The Vector Operator Ñ and The Divergence Theorem

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Presentation transcript:

The Vector Operator Ñ and The Divergence Theorem Chapter 3 Electric Flux Density, Gauss’s Law, and DIvergence The Vector Operator Ñ and The Divergence Theorem Divergence is an operation on a vector yielding a scalar, just like the dot product. We define the del operator Ñ as a vector operator: Then, treating the del operator as an ordinary vector, we can write:

The Vector Operator Ñ and The Divergence Theorem Chapter 3 Electric Flux Density, Gauss’s Law, and DIvergence The Vector Operator Ñ and The Divergence Theorem The Ñ operator does not have a specific form in other coordinate systems than rectangular coordinate system. Nevertheless, Cylindrical Spherical

The Vector Operator Ñ and The Divergence Theorem Chapter 3 Electric Flux Density, Gauss’s Law, and DIvergence The Vector Operator Ñ and The Divergence Theorem We shall now give name to a theorem that we actually have obtained, the Divergence Theorem: The first and last terms constitute the divergence theorem: “The integral of the normal component of any vector field over a closed surface is equal to the integral of the divergence of this vector field throughout the volume enclosed by the closed surface.”

The Vector Operator Ñ and The Divergence Theorem Chapter 3 Electric Flux Density, Gauss’s Law, and DIvergence The Vector Operator Ñ and The Divergence Theorem Example Evaluate both sides of the divergence theorem for the field D = 2xy ax + x2 ay C/m2 and the rectangular parallelepiped formed by the planes x = 0 and 1, y = 0 and 2, and z = 0 and 3. Divergence Theorem But

The Vector Operator Ñ and The Divergence Theorem Chapter 3 Electric Flux Density, Gauss’s Law, and DIvergence The Vector Operator Ñ and The Divergence Theorem

Engineering Electromagnetics Chapter 4 Energy and Potential

Energy Expended in Moving a Point Charge in an Electric Field Chapter 4 Energy and Potential Energy Expended in Moving a Point Charge in an Electric Field The electric field intensity was defined as the force on a unit test charge at that point where we wish to find the value of the electric field intensity. To move the test charge against the electric field, we have to exert a force equal and opposite in magnitude to that exerted by the field. ► We must expend energy or do work. To move the charge in the direction of the electric field, our energy expenditure turns out to be negative. ► We do not do the work, the field does.

Energy Expended in Moving a Point Charge in an Electric Field Chapter 4 Energy and Potential Energy Expended in Moving a Point Charge in an Electric Field Suppose we wish to move a charge Q a distance dL in an electric field E, the force on Q arising from the electric field is: The component of this force in the direction dL which we must overcome is: The force that we apply must be equal and opposite to the force exerted by the field: Differential work done by external source to Q is equal to: If E and L are perpendicular, the differential work will be zero

Energy Expended in Moving a Point Charge in an Electric Field Chapter 4 Energy and Potential Energy Expended in Moving a Point Charge in an Electric Field The work required to move the charge a finite distance is determined by integration: The path must be specified beforehand The charge is assumed to be at rest at both initial and final positions W > 0 means we expend energy or do work W < 0 means the field expends energy or do work

Chapter 4 Energy and Potential The Line Integral The integral expression of previous equation is an example of a line integral, taking the form of integral along a prescribed path. Without using vector notation, we should have to write: EL: component of E along dL The work involved in moving a charge Q from B to A is approximately:

The Line Integral If we assume that the electric field is uniform, Chapter 4 Energy and Potential The Line Integral If we assume that the electric field is uniform, Therefore, Since the summation can be interpreted as a line integral, the exact result for the uniform field can be obtained as: For the case of uniform E, W does not depend on the particular path selected along which the charge is carried

The Line Integral Example Chapter 4 Energy and Potential The Line Integral Example Given the nonuniform field E = yax + xay +2az, determine the work expended in carrying 2 C from B(1,0,1) to A(0.8,0.6,1) along the shorter arc of the circle x2 + y2 = 1, z = 1. Differential path, rectangular coordinate Circle equation:

The Line Integral Example Chapter 4 Energy and Potential The Line Integral Example Redo the example, but use the straight-line path from B to A. Line equation:

Differential Length Rectangular Cylindrical Spherical Chapter 4 Energy and Potential Differential Length Rectangular Cylindrical Spherical

Work and Path Near an Infinite Line Charge Chapter 4 Energy and Potential Work and Path Near an Infinite Line Charge

Definition of Potential Difference and Potential Chapter 4 Energy and Potential Definition of Potential Difference and Potential We already find the expression for the work W done by an external source in moving a charge Q from one point to another in an electric field E: Potential difference V is defined as the work done by an external source in moving a unit positive charge from one point to another in an electric field: We shall now set an agreement on the direction of movement. VAB signifies the potential difference between points A and B and is the work done in moving the unit charge from B (last named) to A (first named).

Definition of Potential Difference and Potential Chapter 4 Energy and Potential Definition of Potential Difference and Potential Potential difference is measured in joules per coulomb (J/C). However, volt (V) is defined as a more common unit. The potential difference between points A and B is: VAB is positive if work is done in carrying the unit positive charge from B to A From the line-charge example, we found that the work done in taking a charge Q from ρ = a to ρ = b was: Or, from ρ = b to ρ = a, Thus, the potential difference between points at ρ = a to ρ = b is:

Definition of Potential Difference and Potential Chapter 4 Energy and Potential Definition of Potential Difference and Potential For a point charge, we can find the potential difference between points A and B at radial distance rA and rB, choosing an origin at Q: rB > rA  VAB > 0, WAB > 0, Work expended by the external source (us) rB < rA  VAB < 0, WAB < 0, Work done by the electric field

Definition of Potential Difference and Potential Chapter 4 Energy and Potential Definition of Potential Difference and Potential It is often convenient to speak of potential, or absolute potential, of a point rather than the potential difference between two points. For this purpose, we must first specify the reference point which we consider to have zero potential. The most universal zero reference point is “ground”, which means the potential of the surface region of the earth. Another widely used reference point is “infinity.” For cylindrical coordinate, in discussing a coaxial cable, the outer conductor is selected as the zero reference for potential. If the potential at point A is VA and that at B is VB, then:

The Potential Field of a Point Charge Chapter 4 Energy and Potential The Potential Field of a Point Charge In previous section we found an expression for the potential difference between two points located at r = rA and r = rB in the field of a point charge Q placed at the origin: Any initial and final values of θ or Φ will not affect the answer. As long as the radial distance between rA and rB is constant, any complicated path between two points will not change the results. This is because although dL has r, θ, and Φ components, the electric field E only has the radial r component.

The Potential Field of a Point Charge Chapter 4 Energy and Potential The Potential Field of a Point Charge The potential difference between two points in the field of a point charge depends only on the distance of each point from the charge. Thus, the simplest way to define a zero reference for potential in this case is to let V = 0 at infinity. As the point r = rB recedes to infinity, the potential at rA becomes:

The Potential Field of a Point Charge Chapter 4 Energy and Potential The Potential Field of a Point Charge Generally, Physically, Q/4πε0r joules of work must be done in carrying 1 coulomb charge from infinity to any point in a distance of r meters from the charge Q. We can also choose any point as a zero reference: with C1 may be selected so that V = 0 at any desired value of r.

Equipotential Surface Chapter 4 Energy and Potential Equipotential Surface Equipotential surface is a surface composed of all those points having the same value of potential. No work is involved in moving a charge around on an equipotential surface. The equipotential surfaces in the potential field of a point charge are spheres centered at the point charge. The equipotential surfaces in the potential field of a line charge are cylindrical surfaces axed at the line charge. The equipotential surfaces in the potential field of a sheet of charge are surfaces parallel with the sheet of charge.

Chapter 4 Energy and Potential Homework 5 D3.9. D4.2. D4.4. D4.5. For D4.4., Replace P(1,2,–4) with P(1,StID, –BMonth). StID is the last two digits of your Student ID Number. Bmonth is your birth month. Example: Rudi Bravo (002201700016) was born on 3 June 2002. Rudi will do D4.4 with P(1,16,–6). All homework problems from Hayt and Buck, 7th Edition. Due: Monday, 4 May 2015.