Abstract: A system for calorimetry includes a well having a volume for receiving a sample, an input feature to facilitate reception of the sample in the well, a light source to irradiate the well and the sample with incident light, and a photonic sensor chip disposed at the bottom of the well. The photonic sensor chip includes plural nanohole array (NHA) sensors. A light detector is configured to measure transmission of light through the NHA sensors to obtain a series of extraordinary optical transmission (EOT) measurements. Frame elements secure and mutually couple the light source, the photonic sensor chip, the light detector, and the input feature to form a calorimetry unit. A processor is configured to calculate a calorimetry measurement as a function of the series of EOT measurements, the calorimetry measurement being indicative of energy released as a result of the sample in the well undergoing a change.

Abstract: A method of obtaining an aliquot of a frozen sample contained in a container includes moving a coring device into the sample and then withdrawing it to obtain a frozen sample core. The location from which the core is taken is selected to be at a radial position where the concentration of at least one substance of interest in the frozen sample core is representative of the overall concentration of that substance in the sample notwithstanding any concentration gradients that may exist in the frozen sample. Another method includes taking two different frozen sample cores from the same sample from radial positions selected such that the concentration of one or more substances of interest in the combined sample cores is representative of the overall concentration of said at least one substance in the sample notwithstanding any radial concentration gradients. A robotic system is programmed or hardwired to implement the methods.

Abstract: Methods and apparatus for ultra-sensitive temperature sensing and calorimetry. Radiation is directed at a thin electrically conductive film having one or more small apertures. The incident radiation excites surface plasmons on a first surface of the electrically conductive film, and energy associated with the surface plasmons couples to an opposite surface of the electrically conductive film, where surface plasmon-enhanced radiation (SPER) is emitted from the aperture(s). A temperature-sensitive fluid or solid dielectric material is disposed contiguous with at least a portion of the electrically conductive film, such that a temperature change in the dielectric material alters a resonance condition for the SPER. Measurable changes in the SPER due to altered resonance conditions provide for an ultrasensitive temperature sensor that can detect small temperature changes in the dielectric material.

Abstract: Methods and apparatus for ultra-sensitive temperature sensing and calorimetry. Radiation is directed at a thin electrically conductive film having one or more small apertures. The incident radiation excites surface plasmons on a first surface of the electrically conductive film, and energy associated with the surface plasmons couples to an opposite surface of the electrically conductive film, where surface plasmon-enhanced radiation (SPER) is emitted from the aperture(s). A temperature-sensitive fluid or solid dielectric material is disposed contiguous with at least a portion of the electrically conductive film, such that a temperature change in the dielectric material alters a resonance condition for the SPER. Measureable changes in the SPER due to altered resonance conditions provide for an ultrasensitive temperature sensor that can detect small temperature changes in the dielectric material.

Abstract: Methods and apparatus for producing small, bright nanometric light sources from apertures that are smaller than the wavelength of the emitted light. Light is directed at a surface layer of metal onto a light barrier structure that includes one or more apertures each of which directs a small spot of light onto a target. The incident light excites surface plasmons (electron density fluctuations) in the top metal surface layer and this energy couples through the apertures to the opposing surface where it is emitted as light from the apertures or from the rims of the apertures. Means are employed to prevent or severely limit the extent to which surface plasmons are induced on the surface at the aperture exit, thereby constraining the resulting emissions to small target areas.

Abstract: Methods and apparatus for producing small, bright nanometric light sources from apertures that are smaller than the wavelength of the emitted light. Light is directed at a surface layer of metal onto a light barrier structure that includes one or more apertures each of which directs a small spot of light onto a target. The incident light excites surface plasmons (electron density fluctuations) in the top metal surface layer and this energy couples through the apertures to the opposing surface where it is emitted as light from the apertures or from the rims of the apertures. Means are employed to prevent or severely limit the extent to which surface plasmons are induced on the surface at the aperture exit, thereby constraining the resulting emissions to small target areas.

Abstract: Apparatus and methods for treating a biological fluid with light and for inactivating contaminants in biological fluid. The biological fluid is contacted with a light source providing a high intensity light to the biological fluid. The biological fluid may include a quantity of a photochemical agent that when activated by light is operable to cause inactivation of at least some of the contaminants.

Abstract: Apparatus and methods for treating a biological fluid with light and for inactivating contaminants in biological fluid. The biological fluid is contacted with a light source providing a high intensity light to the biological fluid. The biological fluid may include a quantity of a photochemical agent that when activated by light is operable to cause inactivation of at least some of the contaminants.