Abstract: A mixing apparatus includes a well plate assembly including a fixed support, and a well movable with respect to the fixed support. A fixed sensor mount has a first portion disposed above the well and a second portion disposed within the well. A plurality of electromagnets are operable to move the well plate assembly vertically with respect to the fixed sensor mount and the fixed support.

Abstract: A sensing device includes a first substrate having a plurality of TSVs extending therethrough, and a second substrate positioned adjacent the first substrate, with the TSVs being electrically connected to the second substrate. At least one carbon nanotube sensor is positioned on the first substrate. Each of a plurality of contact pads is positioned on the first substrate and on one of the carbon nanotube sensors such that each contact pad is electrically connected to one of the TSVs and the one of the carbon nanotube sensors, and such that an end of the one of the carbon nanotube sensors is embedded in the contact pad.

Abstract: A process of analyzing a sample by Raman spectroscopy and X-ray photoelectron spectroscopy (XPS) includes providing a sample having a sample surface within a vacuum chamber, performing a Raman spectroscopic analysis on a plurality of selected areas of the sample surface within the vacuum chamber to map an area of the sample surface comprising the selected areas, the Raman spectroscopic analysis including identifying one or more face in one or more of the selected areas of the sample surface, and performing an X-ray photoelectron spectroscopy (XPS) analysis of one or more selected areas of the sample surface containing at least one chemical and/or structural feature identified by the Raman spectroscopic analysis, wherein the duration of the XPS analysis of a given selected area of the sample surface is longer than the duration of the Raman spectroscopic analysis of that given selected area.

Abstract: A process of analyzing a sample by Raman spectroscopy and X-ray photoelectron spectroscopy (XPS) includes providing a sample having a sample surface within a vacuum chamber, performing a Raman spectroscopic analysis on a plurality of selected areas of the sample surface within the vacuum chamber to map an area of the sample surface comprising the selected areas, the Raman spectroscopic analysis including identifying one or more face in one or more of the selected areas of the sample surface, and performing an X-ray photoelectron spectroscopy (XPS) analysis of one or more selected areas of the sample surface containing at least one chemical and/or structural feature identified by the Raman spectroscopic analysis, wherein the duration of the XPS analysis of a given selected area of the sample surface is longer than the duration of the Raman spectroscopic analysis of that given selected area.

Abstract: A mixing apparatus includes a well plate assembly including a fixed support, and a well movable with respect to the fixed support. A fixed sensor mount has a first portion disposed above the well and a second portion disposed within the well. A plurality of electromagnets are operable to move the well plate assembly vertically with respect to the fixed sensor mount and the fixed support.

Abstract: A sensing device includes a first substrate having a plurality of TSVs extending therethrough, and a second substrate positioned adjacent the first substrate, with the TSVs being electrically connected to the second substrate. At least one carbon nanotube sensor is positioned on the first substrate. Each of a plurality of contact pads is positioned on the first substrate and on one of the carbon nanotube sensors such that each contact pad is electrically connected to one of the TSVs and the one of the carbon nanotube sensors, and such that an end of the one of the carbon nanotube sensors is embedded in the contact pad.

Abstract: Devices and methods are disclosed having (a) an exposed semiconducting single walled carbon nanotube channel on the surface of a substrate, wherein the exposed semiconducting single walled carbon nanotube channel is functionalized with a capture moiety cognate to a target analyte, (b) a source electrode and a drain electrode connecting opposite ends of the exposed semiconducting single walled carbon nanotube channel, and (c) wherein the source electrode and the drain electrode are electrically connected in a manner to detect changes in current through the exposed semiconducting single walled carbon nanotube channel in response to analyte in contact therewith,