Abstract: A system and method A method of growing an elongate nanoelement from a growth surface includes: (a) cleaning a growth surface on a base element; (b) providing an ultrahigh vacuum reaction environment over the cleaned growth surface; (c) generating a reactive gas of an atomic material to be used in forming the nanoelement; (d) projecting a stream of the reactive gas at the growth surface within the reactive environment while maintaining a vacuum of at most 1×10?4 Pascal; (e) growing the elongate nanoelement from the growth surface within the environment while maintaining the pressure of step c); (f) after a desired length of nanoelement is attained within the environment, stopping direction of reactive gas into the environment; and (g) returning the environment to an ultrahigh vacuum condition.

Abstract: A system and method A method of growing an elongate nanoelement from a growth surface includes: a) cleaning a growth surface on a base element; b) providing an ultrahigh vacuum reaction environment over the cleaned growth surface; c) generating a reactive gas of an atomic material to be used in forming the nanoelement; d) projecting a stream of the reactive gas at the growth surface within the reactive environment while maintaining a vacuum of at most 1×10?4 Pascal; e) growing the elongate nanoelement from the growth surface within the environment while maintaining the pressure of step c); f) after a desired length of nanoelement is attained within the environment, stopping direction of reactive gas into the environment; and g) returning the environment to an ultrahigh vacuum condition.

Abstract: A system and method A method of growing an elongate nanoelement from a growth surface includes: a) cleaning a growth surface on a base element; b) providing an ultrahigh vacuum reaction environment over the cleaned growth surface; c) generating a reactive gas of an atomic material to be used in forming the nanoelement; d) projecting a stream of the reactive gas at the growth surface within the reactive environment while maintaining a vacuum of at most 1×10?4 Pascal; e) growing the elongate nanoelement from the growth surface within the environment while maintaining the pressure of step c); f) after a desired length of nanoelement is attained within the environment, stopping direction of reactive gas into the environment; and g) returning the environment to an ultrahigh vacuum condition.

Abstract: A novel molecular beam epitaxy deposition process for precisely growing structurally robust films and coatings containing germanium and various fluoride compounds for use as an optical filter. The process comprises depositing two (2) materials having different indices of refraction via molecular beam epitaxy at a temperature significantly lower than the optimal growth temperature. At such lower temperature, layers of the respective compounds are grown, via molecular beam epitaxy, such that the layers contain large concentrations of dislocations. Once the film or coating has been grown to the desired thickness, the material deposited is allowed to cool to room temperature and may then be used in a wide range of applications.

Abstract: Apparati and methods for varying the flux of a molecular beam emanating from an effusion cell are disclosed. The apparatus includes a means for controllably adjusting the angular distribution of a molecular field effusing from a source material within the effusion cell, therein adjusting the flux of the beam. The method herein disclosed, with respect to the related apparati, including the step of selectively altering the angular distribution of an effusing molecular field, produced by a heated source material, which comprises the molecular beam, thereby varying the flux of the beam.

Abstract: Apparati and methods for varying the flux of a molecular beam emanating from an effusion cell are disclosed. The apparatus includes a means for controllably adjusting the angular distribution of a molecular field effusing from a source material within the effusion cell, therein adjusting the flux of the beam. The method herein disclosed, with respect to the related apparati, including the step of selectively altering the angular distribution of an effusing molecular field, produced by a heated source material, which comprises the molecular beam, thereby varying the flux of the beam.

Abstract: A substrate upon which infrared elements are formed has a crystalline base layer, preferably comprised of silicon; a first strain superlattice layer formed upon the base layer; and a first matched superlattice layer formed upon the strain superlattice layer. The strain superlattice layer and the matched superlattice layer mitigate defect propagation from the base layer to the infrared detector elements. Optionally, a plurality of additional or second strain and matched superlattice layers are formed in an alternating layer configuration upon the first matched superlattice layer so as to achieve enhanced defect filtering.