Perpendicular magnetic recording (PMR) writer with improved trailing shield design

What is claimed is: 1. A write head for perpendicular magnetic recording (PMR) comprising: a main pole having a region of constant width that terminates in a taper that narrows in a negative z-direction and a substantially trapezoidally shaped pole face in an x-y plane of an air bearing surface (ABS), wherein said pole is centrally surrounded by wrap-around shields; wherein said wrap around shields include laterally disposed, mirror image-symmetric side shields formed between a leading shield and a trailing shield; and wherein said wrap around shields are formed of magnetic materials having a common first value of a magnetic saturation field, B s1 ; wherein said pole face is separated at all edges from said wrap-around shields by gap layers and; wherein a leading edge of said trailing shield has an additional trailing shield layer formed thereon wherein said additional trailing shield layer is formed of a magnetic material that has a second value of a magnetic saturation field B s2 that is greater than said first value; and wherein a gap layer between a trailing edge of said pole face and a leading edge of said additional trailing shield layer forms a write gap layer; and wherein a cross-sectional shape of said additional trailing shield layer in a central x-z plane creates a non-conformity with both said tapered and said constant width regions of said main pole, said non-conformity being that said cross-sectional shape is either: a layer of substantially uniform thickness in an x-direction, from whose ABS end a step protrudes in a negative x-direction for an additional distance t, towards said magnetic pole, wherein said step has a height d in a z-direction, and wherein said additional trailing shield layer is of substantially uniform thickness, w, for the remainder of its height above the position of said step; or a layer of substantially uniform thickness, w, in an x-direction, from whose upper end an arm protrudes and from whose ABS end a step protrudes, both in a negative x-direction towards said main pole, wherein said arm and step are substantially parallel, separated in a z-direction by a height h, wherein said additional trailing shield layer is of uniform thickness w between said arm and step and wherein said arm protrudes in a negative x-direction for an additional distance t 1 to within a distance s, of the magnetic pole, wherein said arm has a height h 1 in a z-direction, and wherein said step has a height din a z-direction and protrudes for an additional distance tin an x-direction towards said magnetic pole; whereby, as a result of said non-conformal shape, said write gap layer, which is bounded by said additional trailing shield layer assumes a corresponding shape and a width in the x-direction of said write gap layer varies in a z-direction and flux leakage between said pole and said trailing shield is reduced. 2. The write head of claim 1 wherein B s1 is between approximately 10 and 19 kG (kiloGauss) and B s2 is approximately 24 kG. 3. The write head of claim 2 wherein said common wrap around shield material is NiFe. 4. The write head of claim 2 wherein said additional shield layer material is CoFe. 5. The write head of claim 1 wherein the dimensions of said side shields are between approximately 200 to 500 nm, wherein the dimensions of said leading shield is between approximately 100 and 500 nm and the dimensions of said trailing shield is between approximately 300 and 600 nm. 6. The write head of claim 1 wherein t is between approximately 20 and 100 nm (nanometers) and d is between approximately 20 and 80 nm and the thickness, w, of the remaining layer is between approximately 50 and 100 nm. 7. The write head of claim 1 wherein h is between approximately 100 and 300 nm, wherein t 1 is between approximately 20 and 200 nm, wherein h 1 is between approximately 50 and 350 nm, wherein t is between approximately 20 and 100 nm (nanometers) and d is between approximately 20 and 80 nm and the thickness, w, of the remaining layer is between approximately 50 and 100 nm.