Polar Plane Cordinates and Vector Fields

Vector fields in polar coordinates

Two dimensions

At any point in the plane, we can define vectors rr and e as shown:

i

j

ere

In situations with circular symmetry, it is often more natural to describe vectorfields in terms of er and e rather than i and j. One can translate between thetwo descriptions as follows:

er = cos()i + sin()j e = sin()i + cos()j

i = cos()er sin()e j = sin()er + cos()e.

Two dimensions


i

j

ere

In situations with circular symmetry, it is often more natural to describe vectorfields in terms of er and e rather than i and j.

One can translate between thetwo descriptions as follows:



Two dimensions


i

j

ere




Two dimensions


i

j

ere


er = cos()i + sin()j e = sin()i + cos()ji = cos()er sin()e j = sin()er + cos()e.

Examples

Here are two examples of vector fields described in terms of er and e:

u = sin()er u =r(e + er/10)

Div, grad and curl in polar coordinates

We will need to express the operators grad, div and curl in terms of polarcoordinates.

(a) For any two-dimensional scalar field f (expressed as a function of r and )we have

(f ) = grad(f ) = fr er + r1f e.(b) For any 2-dimensional vector field u = m er + p e (where m and p are

expressed as functions of r and ) we have

div(u) = r1m + mr + r1p

= r1 ((rm)r + p)

curl(u) = r1p + pr r1m

= r1 ((rp)r m)

=1

rdet

[r

m rp

].

Note that the product rule gives (rm)r = m + r mr and (rp)r = p + r pr .

(c) For any two-dimensional scalar field f we have

2(f ) = r1fr + frr + r2f

= r1(rfr )r + r2f

Note: in the exam, if you need these formulae, they will be provided.




(f ) = grad(f ) = fr er + r1f e.

(b) For any 2-dimensional vector field u = m er + p e (where m and p areexpressed as functions of r and ) we have


= r1 ((rm)r + p)


= r1 ((rp)r m)

=1

rdet

[r

m rp

].



2(f ) = r1fr + frr + r2f

= r1(rfr )r + r2f








= r1 ((rm)r + p)


= r1 ((rp)r m)

=1

rdet

[r

m rp

].



2(f ) = r1fr + frr + r2f

= r1(rfr )r + r2f







div(u) = r1m + mr + r1p = r

1 ((rm)r + p)

curl(u) = r1p + pr r1m = r1 ((rp)r m)

=1

rdet

[r

m rp

].



2(f ) = r1fr + frr + r2f

= r1(rfr )r + r2f







div(u) = r1m + mr + r1p = r

1 ((rm)r + p)

curl(u) = r1p + pr r1m = r1 ((rp)r m)

=1

rdet

[r

m rp

].



2(f ) = r1fr + frr + r2f = r1(rfr )r + r2f


Grad in polar coordinates

For any two-dimensional scalar field f (as a function of r and ) we have

(f ) = grad(f ) = fr er + r1f e.

Justification: Consider the field u = fr er + r1f e; we show that this is the

same as grad(f ). Two-variable chain rule: suppose we make a small change rto r . This causes a change x ' xr r to x , which in turn causes a change' fx x ' fx xr r to f . At the same time, our change in r also causes a changey ' yr r to x , which causes a change ' fy y = fy yr r to f . Altogether, thechange in f is f ' (fxxr + fyyr )r . By passing to the limit r 0, we getfr = fxxr + fyyr . Similarly, f = fxx + fyy. Moreover, we can differentiate theformulae x = r cos() y = r sin()

to get xr = cos() yr = sin()

x = r sin() y = r cos()

, so

fr = fxxr + fyyr = cos()fx + sin()fy

f = fxx + fyy = r sin()fx + r cos()fyu = fr er + r

1f e = fxcos()er + fy sin()erfxsin()e + fycos()e= fx (cos()er sin()e) + fy (sin()er + cos()e) = fx i + fy j = grad(f ).



(f ) = grad(f ) = fr er + r1f e.Justification: Consider the field u = fr er + r

1f e; we show that this is thesame as grad(f ).

Two-variable chain rule: suppose we make a small change rto r . This causes a change x ' xr r to x , which in turn causes a change' fx x ' fx xr r to f . At the same time, our change in r also causes a changey ' yr r to x , which causes a change ' fy y = fy yr r to f . Altogether, thechange in f is f ' (fxxr + fyyr )r . By passing to the limit r 0, we getfr = fxxr + fyyr . Similarly, f = fxx + fyy. Moreover, we can differentiate theformulae x = r cos() y = r sin()



, so







1f e; we show that this is thesame as grad(f ). Two-variable chain rule: suppose we make a small change rto r .

This causes a change x ' xr r to x , which in turn causes a change' fx x ' fx xr r to f . At the same time, our change in r also causes a changey ' yr r to x , which causes a change ' fy y = fy yr r to f . Altogether, thechange in f is f ' (fxxr + fyyr )r . By passing to the limit r 0, we getfr = fxxr + fyyr . Similarly, f = fxx + fyy. Moreover, we can differentiate theformulae x = r cos() y = r sin()



, so







1f e; we show that this is thesame as grad(f ). Two-variable chain rule: suppose we make a small change rto r . This causes a change x ' xr r to x

, which in turn causes a change' fx x ' fx xr r to f . At the same time, our change in r also causes a changey ' yr r to x , which causes a change ' fy y = fy yr r to f . Altogether, thechange in f is f ' (fxxr + fyyr )r . By passing to the limit r 0, we getfr = fxxr + fyyr . Similarly, f = fxx + fyy. Moreover, we can differentiate theformulae x = r cos() y = r sin()



, so







1f e; we show that this is thesame as grad(f ). Two-variable chain rule: suppose we make a small change rto r . This causes a change x ' xr r to x , which in turn causes a change' fx x ' fx xr r to f .

At the same time, our change in r also causes a changey ' yr r to x , which causes a change ' fy y = fy yr r to f . Altogether, thechange in f is f ' (fxxr + fyyr )r . By passing to the limit r 0, we getfr = fxxr + fyyr . Similarly, f = fxx + fyy. Moreover, we can differentiate theformulae x = r cos() y = r sin()



, so







1f e; we show that this is thesame as grad(f ). Two-variable chain rule: suppose we make a small change rto r . This causes a change x ' xr r to x , which in turn causes a change' fx x ' fx xr r to f . At the same time, our change in r also causes a changey ' yr r to x

, which causes a change ' fy y = fy yr r to f . Altogether, thechange in f is f ' (fxxr + fyyr )r . By passing to the limit r 0, we getfr = fxxr + fyyr . Similarly, f = fxx + fyy. Moreover, we can differentiate theformulae x = r cos() y = r sin()



, so







1f e; we show that this is thesame as grad(f ). Two-variable chain rule: suppose we make a small change rto r . This causes a change x ' xr r to x , which in turn causes a change' fx x ' fx xr r to f . At the same time, our change in r also causes a changey ' yr r to x , which causes a change ' fy y = fy yr r to f .

Altogether, thechange in f is f ' (fxxr + fyyr )r . By passing to the limit r 0, we getfr = fxxr + fyyr . Similarly, f = fxx + fyy. Moreover, we can differentiate theformulae x = r cos() y = r sin()



, so







1f e; we show that this is thesame as grad(f ). Two-variable chain rule: suppose we make a small change rto r . This causes a change x ' xr r to x , which in turn causes a change' fx x ' fx xr r to f . At the same time, our change in r also causes a changey ' yr r to x , which causes a change ' fy y = fy yr r to f . Altogether, thechange in f is f ' (fxxr + fyyr )r .

By passing to the limit r 0, we getfr = fxxr + fyyr . Similarly, f = fxx + fyy. Moreover, we can differentiate theformulae x = r cos() y = r sin()



, so







1f e; we show that this is thesame as grad(f ). Two-variable chain rule: suppose we make a small change rto r . This causes a change x ' xr r to x , which in turn causes a change' fx x ' fx xr r to f . At the same time, our change in r also causes a changey ' yr r to x , which causes a change ' fy y = fy yr r to f . Altogether, thechange in f is f ' (fxxr + fyyr )r . By passing to the limit r 0, we getfr = fxxr + fyyr .

Similarly, f = fxx + fyy. Moreover, we can differentiate theformulae x = r cos() y = r sin()



, so







1f e; we show that this is thesame as grad(f ). Two-variable chain rule: suppose we make a small change rto r . This causes a change x ' xr r to x , which in turn causes a change' fx x ' fx xr r to f . At the same time, our change in r also causes a changey ' yr r to x , which causes a change ' fy y = fy yr r to f . Altogether, thechange in f is f ' (fxxr + fyyr )r . By passing to the limit r 0, we getfr = fxxr + fyyr . Similarly, f = fxx + fyy.

Moreover, we can differentiate theformulae x = r cos() y = r sin()



, so







1f e; we show that this is thesame as grad(f ). Two-variable chain rule: suppose we make a small change rto r . This causes a change x ' xr r to x , which in turn causes a change' fx x ' fx xr r to f . At the same time, our change in r also causes a changey ' yr r to x , which causes a change ' fy y = fy yr r to f . Altogether, thechange in f is f ' (fxxr + fyyr )r . By passing to the limit r 0, we getfr = fxxr + fyyr . Similarly, f = fxx + fyy. Moreover, we can differentiate theformulae x = r cos() y = r sin()



, so









x = r sin() y = r cos(), so

fr = fxxr + fyyr

= cos()fx + sin()fy










f = fxx + fyy

= r sin()fx + r cos()fyu = fr er + r









f = fxx + fyy = r sin()fx + r cos()fy

u = fr er + r1f e = fxcos()er + fy sin()erfxsin()e + fycos()e

= fx (cos()er sin()e) + fy (sin()er + cos()e) = fx i + fy j = grad(f ).









1f e

= fxcos()er + fy sin()erfxsin()e + fycos()e= fx (cos()er sin()e) + fy (sin()er + cos()e) = fx i + fy j = grad(f ).









1f e = fxcos()er + fy sin()erfxsin()e + fycos()e

= fx (cos()er sin()e) + fy (sin()er + cos()e) = fx i + fy j = grad(f ).









1f e = fxcos()er + fy sin()erfxsin()e + fycos()e= fx (cos()er sin()e) + fy (sin()er + cos()e)

= fx i + fy j = grad(f ).









1f e = fxcos()er + fy sin()erfxsin()e + fycos()e= fx (cos()er sin()e) + fy (sin()er + cos()e) = fx i + fy j

= grad(f ).

Examples of polar div, grad and curl

Example: Consider f = rn.

Clearly fr = nrn1 and f = 0, so

grad(f ) = fr er + r1f e

= nrn1er .

Note also that r = (x , y) = (r cos(), r sin()) = r er , so er = r/r , so we canrewrite as grad(rn) = nrn2r. (Obtained earlier using rectangular coordinates.)

Example: Consider f = .

Clearly fr = 0 and f = 1, so

grad(f ) = fr er+r1f e

= r1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).

(Obtained earlier using rectangular coordinates.)

Example: Consider u =r(e + er/10) from the plot above.

This is

u = per + qe where p = r12 /10 and q = r

12 , so p = q = 0 and pr = r

12 /20

and qr = r 1

2 /2. It follows that

div(u) = r1p + pr + r1q

= r1r12 /10 + r

12 /20 + 0 = 3r

12 /20

curl(u) = r1q + qr r1p = r1r12 + r

12 /2 0 = 3r

12 /2.


Example: Consider f = rn. Clearly fr = nrn1 and f = 0

, so


= nrn1er .





= r1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).



This is


12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



= r1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0 = 3r

12 /2.


Example: Consider f = rn. Clearly fr = nrn1 and f = 0, so


= nrn1er .





= r1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).



This is


12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



= r1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0 = 3r

12 /2.



grad(f ) = fr er + r1f e = nr

n1er .





= r1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).



This is


12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



= r1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0 = 3r

12 /2.




n1er .

Note also that r = (x , y) = (r cos(), r sin()) = r er

, so er = r/r , so we canrewrite as grad(rn) = nrn2r. (Obtained earlier using rectangular coordinates.)




= r1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).



This is


12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



= r1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0 = 3r

12 /2.




n1er .

Note also that r = (x , y) = (r cos(), r sin()) = r er , so er = r/r

, so we canrewrite as grad(rn) = nrn2r. (Obtained earlier using rectangular coordinates.)




= r1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).



This is


12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



= r1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0 = 3r

12 /2.




n1er .

Note also that r = (x , y) = (r cos(), r sin()) = r er , so er = r/r , so we canrewrite as grad(rn) = nrn2r.





= r1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).



This is


12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



= r1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0 = 3r

12 /2.




n1er .





= r1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).



This is


12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



= r1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0 = 3r

12 /2.




n1er .


Example: Consider f = . Clearly fr = 0 and f = 1

, so


= r1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).



This is


12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



= r1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0 = 3r

12 /2.




n1er .


Example: Consider f = . Clearly fr = 0 and f = 1, so


= r1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).



This is


12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



= r1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0 = 3r

12 /2.




n1er .



grad(f ) = fr er+r1f e = r

1e

= r2(r sin(), r cos()) =( yx2 + y 2

,x

x2 + y 2

).



This is


12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



= r1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0 = 3r

12 /2.




n1er .




1e = r2(r sin(), r cos())

=

( yx2 + y 2

,x

x2 + y 2

).



This is


12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



= r1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0 = 3r

12 /2.




n1er .




1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).



This is


12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



= r1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0 = 3r

12 /2.




n1er .




1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).


Example: Consider u =r(e + er/10) from the plot above. This is


12

, so p = q = 0 and pr = r 1

2 /20

and qr = r 1



= r1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0 = 3r

12 /2.




n1er .




1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).




12 , so p = q = 0 and pr = r

12 /20

and qr = r 1

2 /2.

It follows that


= r1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0 = 3r

12 /2.




n1er .




1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).




12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



= r1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0 = 3r

12 /2.




n1er .




1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).




12 , so p = q = 0 and pr = r

12 /20

and qr = r 1


div(u) = r1p + pr + r1q = r

1r12 /10 + r

12 /20 + 0

= 3r12 /20


12 /2 0 = 3r

12 /2.




n1er .




1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).




12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0 = 3r

12 /2.




n1er .




1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).




12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



1r12 /10 + r

12 /20 + 0 = 3r

12 /20

curl(u)

= r1q + qr r1p = r1r12 + r

12 /2 0 = 3r

12 /2.




n1er .




1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).




12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



1r12 /10 + r

12 /20 + 0 = 3r

12 /20

curl(u) = r1q + qr r1p

= r1r12 + r

12 /2 0 = 3r

12 /2.




n1er .




1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).




12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0

= 3r12 /2.




n1er .




1e = r2(r sin(), r cos()) =

( yx2 + y 2

,x

x2 + y 2

).




12 , so p = q = 0 and pr = r

12 /20

and qr = r 1



1r12 /10 + r

12 /20 + 0 = 3r

12 /20


12 /2 0 = 3r

12 /2.

Cylindrical polar coordinates

In cylindrical polar coordinates we use unit vectors er , e and ez as shownbelow:

er

e

ez

Thus, er and e are the same as for two-dimensional polar coordinates, and ezis just the vertical unit vector k. The equations are:

er = cos()i + sin()j e = sin()i + cos()j ez = k

i = cos()er sin()e j = sin()er + cos()e k = ez .



er

e

ez

Thus, er and e are the same as for two-dimensional polar coordinates, and ezis just the vertical unit vector k.

The equations are:





er

e

ez






er

e

ez


er = cos()i + sin()j e = sin()i + cos()j ez = ki = cos()er sin()e j = sin()er + cos()e k = ez .

Div, grad and curl in cylindrical polar coordinates

The rules for div, grad and curl are as follows:

(a) For any three-dimensional scalar field f (expressed as a function of r , and z) we have

(f ) = grad(f ) = fr er + r1f e + fzez .(b) For any three-dimensional vector field u = m er + p e + q ez (where m, p

and q are expressed as functions of r , and z) we have

div(u) = r1m + mr + r1p + qz

= r1(rm)r + r1p + qz

curl(u) =1

rdet

er re ezr

z

m rp q

.

(c) For any three-dimensional scalar field f we have

2(f ) = r1fr + frr + r2f + fzz

= r1(rfr )r + r2f + fzz .




(f ) = grad(f ) = fr er + r1f e + fzez .

(b) For any three-dimensional vector field u = m er + p e + q ez (where m, pand q are expressed as functions of r , and z) we have



curl(u) =1

rdet

er re ezr

z

m rp q

.











curl(u) =1

rdet

er re ezr

z

m rp q

.(c) For any three-dimensional scalar field f we have








div(u) = r1m + mr + r1p + qz = r

1(rm)r + r1p + qz

curl(u) =1

rdet

er re ezr

z

m rp q










1(rm)r + r1p + qz

curl(u) =1

rdet

er re ezr

z

m rp q

.










1(rm)r + r1p + qz

curl(u) =1

rdet

er re ezr

z

m rp q










1(rm)r + r1p + qz

curl(u) =1

rdet

er re ezr

z

m rp q


2(f ) = r1fr + frr + r2f + fzz = r1(rfr )r + r2f + fzz .

Example of curl in cylindrical polar coordinates

Consider the vector field u given in cylindrical polar coordinates byu = r(e + ez).

This is u = mer + pe + qez , where m = 0 and p = q = r , so

curl(u)

=1

rdet

er re ezr

z

0 r 2 r

=1

r

((

(r)

z(r 2)

)er

(

r(r)

z(0)

)re +

(

r(r 2)

(0)

)ez

)=

1

r(re + 2rez) = 2ez e.


Consider the vector field u given in cylindrical polar coordinates byu = r(e + ez). This is u = mer + pe + qez , where m = 0 and p = q = r

, so

curl(u)

=1

rdet

er re ezr

z

0 r 2 r

=1

r

((

(r)

z(r 2)

)er

(

r(r)

z(0)

)re +

(

r(r 2)

(0)

)ez

)=

1



Consider the vector field u given in cylindrical polar coordinates byu = r(e + ez). This is u = mer + pe + qez , where m = 0 and p = q = r , so

curl(u)

=1

rdet

er re ezr

z

0 r 2 r

=1

r

((

(r)

z(r 2)

)er

(

r(r)

z(0)

)re +

(

r(r 2)

(0)

)ez

)=

1




curl(u)

=1

rdet

er re ezr

z

0 r 2 r

=

1

r

((

(r)

z(r 2)

)er

(

r(r)

z(0)

)re +

(

r(r 2)

(0)

)ez

)

=1




curl(u)

=1

rdet

er re ezr

z

0 r 2 r

=

1

r

((

(r)

z(r 2)

)er

(

r(r)

z(0)

)re +

(

r(r 2)

(0)

)ez

)=

1

r(re + 2rez)

= 2ez e.



curl(u)

=1

rdet

er re ezr

z

0 r 2 r

=

1

r

((

(r)

z(r 2)

)er

(

r(r)

z(0)

)re +

(

r(r 2)

(0)

)ez

)=

1


Spherical polar coordinates

In spherical polar coordinates we use unitvectors er , e and e as on the right:

Note that e has the same meaning asit did in the cylindrical case, but er haschanged. It used to be the unit vectorpointing horizontally away from the z-axis, but now it points directly away fromthe origin.

ere

e

The vectors er , e and e are related to i, j and k as follows.

er = sin() cos()i + sin() sin()j + cos()k

e = cos() cos()i + cos() sin()j sin()ke = sin()i + cos()j

i = sin() cos()er + cos() cos()e sin()ej = sin() sin()er + cos() sin()e + cos()e

k = cos()er sin()e.



Note that e has the same meaning asit did in the cylindrical case, but er haschanged.

It used to be the unit vectorpointing horizontally away from the z-axis, but now it points directly away fromthe origin.

ere

e





k = cos()er sin()e.



Note that e has the same meaning asit did in the cylindrical case, but er haschanged. It used to be the unit vectorpointing horizontally away from the z-axis, but now it points directly away fromthe origin.

ere

e





k = cos()er sin()e.

Div, grad and curl in spherical polar coordinates

The rules for div, grad and curl in spherical polar coordinates are as follows.

(a) For any three-dimensional scalar field f (expressed as a function of r , and ) we have

(f ) = grad(f ) = fr er + r1f e + (r sin())1fe.(b) For any three-dimensional vector field u = m er + p e + q e (where m, p

and q are expressed as functions of r , and ) we have

div(u) = r2(r 2m)r + (r sin())1(sin()p) + (r sin())

1q

curl(u) =1

r 2 sin()det

er re r sin()er

m rp r sin()q

.


2(f ) = r2(r 2fr )r + (r 2 sin())1(sin()f) + (r 2 sin2())1f.




(f ) = grad(f ) = fr er + r1f e + (r sin())1fe.

(b) For any three-dimensional vector field u = m er + p e + q e (where m, pand q are expressed as functions of r , and ) we have


1q

curl(u) =1

r 2 sin()det

er re r sin()er

m rp r sin()q

.









1q

curl(u) =1

r 2 sin()det

er re r sin()er

m rp r sin()q









1q

curl(u) =1

r 2 sin()det

er re r sin()er

m rp r sin()q

.









1q

curl(u) =1

r 2 sin()det

er re r sin()er

m rp r sin()q



Example of div, grad and curl in spherical polar coordinates

Potential of a point charge at the origin is V = A/r , (A constant,r =

x2 + y 2 + z2).

The electric field is E = grad(V ). No magnetism or othercharges, so Maxwell says div(E) = 0 and curl(E) = 0. We will check this.First, we have Vr = A/r 2 and V = V = 0, so the rule

grad(V ) = Vr er + r1V e + (r sin())

1Ve

just gives E = grad(V ) = Ar2er . In other words, we haveE = mer + pe + qe with m = Ar2 and p = q = 0. The general rule forthe divergence is

div(E) = r2(r 2m)r + (r sin())1(sin()p) + (r sin())

1q.

As p = q = 0, the second and third terms are zero. In the first term, we haver 2m = A, which is constant, so (r 2m)r = 0 as well. This means thatdiv(E) = 0 as expected. Finally, curl(E) is

1

r 2 sin()det

er re r sin()er

m rp r sin()q

=1

r 2 sin()det

er re r sin()er

Ar2 0 0

.

As

(Ar2) =

(Ar2) = 0, all terms vanish so curl(E) = 0 as well.



x2 + y 2 + z2). The electric field is E = grad(V ).

No magnetism or othercharges, so Maxwell says div(E) = 0 and curl(E) = 0. We will check this.First, we have Vr = A/r 2 and V = V = 0, so the rule


1Ve



1q.


1

r 2 sin()det

er re r sin()er

m rp r sin()q

=1

r 2 sin()det

er re r sin()er

Ar2 0 0

.

As

(Ar2) =




x2 + y 2 + z2). The electric field is E = grad(V ). No magnetism or other

charges, so Maxwell says div(E) = 0 and curl(E) = 0. We will check this.

First, we have Vr = A/r 2 and V = V = 0, so the rulegrad(V ) = Vr er + r

1V e + (r sin())1Ve



1q.


1

r 2 sin()det

er re r sin()er

m rp r sin()q

=1

r 2 sin()det

er re r sin()er

Ar2 0 0

.

As

(Ar2) =





charges, so Maxwell says div(E) = 0 and curl(E) = 0. We will check this.First, we have Vr = A/r 2

and V = V = 0, so the rule


1Ve



1q.


1

r 2 sin()det

er re r sin()er

m rp r sin()q

=1

r 2 sin()det

er re r sin()er

Ar2 0 0

.

As

(Ar2) =





charges, so Maxwell says div(E) = 0 and curl(E) = 0. We will check this.First, we have Vr = A/r 2 and V = V = 0

, so the rule


1Ve



1q.


1

r 2 sin()det

er re r sin()er

m rp r sin()q

=1

r 2 sin()det

er re r sin()er

Ar2 0 0

.

As

(Ar2) =





charges, so Maxwell says div(E) = 0 and curl(E) = 0. We will check this.First, we have Vr = A/r 2 and V = V = 0, so the rule


1Ve



1q.


1

r 2 sin()det

er re r sin()er

m rp r sin()q

=1

r 2 sin()det

er re r sin()er

Ar2 0 0

.

As

(Ar2) =







1Ve

just gives E = grad(V ) = Ar2er .

In other words, we haveE = mer + pe + qe with m = Ar2 and p = q = 0. The general rule forthe divergence is


1q.


1

r 2 sin()det

er re r sin()er

m rp r sin()q

=1

r 2 sin()det

er re r sin()er

Ar2 0 0

.

As

(Ar2) =







1Ve

just gives E = grad(V ) = Ar2er . In other words, we haveE = mer + pe + qe with m = Ar2 and p = q = 0.

The general rule forthe divergence is


1q.


1

r 2 sin()det

er re r sin()er

m rp r sin()q

=1

r 2 sin()det

er re r sin()er

Ar2 0 0

.

As

(Ar2) =







1Ve



1q.


1

r 2 sin()det

er re r sin()er

m rp r sin()q

=1

r 2 sin()det

er re r sin()er

Ar2 0 0

.

As

(Ar2) =







1Ve



1q.

As p = q = 0, the second and third terms are zero.

In the first term, we haver 2m = A, which is constant, so (r 2m)r = 0 as well. This means thatdiv(E) = 0 as expected. Finally, curl(E) is

1

r 2 sin()det

er re r sin()er

m rp r sin()q

=1

r 2 sin()det

er re r sin()er

Ar2 0 0

.

As

(Ar2) =







1Ve



1q.

As p = q = 0, the second and third terms are zero. In the first term, we haver 2m = A, which is constant

, so (r 2m)r = 0 as well. This means thatdiv(E) = 0 as expected. Finally, curl(E) is

1

r 2 sin()det

er re r sin()er

m rp r sin()q

=1

r 2 sin()det

er re r sin()er

Ar2 0 0

.

As

(Ar2) =







1Ve



1q.

As p = q = 0, the second and third terms are zero. In the first term, we haver 2m = A, which is constant, so (r 2m)r = 0 as well.

This means thatdiv(E) = 0 as expected. Finally, curl(E) is

1

r 2 sin()det

er re r sin()er

m rp r sin()q

=1

r 2 sin()det

er re r sin()er

Ar2 0 0

.

As

(Ar2) =







1Ve



1q.

As p = q = 0, the second and third terms are zero. In the first term, we haver 2m = A, which is constant, so (r 2m)r = 0 as well. This means thatdiv(E) = 0 as expected.

Finally, curl(E) is

1

r 2 sin()det

er re r sin()er

m rp r sin()q

=1

r 2 sin()det

er re r sin()er

Ar2 0 0

.

As

(Ar2) =







1Ve



1q.


1

r 2 sin()det

er re r sin()er

m rp r sin()q

=1

r 2 sin()det

er re r sin()er

Ar2 0 0

.As

(Ar2) =







1Ve



1q.


1

r 2 sin()det

er re r sin()er

m rp r sin()q

= 1r 2 sin()

det

er re r sin()er

Ar2 0 0

.

As

(Ar2) =







1Ve



1q.


1

r 2 sin()det

er re r sin()er

m rp r sin()q

= 1r 2 sin()

det

er re r sin()er

Ar2 0 0

.As

(Ar2) =

(Ar2) = 0, all terms vanish

so curl(E) = 0 as well.






1Ve



1q.


1

r 2 sin()det

er re r sin()er

m rp r sin()q

= 1r 2 sin()

det

er re r sin()er

Ar2 0 0

.As

(Ar2) =

(Ar2) = 0, all terms vanish so curl(E) = 0 as

Polar Plane Cordinates and Vector Fields

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