Coated cutting tool

1 . A coated cutting tool comprising: a body; and a hard and wear resistant coating on the body, the coating having at least one NbN layer with a thickness between 0.2 μm and 15 μm, the NbN layer being a phase mixture of a cubic phase, c-NbN, and a hexagonal phase, h-NbN, with a X-ray diffraction peak area ratio of 0.4<R 0 <1, where R 0 =I c-NbN(200) /(I c-NbN(200) +I h-NbN(100) ), and I c-NbN(200) and I h-NbN(100) are the X-ray diffraction peak areas as extracted from the pseudo-Voigt peak profile fitting results of θ-2θ scans obtained with Cu—Kα-radiation for the c-NbN (200) and h-NbN (100) diffraction peaks, respectively. 2 . The coated cutting tool according to claim 1 , wherein the peak area ratio R 0 is 0.6<R 0 ≤1.0. 3 . The coated cutting tool according to claim 1 , wherein the cubic phase c-NbN has a crystallographic orientation of 0.2<R 2 ≤1, where R 2 =I c-NbN(200) /(I c-NbN(200) +I c-NbN(111) )), and I c-NbN(200) and I c-NbN(111) are the X-ray diffraction peak areas as extracted from the pseudo-Voigt peak profile fitting results of θ-2θ scans obtained with Cu—Kα-radiation for the c-NbN (200) and c-NbN (111) diffraction peaks, respectively. 4 . The coated cutting tool according to claim 3 , wherein the peak area ratio R 2 is 0.4<R 2 ≤1. 5 . The coated cutting tool according to claim 3 , wherein the peak area ratio R 2 is 0.6<R 2 ≤1. 6 . The coated cutting tool according to claim 1 , wherein the NbN layer has a crystallographic orientation relation of 0.5<R 1 ≤1, where R 1 =I c-NbN(200) /(I c-NbN(200) +I h-NbN(101) ), and where I c-NbN(200) and I h-NbN(101) ) are the X-ray diffraction peak areas as extracted from the pseudo-Voigt peak profile fitting results of θ-2θ scans obtained with Cu—K α -radiation for the c-NbN (200) and h-NbN (101) diffraction peaks, respectively. 7 . The coated cutting tool according to claim 6 , wherein the peak area ratio R 1 is 0.7<R 1 ≤1.0. 8 . The coated cutting tool according to claim 1 , wherein the coating includes a cubic c-(Ti 1-x Al x )N y layer, where 0<x<0.7 and 0.7<y<1.1, arranged between the body and the NbN layer. 9 . The coated cutting tool according to claim 8 , wherein 0.4<x<0.7. 10 . The coated cutting tool according to claim 8 , wherein the c-(Ti 1-x Al x )N y layer and the NbN layer has a thickness ratio d c-(Ti 1-x Al x )N y :d NbN of 2:3<d c-(Ti 1-x Al x )N y :d NbN <6:1, preferably 1:1<d c-(Ti 1-x Al x )N y :d NbN <5:1. 11 . The coated cutting tool according to claim 8 , wherein the cubic c-(Ti 1-x Al x )N y layer contains less than 5 at % of cubic c-TiN, cubic c-AlN and hexagonal h-AlN phases. 12 . The coated cutting tool according to claim 8 , wherein the c-(Ti 1-x Al x )N y layer has a crystallographic orientation relation of 0.5<R 7 ≤1, where R 7 =I c-(Ti 1-x Al x )N y (200) /(I c-(Ti 1-x Al x )N y (200) +I c-(Ti 1-x Al x )N y (111) ), and I c-(Ti 1-x Al x )N y (200) and I c-(Ti 1-x Al x )N y (111) are the X-ray diffraction peak areas as extracted from the pseudo-Voigt peak profile fitting results of θ-2θ scans obtained with Cu—Kα-radiation for the c-(Ti 1-x Al x )N y (200) and c-(Ti 1-x Al x )N y (111) diffraction peaks, respectively. 13 . The coated cutting tool according to claim 12 , wherein the peak area ratio R 7 is 0.6<R 7 ≤1. 14 . The coated cutting tool according to claim 1 , wherein the coated cutting tool is a drill or end-mill for machining by chip removal, and the body is a hard alloy of cemented carbide, cermet, ceramics, cubic boron nitride based material or high speed steel.