1547845439-The_Ricci_Flow_-_Techniques_and_Applications_-_Part_I__Chow_

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278 6. ENTROPY AND NO LOCAL COLLAPSING


If g is a steady gradient soliton flowing along 'V f, then


Rij + 'Vi'Vjf = 0,
2Af-J'VJJ^2 + R = 0,

(6.109)

Writing the second variation this way, we see the appearance of the linear
trace Harnack quadratic.
Note that the first line of (6.109) is independent of h whereas for (point-


wise) measure-preserving variations (v, h) of (g, f), the last two lines of

(6.109) vanish. This shows that given Vij, the variation (v, h) minimizing
J: 2 :F(g, J) while preserving the (integral) constraint JM e-f dμ = 1 has the
last two lines of (6.109) nonpositive; not surprisingly, the last two lines are
less than or equal to a negative norm squared, as we shall show below.
Using (6.108), the second line in (6.109) may be rewritten as



  • 2 JM [ \Ji\Jj ( h - ~)] Vije-f dμ


= 2 JM (div v - v ('V f)) · [ \l ( h - ~)] e-f dμ.


Hence for a steady gradient soliton g flowing along 'V f,

::2:F(g, f) =JM ( \liVjp - ~\JpVij) (\lpVij) e-f dμ



  • 2 JM (div v - v ('VJ)) · [ \l (h -~)] e-f dμ


+2JMl\l(h-~)l


2
e-fdμ.

Completing the square, we have


::2 :f'(g, j) = JM ( \JiVjp - ~ \J pVij) (\J pVij) e-f dμ


-~ r Jdivv-v('Vf)J^2 e-fdμ


2}M


  • 2 JM I~ (divv -v ('VJ))+ \l ( h-~) j


2
e-f dμ.
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