Patent Number: 054830648
Section: claims

1. A scanning microscope for scanning a sample having a surface disposed substantially perpendicular to a tip of a probe to generate a signal indicative of a property of the sample as a function of planar coordinates along the surface of the sample, comprising: (a) a rigid support structure  (b) scanning means having a fixed end mounted on said support structure and a free end movable along a plane substantially perpendicular to a main axis of the scanning means in response to control signals applied to the scanning means;  (c) a probe having a tip fixedly disposed in coaxial alignment with said main axis of the scanning means, said tip with a point on the surface of the sample precisely aligned with said tip to produce a signal indicative of said property of the sample at said point, thereby providing a map of such property as a function of position on the surface of the sample;  (d) a stand-off slidably mounted on said free end of the scanning means, said stand-off comprising a bottom surface slidably connected to the free end of the scanning means and a top surface comprising means for receiving said sample fixedly mounted thereon; and  (e) sample-positioner means mounted on said support structure and comprising means for slidably moving said stand-off over said free end of the scanning means in order to position the sample to a desired location for scanning, said sample-positioner means also comprising means for disengaging the stand-off after positioning of the sample and providing a sufficient gap between the stand-off and the sample-positioner means to prevent contact and resulting interference therebetween during scanning.  wherein said scanning means consists of a piezoelectric unit;  wherein said sample-positioner means comprises a plate having an opening sufficiently large to surround said stand-off, said plate being disposed coplanarly therewith, the plate comprising means for slidably moving said stand-off in order to position the sample to a desired location for scanning and further comprising means for disengaging the stand-off after positioning of the sample, so as to provide a sufficient gap between the stand-off and the sample-positioner means to prevent contact and resulting interference therebetween during scanning; and  wherein said scanning microscope further comprises:  apparatus for manually controlling the motion of the sample positioner means in response to a visual signal indicative of the relative position of a desired target point on the surface of the sample with respect to the tip of the probe; and  apparatus for automatically controlling the motion of the sample-positioner means to provide said gap between the stand-off and the sample-positioner means in response to a signal indicative of said desired target point on the surface of the sample having been placed in alignment with the tip of said probe.  (a) providing a rigid support structure;  (b) providing scanning means having a fixed end mounted on said support structure and a free end movable along a plane substantially perpendicular to main axis of said scanning means in response to control signals applied to the scanning means, said free end comprising means for slidably mounting said sample thereon;  (c) providing a probe having a tip fixedly disposed in coaxial alignment with said main axis of the scanning means, said tip interacting with a point, the surface of the sample precisely aligned with said tip to produce a signal indicative of a property of the sample at said point;  (d) mounting the sample on said free end of the scanning means;  (e) slidably moving said sample over said free end of the scanning means in order to position the sample such that a desired target thereon is aligned with said tip of the probe for scanning; and  (f) scanning the sample maintaining said tip and said scanning means in substantial coaxial alignment;  whereby a map of such property as a function of position on the surface of the sample is provided;  (g) providing a stand-off slidably mounted on said free end of the scanning means, said stand-off comprising a bottom surface slidably connected to the free end of the scanning means and a top surface to receive said sample fixedly mounted thereon; and  (h) providing sample-positioner means mounted on said support structure and to slidably move said stand-off over said free end of the scanning means in order to position the sample to a desired location for scanning, said sample-positioner means also to disengage the stand-off after positioning of the sample and provide a sufficient gap between the stand-off and the sample-positioner means to prevent contact and resulting interference therebetween during scanning; and  wherein step (d) is accomplished by fixedly mounting the sample on said top surface of the stand-off; and step (e) is accomplished by slidably moving said stand-off with said sample-positioner means to position the sample to said desired location for scanning and by thereafter disengaging the stand-off and providing a sufficient gap between the stand-off and the sample-positioner means to prevent contact and resulting interference therebetween during scanning. 2. The scanning microscope recited in claim 1, wherein said scanning means consists of a piezoelectric unit. 3. The scanning microscope recited in claim 2, wherein said piezoelectric unit consists of a piezoelectric ceramic tube. 4. The scanning microscope recited in claim 1, wherein said sample-positioner means comprises a plate having an opening sufficiently large to surround said stand-off, said plate being disposed coplanarly therewith, the plate comprising means for slidably moving said stand-off in order to position the sample to a desired location for scanning and further comprising means for disengaging the stand-off after positioning of the sample, so as to provide a sufficient gap between the stand-off and the sample-positioner means to prevent contact and resulting interference therebetween during scanning. 5. The scanning microscope recited in claim 4, wherein said plate is coupled to orthogonal plungers slidably engaged by conforming guides in said support structure, said plungers being engaged by cooperatively-aligned push-pull mechanisms for sliding the plungers in and out of the guides as necessary in order to effect a desired translation of the plate to target planar coordinates. 6. The scanning microscope recited in claim 5, wherein said push-pull mechanisms consists of screw gears engaged by drivegear devices mounted on the support structure. 7. The scanning microscope recited in claim 4, further comprising apparatus for manually controlling the motion of the plate in response to a visual signal indicative of the relative position of a desired target point on the surface of the sample with respect to the tip of the probe. 8. The scanning microscope recited in claim 1, further comprising apparatus for manually controlling the motion of the sample-positioner means in response to a visual signal indicative of the relative position of a desired target point on the surface of the sample with respect to the tip of the probe. 9. The scanning microscope recited in claim 1, further comprising apparatus for automatically controlling the motion of the sample-positioner means to provide said gap between the stand-off and the sample-positioner means in response to a signal indicative of a desired target point on the surface of the sample having been placed in alignment with the tip of said probe. 10. The scanning microscope recited in claim 1, wherein said stand-off further comprises a magnet and said free end of the scanning means comprises ferromagnetic material to improve the slidable connection therewith. 11. The scanning microscope recited in claim 1, 12. A method of analyzing a sample having an exposed surface by scanning microscopy, comprising the following steps: