Learning Goal:
To understand the meaning of the variables in Gauss's law, and the conditions under which the law is applicable.
Gauss's law is usually written
ΦE=∮E⃗ ⋅dA⃗ =qenclϵ0,
where ϵ0=8.85×10−12C2/(N⋅m2) is the permittivity of vacuum.
Part A
How should the integral in Gauss's law be evaluated?
Learning Goal: To understand the meaning of the variables in Gauss's law, and the conditions under...
Item 9 Review Part A Learning Goal: How should the integral in Gauss's law be evaluated? To understand the meaning of the variables in Gauss's law, and the conditions under which the law is applicable. around the perimeter of a closed loop over the surface bounded by a closed loop over a closed surface Gauss's law is usually written &se where co 8.85 x 10 12 C2/(N m2) is the permittivity of vacuum Submit Request Answer
To understand the meaning of the variables in Gauss's law, andthe conditions under which the law is applicable. Gauss's law is usually written where isthe permittivity of vacuum. How should theintegral in Gauss's law be evaluated? around theperimeter of a closed loop over the surfacebounded by a closed loop over a closedsurface
Gauss's law is usually written phi _E = contourintegral E vector middot dA vector = q_encl/epsilon _0 where epsilon _0 = 8.85 times 10^-12 C^2 /(N middot m^2) is the permittivity of vacuum. Correct In the integral for Gauss's law, the vector dA^vector represents an infinitesimal surfa magnitude of dA^vector is the area of the surface element. The direction of dA^vector is no element, pointing out of the enclosed volume. In Gauss's law, to what does q_encl refer? the net...
Please explain
EXECUTE the solution as follows Learning Goal: To practice Problem-Solving Strategy 22.1: Gauss's Law Partc An infinite cylindrical rod has a uniform volume charge density ρ (where ρ > 0). The cross section of the rod has radius re. Find the magnitude of the electric field E at a distance r from the axis of the rod. Assume that r < Find the magnitude E of the electric field at a distance r from the axis of the...
Learning Goal: To understand the heat conduction formula and the variables in it. Conduction—the flow of heat from a hotter object to a cooler object or from a hotter region to a cooler region of the same object—is the most common mechanism of heat transfer. The formula governing this is H=ΔQ/Δt=kA((TH−TC)/L), where H is known as the heat current. Part D The quantity ΔQ/Δt is the rate of heat removed from the cold end of the rod to maintain its...
Learning Goal: To understand how to use Hess's law to find the enthalpy of an overall reaction. Correct The change in enthalpy, AH, is the heat absorbed or produced during any reaction at constant pressure. Hess's law states that ? H for an overall reaction is the sum of the values for the individual reactions. For example, if we wanted to know the enthalpy change for the reaction PartB What is the enthalpy for reaction 1 reversed? Express your answer...
Learning Goal: To understand how to use Hess's law to find the enthalpy of an overall reaction. The change in enthalpy, ΔH, is the heat absorbed or produced during any reaction at constant pressure. Hess's law states that ΔH for an overall reaction is the sum of the ΔH values for the individual reactions. For example, if we wanted to know the enthalpy change for the reaction 3Mn+3O2→3MnO2 we could calculate it using the enthalpy values for the following individual...
Learning Goal:
To understand the meaning and the basic applications of
pV diagrams for an ideal gas.
As you know, the parameters of an ideal gas are described by the
equation
pV=nRT,
where p is the pressure of the gas, V is the volume of the gas,
n is the number of moles, R is the universal gas constant, and T is
the absolute temperature of the gas. It follows that, for a portion
of an ideal gas,
pVT=constant.
One...
Learning Goal:
To understand the meaning and the basic applications of
pV diagrams for an ideal gas.
As you know, the parameters of an ideal gas are described by the
equation
pV=nRT,
where p is the pressure of the gas, V is the volume of the gas,
n is the number of moles, R is the universal gas constant, and T is
the absolute temperature of the gas. It follows that, for a portion
of an ideal gas,
pVT=constant.
One...
Magnetic Field inside a Very
Long Solenoid Learning Goal: To apply Ampère's law to find the
magnetic field inside an infinite solenoid. In this problem we will
apply Ampère's law, written ?B? (r? )?dl? =?0Iencl, to calculate
the magnetic field inside a very long solenoid (only a relatively
short segment of the solenoid is shown in the pictures). The
segment of the solenoid shown in (Figure 1) has length L, diameter
D, and n turns per unit length with each...