In an insulated thin rod, obtain and derive the one dimensional heat equation for the first,...

solve the heat equation for a semi-infinite rod whose lateral surfaces are insulated and for which...

solve the heat equation for a semi-infinite rod whose lateral surfaces are insulated and for which u(x,0)=u0 for x>0, u(0,t)=u1 for t>0, and lim as x approches infinity u(x,t)=u0.

A rod, with sides insulated to prevent heat loss, has one end immersed in boiling water...

A rod, with sides insulated to prevent heat loss, has one end immersed in boiling water 100°C and the other end in a water-ice mixture at 0.00°C. The rod has uniform cross-sectional area of 4.04 cm2 and length of 91 cm. Under steady state conditions, the heat conducted by the rod melts the ice at a rate of 1 g every 34 seconds. What is the thermal conductivity of the rod? (The heat of fusion of water is 3.34 ×...

A thin, 1-dimensional, uniform rod of mass M and length L lies on the x axis...

A thin, 1-dimensional, uniform rod of mass M and length L lies on the x axis with one end at the origin. (a) Find its moment of inertia tensor about the origin. (b) Find the moment of inertia tensor if the rod’s center is located at the origin.

One end of an insulated metal rod is maintained at 100ºC, and the other end is...

One end of an insulated metal rod is maintained at 100ºC, and the other end is maintained at 0ºC by an ice-water mixture. The rod is 60.0 cm long and has a cross-section area of 1.25 cm2. The heat conducted by the rod melts 8.50 g of ice in 10.0 minutes. Find the thermal conductivity of the metal rod.

Starting with an energy balance (or the heat conduction equation) on the volume element, obtain the...

Starting with an energy balance (or the heat conduction equation) on the volume element, obtain the three-dimensional transient explicit finite difference equation for a general interior node in rectangular coordinates for T(x,y,z,t). The thermal conductivity is constant and there is no heat generation.

One end of an insulated metal rod is maintained at 100 ∘C and the other end...

One end of an insulated metal rod is maintained at 100 ∘C and the other end is maintained at 0.00 ∘C by an ice–water mixture. The rod has a length of 50.0 cm and a cross-sectional area of 1.20 cm2 . The heat conducted by the rod melts a mass of 9.00 g of ice in a time of 10.0 min . Part A Find the thermal conductivity k of the metal. k = W/(m⋅K)

A thin rod of length ll swings at small amplitude with the pivot point at one...

A thin rod of length ll swings at small amplitude with the pivot point at one end, with a thick rod of length LL and radius RR attached on the other end. The thin rod has a mass mm = 0.14 kg, and the thick rod a mass of MM = 1.36 kg. The radius of the thick rod is 0.09 m. If ll = 0.86 m and LL = 0.06 m, what is the period of oscillation? Answer in...

Consider a thin rod of length L=2.58m and mass m1=1.27 kg, and a hollow (empty) sphere...

Consider a thin rod of length L=2.58m and mass m1=1.27 kg, and a hollow (empty) sphere of radius R=0.16 m and mass of m2=0.82 kg. Sphere is at one end of the rod and the other end of the rod is fixed and oscillate like a pendulum (simple harmonic oscillations, SHM) with small-angle oscillations. When ? ?? ?????, ???? ≈ ?. a) Derive a second order differential equation for this pendulum to confirm the oscillation is SHM.(b) Compare the above...

A long thin rod lies on the x axis with one end at the origin and...

A long thin rod lies on the x axis with one end at the origin and the other at the 4 cm point. It has a uniform linear charge density of 125 nano C/m. Find the E field due to this rod at the 52 cm position on the x axis. Find the force exerted by the rod on a point charge of 5 micro coulombs placed at a position of 109 cm on the x axis if the rod...

Suppose we are modeling heat flow in a one dimensional rod with constant thermal conductivity K0...

Suppose we are modeling heat flow in a one dimensional rod with constant thermal conductivity K0 and oriented along the x axis from x=0 to x=L. Suppose the x=0 end has a prescribed temperature of 0 as boundary condition, and the x=L end has prescribed temperature equal to sin(2pi t) for t>0 1. Wrote the boundary condition at the x=0 end 2. 2. Write the boundary condition at the x=L end 3. 3. Are the boundary condition homogeneous? 4. Will...