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Fabrication method for digital etching of nanometer-scale level structures

WO2018026412A1

Description (excerpt)

Fabrication Method for Digital Etching of Nanometer-Scale Level Structures CROSS-REFERENCE TO RELATED APPLICATIONS [0001] The present application claims priority to U.S. Provisional Patent Application Serial No. 62/369,812, which was filed on 2 August 2016 and which is incorporated herein by reference. FIELD OF THE INVENTION [0002] The present invention relates in general to nanometer-scale level structures and methods of making and using same, and in particular to surface profile optical elements having nanometer-scale level structures and methods of making and using same. BACKGROUND OF THE INVENTION [0003] Diffractive optical elements ("DOE") are used in many applications, such as optica! storage devices, processing, sensing, and communications. A DOE serves to wave-shape incoming light Whereas standard refractive optical elements, such as mirrors and lenses, are often bulky, expensive and limited to a specific use, DOEs are generally light-weight, compact, easily replicated, and can modulate complicated wavefronts. [0004] A Fresnel lens is an example for a DOE. Like a classical convex leas, the Fresnel lens focuses parallel light onto a single focal point. The Fresnel lens' design can be considered conceptually as being created by removing slabs of glass that do not contribute to the bending of light rays to the focal point. Conventional Fresnel lens fabrication requires that the lens profile needs to be etched into, for example, a glass wafer. This fabrication is done by step-wise, lite first etched profile, a so-called Fresnel plate, is not a good approximation of tile ideal Fresnel shape. A conventional Fresnel plate is only ~ 41% effective (i.e., only around 41% of transmitted light gets focused). [0005] Other examples of DOEs include beam shapers, e.g., beam horaogenizers. A DOE can also encode complex structures, which produce visible images in the far field when the light passes through the DOE structure. The fabrication of a DOE, which encodes the images, is a rather complex process. The gray-scale level of each image pixel is encoded by the phase shift of the light which passes through the DOE. This is achieved by encoding the depth of the features, which are etched in clear dielectric. [0006] A typical DOEs consists of many features with a typical size of 7 μm, with depths varying continuously between 0 and 600 nm, to produce a. phase shift between 0 and π for a 632 nm irradiation wavelength. The depth of the etched features must be precisely fabricated, and the etch roughness must be as low as possible. For example, the roughness of the etched features for a DOE, which encodes an image with 16 colors, must be smoother than 30 nm. [0007] The three-dimensional ("3D") surface profile of the DOE determines how the element will shape an incoming wavefront. Hence* the key feature of any DOE is its complicated 3D surface topography. Some gratings can be blazed or cut, but most DOE are made by micro- fabrication techniques. This usually involves a lithography step and an etching step: A photosensitive resist layer is applied and exposed with a mask under ultra-violet ("UV") light. After developing, the mask pattern, is transferred into the resist layer. The resist layer then defines where material is etched away. This is normally done with reactive ion etching CRIP'). The step depth is defined by resist layer profile and the RIB etch recipe. [0008] Multiple levels are made by multiple photo-lithography and etching steps in standard, multilevel fabrication methods. However, such standard, multilevel fabrication methods work better in theory than in practice. For example, the use of multi photo- masks is a challenge because each mask must be aligned with respect to the previous etch step. The alignment is never perfect, generating displacements in x- and y-directions and rotational, errors. With the number of lithography and etching step cycles the alignment errors add up. This is the reason why most DOEs only have 8-16 step levels. The theoretical efficiency (i.e., the fraction of the light that gets focused s) for a DOE with 8. steps and without fabrication errors like misalignment or surface roughness is no better than 95 %. Fabrication errors will reduce this efficiency and further degrade optical performance. Increasing the number of steps in theory will increase the efficiency, but in practice, fabrication errors have been found to reduce the efficiency with larger effect. [0009] An alternative, conventional micro-fabrication method to fabricate 3D profiles includes the use of standard gray-tone lithography. Gray-tone lithography (also known as grayscale lithography) is a standard lithography process that results in continuously variable resist profiles. A gray-tone optical mask is used to transmit only a poition of the intensity of incident light, partially exposing sections of a positive photoresist to a certain depth, litis exposure renders the top portion of the photoresist layer more soluble in a developer solution, while the bottom portion of the photoresist lay

Filing details

Inventors
Marc Christophersen
Assignee
… America, As Represented By The Secretary Of The Navy Naval Research Laboratory
Filed
May 17, 2017
Granted
Application pending

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