you've only given one of the quantities needed - we still need the volume of the sphere.
The electric field inside a sphere of uniform charge density is zero.
The distribution of the electric field inside a sphere with non-uniform charge density varies depending on the specific distribution of charges within the sphere. The electric field strength at any point inside the sphere can be calculated using the principles of Gauss's Law and the superposition principle. The field strength will be stronger in regions with higher charge density and weaker in regions with lower charge density.
Assuming the ball is a perfect sphere of uniform density, and is suspended from a massless string, the centre of gravity is in the centre of the ball.
The s orbital from the energy level resembles a sphere. It is the lowest energy orbital in an atom and has a symmetrical spherical shape around the nucleus.
The formula for calculating the charge density of a sphere is Q / V, where is the charge density, Q is the total charge of the sphere, and V is the volume of the sphere.
The surface charge density formula of a sphere is Q / 4r, where is the surface charge density, Q is the total charge on the sphere, and r is the radius of the sphere.
The charge density formula for a sphere is Q / V, where is the charge density, Q is the total charge, and V is the volume of the sphere.
The formula for calculating the surface charge density of a sphere is: Q / 4r, where represents the surface charge density, Q is the total charge on the sphere, and r is the radius of the sphere.
The motion of a sphere in fluid becomes uniform over time due to the balance between gravitational forces and fluid resistance. As the sphere moves, the fluid creates a drag force that eventually equals the gravitational force acting on the sphere. This equilibrium causes the sphere to move at a constant velocity, resulting in a uniform motion.
a gold sphere
you need the mass and radius of the sphere- density = mass divided by volume, so mass/volume. the volume of a sphere is 4 divided by 3 multiplied by pi multiplied by the radius squared. 4/3(π)(r^2).
The nuclear atom differs from the uniform sphere model, because they both are made from different atoms because of the elements.