Abstract: A nitride cantilever is formed with an integral conical silicon tip at the free end thereof. A top layer of silicon dioxide is patterned into a tip mask on a doped or epitaxial silicon layer in a silicon substrate. Photoresist is spun on the silicon substrate and patterned and the silicon is etched to define a cantilever pattern in the substrate with the tip mask positioned to be near the free end of a nitride cantilever to be subsequently formed. A bottom layer of silicon dioxide is formed on the silicon substrate and then patterned and etched to define a masking aperture on the bottom silicon dioxide layer. The bottom of the silicon substrate is anisotropically etched through the masking aperture and the etch stops at the doped silicon layer. Alternatively, electrochemical etching is done by applying an electric potential across the P-N junction between the doped silicon layer and the appropriately-doped substrate. This releases the free end of the doped silicon layer from the silicon substrate.

Abstract: Acoustic radiators which are focused diffractively by multi-discrete-phase binary Fresnel lenses are provided for applications, such as acoustic ink printing. Standard semiconductor integrated circuit techniques are available for fabricating such lenses in compliance with design specifications having relatively tight tolerances, including specifications for integrated lens arrays demanding substantial precision in the relative spatial positioning of several lenses. The diffractive performance of these lenses simulate concave refractive lenses, even though the lenses preferably have generally flat geometries. To that end, the lenses advantageously are defined by patterning acoustically flat surfaces, such as an acoustically flat face of a substrate or, better yet, an acoustically flat face of a layer of etchable material which is grown or otherwise deposited on an acoustically flat surface of an etch resistant substrate.

Abstract: In accordance with the present invention, an acoustic ink printer comprises a pool of liquid ink having a free surface in intimate contact with the inner face of a perforated membrane. The printer addresses all pixel positions within its image field via substantially uniform, relatively large diameter apertures which extend through the membrane on centers that are aligned with respective ones of the pixel positions. In operation, one or more focused acoustic beams selectively eject individual droplets of ink from the ink menisci that extend across the apertures. Accordingly, the membrane is positioned and the bias pressure that is applied to the ink is selected so that the menisci essentially remain within the focal plane of such beam or beams.

Abstract: Apparatus and method for forming a microfabricated cantilever with a single crystal, integral silicon tip on a nitride cantilever. A nitride-silicon-nitride sandwich structure is patterned and etched to form a cantilever structure, exposing sidewall portions of the silicon layer. The exposed sidewall portions of the silicon layer are oxidized to form oxide sidewalls. The top nitride layer is removed and the silicon layer is anisotropically etched and removed except fo a tetrahedral silicon tip formed on the rear nitride layer. The tetrahedral silicon tip has one exterior surface bounded by a (111) plane with two additional exterior surfaces bounded by the oxide sidewall. The oxide sidewall is removed to provide a tetrahedral silicon tip at the free end of the nitride cantilever. Alternative cantilever materials such as polysilicon and deposited oxide can be substituted for nitride.

Abstract: An acoustic ink printhead having improved ink drop ejection control includes a substrate having an array of acoustic lenses at its upper surface for bringing rf acoustic waves to a predetermined focus and a layer of acoustically reflective material of a thickness equal to an odd multiple of one quarter of the wavelength of the acoustic rf waves passing through it having openings corresponding to and positioned above each lens. Ink from an ink pool is allowed to couple acoustically to the lenses at each opening for receiving the focussed acoustic rf wave, while the layer acoustically isolates the interstitial regions between each lens by reflecting the acoustic rf waves incident on the upper surface of the substrate in those regions.

Abstract: A sample and selective support structure mounted on a platform in a scanning tunneling microscope includes a double spring support with the springs overlapped to reduce overall length of the support. In a preferred embodiment, a rigid support structure supports a first platform. A second platform is positioned around and spaced from the first platform and includes a plurality of support members extending therefrom. A first set of springs is attached to the rigid support structure and to the second platform for supporting the second platform, and a second set of springs is attached to the second platform and to the first platform for supporting the first platform. By attaching the second set of springs to the rigid members extending from the second platform, the first and second sets of springs can be overlapped, thereby reducing the overall length of the spring support without reducing the effective length of the springs.

Abstract: An ink transport comprising a perforated belt or web configured carrier having a longitudinally repetitive pattern of relatively large diameter apertures extending through it is provided for delivering a regularly refreshed supply of liquid ink to the printhead of an acoustic ink printer. Ink is loaded into the apertures from the top and/or the bottom. Furthermore, the apertures within each repeat of the aperture pattern are on centers which cause them to laterally align, on a one-for-one basis, with the individual pixel positions within a pagewidth address field. The printhead, in turn, includes one or more droplet ejectors, each of which supplies an acoustic beam which converges to a relatively sharp (i.e., narrow waist diameter) focus approximately on the free surface of the ink entrained in the apertures, and the radiation pressure exerted by each beam is modulated to acoustically eject individual droplets of ink from the apertures on command to print an image on a nearby recording medium.

Abstract: Polychromatic acoustic ink printers are disclosed, including several embodiments which utilize a single printhead for ejecting droplets of ink on command from a transport which carries the different colored inks past the printhead in timed synchronism with the printing of the corresponding color separations. If desired, a diluent also may be provided to permit the printing of an intensity mask.A variety of transports are described, including single ply solid or perforated films, as well as laminated multiple ply films composed of a solid or perforated lower layer, a perforated or mesh upper layer, and, in some embodiments, one or more perforated intermediate layers. Furthermore, it is disclosed that a perforated transport may be overcoated with a patterned metallization so that an electric field can be generated to assist in controlling the droplet ejection process. Some of the transports are designed to carry the inks in a liquid state.

Abstract: The output surface of an acoustic printhead having one or more concave acoustic beam forming devices for supplying focused acoustic beams to eject droplets of ink on demand from the surface of a pool of ink is planarized by filling those concave devices with a solid material having an acoustic impedance and an acoustic velocity which are intermediate the acoustic impedance and the acoustic velocity, respectively, of the ink and of the printhead. This not only facilitates the cleaning of the printhead, but also eliminates the edges upon which an optional ink transport or the like may tend to drag. The outer surface of the filler may be essentially flush with the face of the printhead, or the filler may overcoat the printhead.

Abstract: To facilitate the fabrication of acoustic printheads, arrays of spherical acoustic lenses are provided for bringing rf acoustic waves to essentially diffraction limited focii at or near the free surface of a pool of ink. These lenses produce focal patterns which are relatively free of localized amplitude variations, so they may be employed to fabricate acoustic printheads having relatively stable characteristics for acoustic printing.

Abstract: A printhead for an acoustic printer comprises one or more acoustic microlenses, each of which brings an acoustic beam to focus approximately at the free surface of a pool of ink for ejecting individual droplets of ink from the pool on demand. As used herein, an "acoustic microlens" is defined as being an acoustic lens having an aperture diameter which is less than an order of magnitude greater than the wavelength of the incident acoustic wave (i.e., the acoustic wave which illuminates the lens).

Abstract: The invention relates to a multi-layered piezoelectric acoustic transducer for generating layers of the same piezoelectric material are provided such tool alternate layers have different crystallographic orientations and different piezoelectric coupling coefficients. The layers may be provided so that alternate layers have crystallographic orientations which provide maximum electro-acoustic coupling and layers which provide minimum electro-acoustic coupling.

Abstract: To facilitate the use of hot melt inks in acoustic ink printers of the type having a printhead including one or more acoustic droplet ejectors for supplying focused acoustic beams, such a printer comprises a carrier for transporting a generally uniformly thick film of hot melt ink across its printhead, together with a heating means for liquefying the ink as it nears the printhead. The droplet ejector or ejectors are acoustically coupled to the ink via the carrier, and their output focal plane is essentially coplanar with the free surface of the liquefied ink, thereby enabling them to eject individual droplets of ink therefrom on command. The ink, on the other hand, is moved across the printhead at a sufficiently high rate to maintain the free surface which it presents to the printhead at a substantially constant level.

Abstract: Provision is made spatially stabilizing standing capillary surface waves in fixed and repeatable locations with respect to stationary external references. For spatially stabilizing such a wave on the free surface of a volume of liquid, the wave propagation characteristics of the free surface of liquid are periodically varied in a spatially stable manner at a spatial frequency equal to the spatial frequency of the standing wave or a subharmonic thereof, thereby locking the crests and troughs of the standing wave in predetermined spatial locations. A spatially periodic pattern of notches in a wall or base plate bounding the free surface of the liquid may be employed to physically modulate its wave propagation characteristics at a suitable spatial frequency. Alternatively freely propagating secondary capillary surface waves may be launched from spatially periodic sites along the free surface of the liquid to actively modulate its wave propagation characteristics at the diesired spatial frequency.

Abstract: Provision is made for selectively addressing inividual crests of traveling or standing capillary surface waves to eject droplets from the selected crests on command. To that end, the addressing mechanism of this invention locally increase the surface pressure acting on the selected crests and/or locally reduce the surface tension of the liquid within the selected crests. The preferred addressing mechanisms have sufficient spatial resolution to address a single crest substantially independently of its neighbors.Discrete addressing mechanisms having a plurality of individual addressing elements are especially attractive for liquid ink printing and similar applications, not only because their individual addressing elements may be spatially fixed, but also because the spatial frequency of their addressing elements may be matched to the spatial frequency of the capillary wave. Such frequency matching enables selected crests of the capillary wave to be addressed in parallel, such as for line printing.

Abstract: A nozzleless print head for ink jet printing and the like comprises one or more essentially planar surface acoustic wave transducers which are submerged at a predetermined depth in a liquid filled reservoir, so that each of the transducers launches a converging cone of coherent acoustic waves into the reservoir, thereby producing an acoustic beam which comes to a focus at or near the surface of the reservoir (i.e., the liquid/air interface). The acoustic beam may be intensity modulated to control the ejection timing, or an external source may be used to extract droplets from the acoustically excited liquid on the surface of the reservoir on demand. Regardless of the timing mechanism employed, the size of the ejected droplets is determined by the waist diameter of the focused acoustic beam.

Abstract: Disclosed is a digital memory in which data is stored by establishing perturbations in a surface of a substrate and thereafter identifying the perturbations by establishing a tunnel electron current between the surface of the substrate and a movable probe. The perturbations can be physical, electrical, or magnetic, for example, such that the tunneling electron current is affected thereby. Storage area for a bit of data can be reduced to the order of 10.sup.-4 square microns, and the volume of a 100 megabyte mass storage can be reduced to the order of a cubic centimeter.

Abstract: An acoustic microscope and method are disclosed in which an object under investigation is excited by two energy sources. Acoustic waves are propagated from the heated area of the object and the waves are detected and analyzed.

Abstract: An acoustic apparatus and method for microscopic imaging and spectroscopy. The apparatus includes a plurality of devices for exciting an object of interest so that acoustic waves are propagated from the object. These devices include lasers, x-ray sources, microwave generators, ultraviolet sources, and electric current generators. The acoustic waves propagated from the object of interest are detected and the object of interest and the acoustic wave detector are moved with respect to each other in a raster scanning pattern. The magnitude of the detected acoustic waves and the corresponding raster pattern of the object are recorded so that a visual image of the object can be obtained. In addition, the frequency of the exciting electromagnetic radiation that excites the object can be varied so that both the absorption spectra and the Raman frequency mode of the object can be determined.

Abstract: A scanning acoustic microscope wherein a high frequency acoustic plane wave is focused by an acoustic lens to scan an object at the focal plane and is then recollimated by a second acoustic lens, detected with a piezoelectric detector, and the detected acoustic signal applied to an oscilloscope to provide a visual display.