Electron beam resist composition

The invention claimed is: 1. An antiscattering resist composition for fabricating an integrated circuit die or an integrated circuit wafer, the composition comprising an anti-scattering compound, wherein the antiscattering compound is a polymetallic metal-organic complex comprising a primary metal complex (PMC). 2. The antiscattering resist composition of claim 1 , further comprising a scattering compound comprising one or more electron-containing π- and/or p-orbitals, suitably characterized by alkene and/or alkyne moieties, optionally wherein the scattering compound comprises one or more atoms capable of datively co-ordinating with the anti-scattering compound/complex. 3. The antiscattering resist composition of claim 1 , further comprising a secondary electron generator, which secondary electron generator is or comprises a compound comprising a d-block, p-block, or f-block metal species having an atomic number greater than or equal to 49; wherein: optionally the secondary electron generator is or comprises a compound having an effective atomic number (Z eff ) greater than or equal to 15, wherein: Z eff =Σα i Z i where Z i is the atomic number of the ith element in the compound, and α i is the fraction of the sum total of the atomic numbers of all atoms in the compound (i.e. the total number of protons in the compound) constituted by said ith element; optionally the antiscattering compound/complex forms one or more dative bonds with the secondary electron generator. 4. The antiscattering resist composition of claim 1 , wherein the antiscattering compound is heterometallic. 5. The antiscattering resist composition of claim 4 , wherein at least one metal species of the antiscattering compound is a transition metal species. 6. The antiscattering resist composition of claim 1 , wherein the antiscattering compound comprises: at least one trivalent metal species selected from the group consisting of Cr III , Fe III , V III , Ga III , Al III , and In III , most suitably Cr III ; and at least one divalent metal species selected from the group consisting of Ni II , Co II , Zn II , Cd II , Mn II , Mg II , Ca II , Sr II , Ba II , Cu II , and Fe II , most suitably Ni II . 7. The antiscattering resist composition of claim 1 , wherein the anti-scattering compound has a solubility of at least 10 mg/g in hexane. 8. The antiscattering resist composition of claim 1 , wherein the antiscattering compound comprises a ligand which is a linker component that is capable of acting as a lewis acid and/or a lewis base. 9. The antiscattering resist composition of claim 1 , wherein the antiscattering compound itself serves as a resist component, whose developer-solubility properties change following exposure to radiation. 10. The antiscattering resist composition of claim 1 , wherein the composition comprises 20-99 wt % solvent. 11. The antiscattering resist composition of claim 1 , wherein the composition is a solution. 12. The antiscattering resist composition of claim 11 , wherein the composition is free of any dispersed or suspended particulate matter. 13. The antiscattering resist composition of claim 1 , wherein the composition is spin-coatable. 14. The antiscattering resist composition of claim 1 , wherein the anti-scattering compound controls the flow and/or scattering of electrons when exposed to radiation. 15. The antiscattering resist composition of claim 1 , wherein the anti-scattering compound has a density less than or equal to 1.5 g/cm 3 . 16. A method of fabricating an integrated circuit die or an integrated circuit wafer comprising a plurality of integrated circuit dice, the or each die comprising a plurality of electronic components, wherein the method comprises: i) providing an antiscattering resist-coated substrate or applying an antiscattering resist coating to a substrate; and ii) exposing parts of the resist coating to radiation to provide an exposed resist coating; OR i) providing: a. a resist-coated substrate or applying a resist coating to a substrate; and b. a lithographic mask comprising a mask pattern characterised by regions of surface/substrate transparency juxtaposed with regions of surface/substrate opacity, wherein the lithographic mask is obtained by performing lithography upon an anti scattering resist-coated mask substrate; and ii) exposing parts of the resist coating, through the lithographic mask to radiation to provide an exposed resist coating; AND THEN iii) developing the exposed resist coating to generate a resist pattern layer, the resist pattern layer comprising: developer-insoluble coating portions of the resist coating (i.e. ridges); and an array of grooves extending through the resist pattern layer; iv) modifying the substrate, substrate surface, or parts thereof, underlying the resist pattern layer; v) removing the resist pattern layer to provide a modified substrate; vi) optionally repeating, one or more times, upon the modified substrate step iv) and/or steps i)-v) with either an antiscattering resist coating or an alternative resist coating, optionally using alternative radiation; vii) conductively interconnecting the electronic components of the or each die with conductors if not already performed during one or more substrate/substrate-surface modifying steps to provide an integrated circuit with external contact terminals; viii) optionally performing one or more further finishing steps; ix) optionally separating an integrated circuit die from a wafer comprising a plurality of integrated circuit dice; wherein: the antiscattering resist-coated substrate is a substrate coated with an antiscattering resist coating; the antiscattering resist coating comprises an optionally dried and/or cured antiscattering resist composition; the antiscattering resist composition is as claimed in claim 1 . 17. A method of manufacturing an integrated circuit package, the integrated circuit package comprising a plurality of pins and an integrated circuit die with external contact terminals conductively connected to the corresponding plurality of pins, wherein the method comprises: i) providing an integrated circuit die by or obtained by a method of fabricating an integrated circuit die as claimed in claim 16 ; ii) attaching the integrated circuit die to a package substrate, wherein the package substrate comprises electrical contacts, each of the electrical contacts being optionally connected or connectable to a corresponding pin; iii) conductively connecting each of the external contact terminals of the integrated circuit die to corresponding electrical contacts of the package substrate; iv) optionally and if necessary connecting the electrical contacts of the package substrate to corresponding pins; v) encapsulating the integrated circuit die. 18. A method of manufacturing a circuit board comprising an integrated circuit package comprising a plurality of pins, wherein the method comprises: i) providing an integrated circuit package by or obtained by a method of manufacturing an integrated circuit package as claimed in claim 17 ; ii) conductively connecting the integrated circuit package to a circuit board. 19. A method of manufacturing an electronic device or system, the electronic device or system comprising or being connectable to a power source and comprising a circuit board conductively connected to or connectable to a power source, wherein the method comprises: i) providing a circuit board by or obtained by the method of manufacturing a circuit board as claimed i