Optical device and a method of forming an optical device

The invention claimed is: 1 . An optical device that is arranged to emit electromagnetic radiation, the optical device comprising: an optical fibre that is arranged to transmit electromagnetic radiation between a source of electromagnetic radiation and an area of interest of a sample material; and an optical element formed directly on an end-portion of the optical fibre, the optical element comprising a graphene lens having a plurality of concentric rings disposed over a core of the optical fibre and having radii determined based on electric field modes of the optical fibre, wherein the graphene lens has a diameter that is substantially matched with a diameter of the optical fibre core, and that is arranged to focus the electromagnetic radiation transmitted by the optical fibre to a focal region within the area of interest of the sample material. 2 . The optical device of claim 1 , wherein the optical device is further arranged to receive electromagnetic radiation that interacted with the area of interest of the sample material. 3 . The optical device of claim 2 , wherein the optical element is arranged to receive electromagnetic radiation that interacted with the area of interest of the sample material and the optical fibre is further arranged to transmit the electromagnetic radiation received by the optical element. 4 . The optical device of claim 1 , wherein the optical fibre comprises a multi-mode optical fibre and the optical element comprises at least two graphene lenses that are arranged to focus light transmitted by the optical fibre to at least two focal regions within the area of interest of the sample material. 5 . The optical device of claim 1 , wherein the optical fibre is one optical fibre of a bundle of optical fibres and the optical element is one optical element of a plurality of optical elements. 6 . The optical device of claim 5 , wherein each optical element of the plurality of optical elements is formed directly on an end-portion of a respective one optical fibre of the bundle of optical fibres. 7 . The optical device of claim 1 , wherein the optical device comprises a bundle of optical fibres, the optical element being formed directly on end portions of the optical fibres of the bundle of optical fibres. 8 . The optical device of claim 1 , wherein the graphene lens is arranged to focus the electromagnetic radiation to the focal region with a sub-micron optical resolution. 9 . An endoscope comprising the optical device of claim 1 . 10 . An optical coherence tomography system comprising the optical device of claim 1 . 11 . A scanning imaging system comprising: the optical device of claim 1 ; and a scanning head coupled to, or comprising at least a portion of, the optical device, the scanning head being arranged for changing a position of the optical element of the optical device relative to the sample material such that the focal region within the area of interest can be scanned across the area of interest of the sample material. 12 . A scanning imaging system comprising: the optical device of claim 1 ; and a spatial light modulator coupled to the optical device, the spatial light modulator being arranged for phase modulation of electromagnetic radiation transmitted through the optical fibre; wherein the optical device is arranged to scan the focal region across the area of interest by phase modulation; wherein the optical fibre comprises a bundle of multi-mode optical fibre and the optical element is formed directly on the end portions of the optical fibres of the bundle of multi-mode optical fibre; and wherein the optical element comprises at least two graphene lenses that are arranged to focus light transmitted by the optical fibre to at least two focal regions within the area of interest of the sample material. 13 . The scanning imaging system of claim 12 , wherein the scanning imaging system further comprises a scanning head coupled to, or comprising at least a portion of, the optical device, the scanning head being arranged for changing a position of the optical element relative to the sample material such that the focal region can be scanned across another adjacent area of interest of the sample material. 14 . An optical fibre coupler for coupling light into a photonic chip, the optical fibre coupler comprising the optical device of claim 1 . 15 . The optical device of claim 1 , wherein the graphene lens comprises 3 to 10 concentric rings. 16 . The optical device of claim 15 , wherein an innermost concentric ring of the 3 to 10 concentric rings has a radius in a range of 1.2 to 7 microns. 17 . The optical device of claim 15 , wherein an outermost concentric ring of the 3 to 10 concentric rings has a radius in a range of 3 to 36 microns. 18 . The optical device of claim 1 , wherein the graphene lens is configured to focus the electromagnetic radiation to a focal length between 1.7 and 2.0 microns for a single mode fibre. 19 . The optical device of claim 1 , wherein the graphene lens is configured to focus the electromagnetic radiation to a focal length between 50 and 100 microns for a multimode fibre. 20 . A method of forming an optical device that is arranged to emit electromagnetic radiation, the method comprising: providing an optical fibre for transmitting electromagnetic radiation between a source of electromagnetic radiation and an area of interest of a sample material; and forming an optical element comprising a graphene lens directly on an end portion of the optical fibre in a manner such that, in use, electromagnetic radiation transmitted by the optical fibre through the graphene lens is focused to a focal region within the area of interest of the sample material; wherein the graphene lens has a plurality of concentric rings disposed over a core of the optical fibre and having radii determined based on electric field modes of the optical fibre, wherein the graphene lens has a diameter that is substantially matched with a diameter of the optical fibre core wherein the graphene lens has a diameter that is substantially matched with a diameter of the optical fibre core, and wherein the graphene lens. 21 . The method of claim 20 , wherein the step of forming the optical element directly on the end portion of the optical fibre comprises positioning the optical element relative to the end portion of the optical fibre such that the graphene lens covers a core of the optical fibre.