Radiation source, metrology apparatus, lithographic system and device manufacturing method

The invention claimed is: 1. A radiation source apparatus comprising: a container comprising a first wall portion and a second wall portion that define a space configured to contain a gaseous medium in which radiation emitting plasma is generated following excitation of the gaseous medium by a driving radiation; and a thermal load applicator configured to apply a thermal load to the first wall portion to reduce a thermal gradient between the first wall portion and the second wall portion, thereby reducing stresses in the first and second wall portions. 2. The radiation source apparatus of claim 1 , wherein the thermal load applicator is configured to heat the first wall portion. 3. The radiation source apparatus of claim 1 , wherein the thermal load applicator is a passive component. 4. The radiation source apparatus of claim 1 , wherein the thermal load applicator comprises a reflector for reflecting part of the radiation emitted from the container back to the first wall portion. 5. The radiation source apparatus of claim 4 , wherein: the first wall portion is lower than the second wall portion; and the reflector has a focus point nearer to the first wall portion than the second wall portion. 6. The radiation source apparatus of claim 4 , wherein the reflector is convex. 7. The radiation source apparatus of claim 1 , wherein the thermal load applicator comprises a coating on the first wall portion which absorbs plasma emitted radiation thereby heating up the first wall portion. 8. The radiation source apparatus of claim 1 , wherein the load applicator is an active component. 9. The radiation source apparatus of claim 1 , wherein the thermal load applicator is a heater. 10. The radiation source apparatus of claim 9 , wherein: the first wall portion is lower than the second wall portion; and the heater is configured to heat the first wall portion more than the second wall portion. 11. The radiation source apparatus of claim 9 , wherein the heater is a radiation source. 12. The radiation source apparatus of claim 9 , wherein the heater heats the first wall portion by conduction. 13. The radiation source apparatus of claim 12 , wherein the heater is an electrical resistance heater. 14. The radiation source apparatus of claim 9 , further comprising: two or more electrodes positioned in the space on opposite sides of a plasma forming location within the container for use in igniting the plasma, and wherein the heater is configured to heat the electrodes and the first wall portion through conduction of heat from the heated electrodes to the first wall portion. 15. The radiation source apparatus of claim 14 , wherein the heater is an induction heater. 16. The radiation source apparatus of claim 1 , wherein the thermal load applicator is configured to cool the first wall portion. 17. The radiation source apparatus of claim 16 , wherein: the first wall portion is higher than the second wall portion; and the thermal load applicator is configured to direct a flow of gas against the first wall portion, thereby applying a cooling load to the first wall portion. 18. The radiation source apparatus of claim 1 , further comprising: a driving system configured to generate the driving radiation and to form the driving radiation into at least one beam focused on a plasma forming location within the container, and a collecting optical system configured to collect plasma emitted radiation and forming the plasma emitted radiation into at least one beam of radiation. 19. The radiation source apparatus of claim 18 , wherein the driving system comprises at least one laser for generating the driving radiation. 20. The radiation source apparatus of claim 18 , wherein: the driving radiation comprises a first range including infrared wavelengths, and the plasma emitted radiation comprises a second range, different from the first range, including at least one of visible radiation and ultraviolet radiation. 21. The radiation source apparatus of claim 18 , wherein the collecting optical system is configured to collect radiation emitted plasma in a longitudinal direction of the plasma. 22. The radiation source apparatus of claim 1 , further comprising a second container defining a space configured to contain the container and the thermal load applicator. 23. An inspection apparatus for measuring a property of a structure on a substrate, the apparatus comprising: a support for the substrate having the structure thereon; an optical system configured to illuminate the structure under predetermined illumination conditions and to detect predetermined portions of radiation diffracted by the component target structures under the illumination conditions; and a processor arranged to process information characterizing the detected radiation to obtain a measurement of the property of the structure, wherein the optical system includes a radiation source apparatus comprising: a container comprising a first wall portion and a second wall portion defining a space configured to contain a gaseous medium in which radiation emitting plasma is generated following excitation of the gaseous medium by a driving radiation; and a thermal load applicator configured to apply a thermal load to the first wall portion to reduce a thermal gradient between the first wall portion and the second wall portion, thereby reducing stresses in the first and second wall portions. 24. A lithographic system comprising: a lithographic apparatus comprising: an illumination optical system arranged to illuminate a pattern; a projection optical system arranged to project an image of the pattern onto a substrate; and an inspection apparatus for measuring a property of a structure on a substrate, the apparatus comprising: a support for the substrate having the structure thereon; an optical system configured to illuminate the structure under predetermined illumination conditions and to detect predetermined portions of radiation diffracted by the component target structures under the illumination conditions; a processor arranged to process information characterizing the detected radiation to obtain a measurement of the property of the structure, wherein the optical system includes a radiation source apparatus comprising: a container comprising a first wall portion and a second wall portion defining a space configured to contain a gaseous medium in which radiation emitting plasma is generated following excitation of the gaseous medium by a driving radiation; and a thermal load applicator configured to apply a thermal load to the first wall portion to reduce a thermal gradient between the first wall portion and the second wall portion, thereby reducing stresses in the first and second wall portions, and wherein the lithographic apparatus is configured to use the measurement results from the inspection apparatus in applying the pattern to further substrates. 25. A method of measuring a property of structures that have been formed by a lithographic process on a substrate, the method comprising: illuminating the structures using output radiation of a radiation source apparatus, the radiation source comprising: a container comprising a first wall portion and a second wall portion defining a space containing a gaseous medium in which radiation emitting plasma is generated following excitation of the gaseous medium by a driving radiation, and a thermal load