Patent Number: 052987590
Section: claims

1. A photo-cracker cell for placement between a source cell and a growth chamber of apparatus for growth of III-V, IV, and II-VI semiconductor layers, comprising: (a) a vacuum chamber provided with inlet means and outlet means, said inlet means operatively associated with said source cell and said outlet means operatively associated with said growth chamber, said inlet means and said outlet means opposite each other in said vacuum chamber so as to define a beam path for a beam of molecular species emitted from said source cell to said growth chamber; and  (b) a source of ultraviolet radiation oriented so as to impinge on said beam of molecular species along said beam path, said source of ultraviolet radiation having an intensity sufficient to dissociate said molecular species to atomic species.  (a) at least one source cell for the generation of a beam of species employed in said growth of said layers;  (b) a growth chamber wherein said growth of said layers occurs; and  (c) a photo-cracker cell interposed between said at least one source cell and said growth chamber, said photo-cracker cell comprising:  (a) generating a beam of molecular Group V or Group VI species in a source cell;  (b) directing said beam toward a growth chamber for growth of said semiconductor layers; and  (c) exposing said beam to a source of ultraviolet radiation between said source cell and said growth chamber, said source of ultraviolet radiation having an intensity sufficient to photodissociate said molecular species to atomic species. 2. The photo-cracker cell of claim 1 wherein said apparatus comprises molecular beam epitaxy apparatus and said source cell comprises an effusion source. 3. The photo-cracker cell of claim 1 wherein said apparatus comprises gas-source molecular beam epitaxy apparatus and said source cell comprises a thermal cracker cell. 4. The photo-cracker cell of claim 1 wherein said apparatus comprises metal-organic molecular beam epitaxy apparatus and said source cell comprises a gas injector cell. 5. The photo-cracker cell of claim 1 wherein said vacuum chamber is provided with an elliptical reflective cavity, said elliptical reflective cavity defining two foci, with said source of ultraviolet radiation located along one focus and with said beam path located along the other focus and substantially parallel thereto. 6. The photo-cracker cell of claim 5 wherein said source of ultraviolet radiation comprises a UV high intensity lamp. 7. The photo-cracker cell of claim 6 wherein said source of ultraviolet radiation is housed inside an ultrahigh vacuum-compatible quartz tube that extends into said vacuum chamber along said one focus. 8. The photo-cracker cell of claim 6 wherein said source of ultraviolet radiation is oriented substantially parallel to said beam path. 9. The photo-cracker cell of claim 5 further including a reflective shield positioned between said source of ultraviolet radiation and said beam path to reduce coating of said source of ultraviolet radiation with said species. 10. The photo-cracker cell of claim 5 wherein said source of ultraviolet radiation comprises a UV laser. 11. The photo-cracker cell of claim 10 wherein said vacuum chamber includes means for directing a beam emitted by said UV laser along the axis of said molecular beam path. 12. Apparatus for growth of III-V, IV, and II-VI semiconductor layers, said apparatus comprising: 13. The apparatus of claim 12 wherein said apparatus comprises molecular beam epitaxy apparatus and said source cell comprises an effusion source. 14. The apparatus of claim 12 wherein said apparatus comprises gas-source molecular beam epitaxy apparatus and said source cell comprises a thermal cracker cell. 15. The apparatus of claim 12 wherein said apparatus comprises metal-organic molecular beam epitaxy apparatus and said source cell comprises a gas injector cell. 16. The apparatus of claim 12 wherein said vacuum chamber is provided with an elliptical reflective cavity, said elliptical reflective cavity defining two foci, with said source of ultraviolet radiation located along one focus and with said beam path located along the other focus substantially parallel thereto. 17. The apparatus of claim 16 wherein said source of ultraviolet radiation comprises a UV high intensity lamp. 18. The apparatus of claim 17 wherein said source of ultraviolet radiation is housed inside an ultra-high vacuum-compatible quartz tube that extends into said vacuum chamber along said one focus. 19. The apparatus of claim 17 wherein said source of ultraviolet radiation is oriented substantially parallel to said beam path. 20. The apparatus of claim 16 further including a reflective shield positioned between said source of ultraviolet radiation and said beam path to reduce coating of said source of ultraviolet radiation with said species. 21. The apparatus of claim 16 wherein said source of ultraviolet radiation comprises a UV laser. 22. The apparatus of claim 21 wherein said vacuum chamber includes means for directing a beam emitted by said UV laser along the axis of said molecular beam path. 23. A process for producing substantially monomeric Group V or Group VI species for use in epitaxy growth of III-V, IV, and II-VI semiconductor layers, comprising: 24. The process of claim 23 wherein said Group V and Group VI species are selected from the group consisting of arsenic, antimony, tellurium, and selenium dimers and tetramers. 25. The process of claim 23 wherein said Group V and Group VI species comprise metal-organic molecules containing an element selected from the group consisting of arsenic, antimony, tellurium, and selenium. 26. The process of claim 23 wherein said beam of molecular species is directed along one focus of an ellipse and said source of radiation positioned at the other focus of said ellipse and focused onto said beam of molecular species.