An apparatus includes a thermal chamber, a first reservoir containing a first liquid/vapor two-phase system, a second reservoir containing a second liquid/vapor two-phase system and conduits connecting the first reservoir and second reservoir to the thermal chamber. The first and second liquid/vapor two-phase systems include a liquid phase and a separate vapor phase. The apparatus also includes a conduit connecting the vapor phases of the first and second reservoirs. The apparatus can be used to thermally cycle an object placed in the thermal chamber or the vapor region of the first reservoir. The object can include one or more layers of an electrically or magnetically polarizable material.

A micromechanical sensor device and a corresponding production method include a substrate that has a front and a rear and a plurality of pillars that are formed on the front of the substrate. On each pillar, a respective sensor element is formed, which has a greater lateral extent than the associated pillar. A cavity is provided laterally to the pillars beneath the sensor elements. The sensor elements are laterally spaced apart from each other by respective separating troughs and make electrical contact with a respective associated rear contact via the respective associated pillar.

Disclosed herein is a non-Inductive voltage boost-converter (NVBC) for micro-power energy harvesting systems for energy storage and delivery applications. Current devices deliver a wide-range of micro-power having only up to 0.8V peak-voltage, but nominally 0.45V in lab test conditions. This voltage is not adequate in charging storage cells such as rechargeable batteries and also driving electronic circuits. Technology is in demand where a boost-converter must operate at MOS sub-threshold voltage (Sub-V.sub.TH) limits. Disclosed herein is a novel NVBC device that has eliminated the need of an inductor coil and associated high-speed switching circuits; thus achieving higher efficiency. The disclosed invention applies a simple self-synchronizing technique to adapt the NVBC automatically to the low-frequency energy signal of a pyroelectric device. A novel NVBC is presented for stabilized output of NVBC (S-NVBC). In an embodiment, the S-NVBC achieves an efficiency of 86%.

An energy harvest is disclosed. The disclosed energy harvest includes: a first charging member including a plurality of first protruding parts; and a second charging member including a plurality of second protruding parts arranged between the first protruding parts and including a material different from that of the first protruding parts. When at least one of the first and second charging members moves, side surfaces of the first protruding parts and side surfaces of the second protruding parts come into contact with each other, or gaps between the side surfaces of the first protruding parts and the side surfaces of the second protruding parts are changed. The energy harvest generates electrical energy from the contact or the gap change.

A portable power supply according to the present invention is provided with a combustion device (20) and a heating container (30) that retains an object to be heated, wherein at least a part of a portion of the heating container, the portion being directly heated by the combustion device, is provided with a magnetic metal plate (32) that has spontaneous magnetization and that generates electromotive force due to an anomalous Nernst effect induced by the heating, and wherein electrodes (33a, 33b) for drawing power are provided. Thus, the heating container for generating electricity has a simple configuration, and furthermore the portable power supply is provided with both the heating container and the combustion device.

A calorimeter with a heat sink that includes a diffusion-bonded block that has higher thermal conductivity laterally across the block than through the block. The diffusion-bonded block has multiple metallic layers that are diffusion-bonded together, with relatively higher thermal conductivity layers alternating with relatively lower thermal conductivity layers. The diffusion-bonded block may be used in differential scanning calorimeters, multi-cell differential scanning calorimeters, nano-differential scanning calorimeters and isothermal titration calorimeters, as well as other calorimeters that measure differential heat flow to and/or from a sample with respect to the heat flow to and/or from a reference.

A bi-stable micro-electrical mechanical system (MEMS) heat harvester is provided. A bi-stable MEMS cantilever located between a hot temperature surface and a cold temperature surface, and is made up of a first MEMS material layer, having a first coefficient of thermal expansion. A second MEMS material layer is in contact with the first MEMS material layer, and has a second coefficient of thermal expansion less than the first coefficient of thermal expansion. A tensioner, made from a material having a tensile stress greater than the stress of the first or second MEMS materials, is connected to the cantilever. The heat harvester also includes a mechanical-to-electrical power converter, which may be a piezoelectric device or an electret device. The bi-stable MEMS cantilever may include a thermal expander having a coefficient of thermal expansion greater than the second coefficient of thermal expansion. The thermal expander is connected to the tensioner.

IR emission devices comprising an array of polaritonic IR emitters arranged on a substrate, where the emitters are coupled to a heater configured to provide heat to one or more of the emitters. When the emitters are heated, they produce an infrared emission that can be polarized and whose spectral emission range, emission wavelength, and/or emission linewidth can be tuned by the polaritonic material used to form the elements of the array and/or by the size and/or shape of the emitters. The IR emission can be modulated by the induction of a strain into a ferroelectric, a change in the crystalline phase of a phase change material and/or by quickly applying and dissipating heat applied to the polaritonic nanostructure. The IR emission can be designed to be hidden in the thermal background so that it can be observed only under the appropriate filtering and/or demodulation conditions.

A pyroelectric device, comprising a plurality of layers of a polar dielectric material having a pyroelectric coefficient, p, wherein each layer exhibits pyroelectric properties; a plurality of conductive electrodes, wherein each conductive electrode is substantially in contact with at least a portion of one surface of a respective at least one of said plurality of layers of polar dielectric material, wherein said electrodes are electrically connected in a parallel configuration as to form a series of capacitors comprised of said plurality of layers of polar dielectric material and plurality of conductive electrodes.

A pyroelectric device having a substrate and a first electrode overlying at least a portion of the substrate. A plurality of spaced apart nanometer sized pyroelectric elements are electrically connected to and extending outwardly from the first electrode so that each element forms a single domain. A dielectric material is deposited in the space between the individual elements and a second electrode spaced apart from said first electrode is electrically connected to said pyroelectric elements.