The present teachings relate to high energy-density radioisotope micro power sources, such as micro size batteries, for use in micro electro mechanical systems.
The statements in this section merely provide background information related to the present disclosure and may not constitute prior art.
Large, weighty batteries have been significant obstacles to realizing the full potential of various miniaturized electrical and mechanical devices developed in the recent, remarkable growth of micro/nanotechnology. Micro electro mechanical systems (MEMS) devices have been developed for use as various sensors and actuators; as biomedical devices; as wireless communication systems; and as micro chemical analysis systems. The ability to employ these systems as portable, stand-alone devices in both normal and extreme environments depends, however, upon the development of power sources compatible with the MEMS technology. In the worst case, the power source is rapidly depleted and the system requires frequent recharge for continuous, long-life operation.
A significant amount of research has been devoted to the development of higher energy density, light weight power sources. For example, solar cells can be used to provide electrical power for MEMS. Micro fuel cells have also been developed for many applications and a micro combustion engine has been reported. One of the major disadvantages of using chemical-reaction-based power sources is that the power density of the fuels gets lower as the size of the systems is reduced. A second major challenge is that the performance of these systems drops significantly when they are designed to achieve longer lives. In such cases, refueling (or recharging) is not a viable option because it cannot be done easily in tiny, portable devices. And finally, the aforementioned power sources cannot be used in extreme environments because either the reaction rate is influenced by temperature, and/or there is no sunlight available for powering the device.
Known radioisotope power sources were introduced in late 1950s. The concept of such direction conversion methods (alphavoltalics and betavoltaics) utilizes energy from radioactive decay. The radioisotope material emits α or β particles, which are coupled to a rectifying junction like a semiconductor p-n junction (or diode). The particles propagate to the rectifying junction and produce electron-hole pairs (EHPs). The EHPs are separated by the rectifying junction and converted into electrical energy.
Known crystalline solid-state semiconductors such as silicon carbides (SiC) or silicon based semiconductors have been formerly used for low energy beta voltaic cells using the rectifying junctions. However, one of the major drawbacks to using such known solid-state betavoltaic converters is that the ionizing radiation degrades the efficiency, performance, and lifetime of the conversion device. The primary degradation mechanism is the production of charge carrier traps from lattice displacement damage over the periods of time. Similarly but more seriously, high energy alpha particles can cause severe damage to the rectifying junctions of the solid-state semiconductors.
The present disclosure relates to high energy-density radioisotope micro power sources, such as micro size batteries, for use in micro electro mechanical systems.
In various embodiments, the present disclosure provides a method of constructing an amorphous, i.e., not crystalline, solid-state high energy-density micro radioisotope power source device. In such embodiments, the method comprises depositing the pre-voltaic semiconductor composition, comprising a semiconductor material and a radioisotope material, into a micro chamber formed within a body of a high energy-density micro radioisotope power source device. The method additionally includes heating the body to a temperature at which the pre-voltaic semiconductor composition will liquefy within the micro chamber to provide a liquid state composite mixture. Furthermore, the method includes cooling the body and liquid state composite mixture such that liquid state composite mixture solidifies to provide a solid-state composite voltaic semiconductor, thereby providing a solid-state high energy-density micro radioisotope power source device.
In various other embodiments, the present disclosure provides a method of constructing an amorphous solid-state high energy-density micro radioisotope power source device, wherein the method comprises combining at least one semiconductor material with at least one radioisotope material and at least one dopant to provide a pre-voltaic semiconductor composition. The method additionally includes depositing the pre-voltaic semiconductor composition into a micro chamber formed in a bottom portion of a high energy-density micro radioisotope power source device. The bottom portion of the high energy-density micro radioisotope power source device includes a first electrode disposed in a bottom of the micro chamber. The method further includes disposing a top portion of the high energy-density micro radioisotope power source device onto the bottom portion of the high energy-density micro radioisotope power source device, thereby covering the micro chamber and providing an assembled body of the high energy-density micro radioisotope power source device. The top portion of the high energy-density micro radioisotope power source device includes a second electrode disposed at a top of the micro chamber.
Still further, the method includes heating the assembled body to a temperature at which the pre-voltaic semiconductor composition will liquefy within the micro chamber such that the at least one semiconductor material, at least one radioisotope material and at least one dopant are thoroughly and uniformly mixed to provide a liquid state composite mixture. The method still yet further includes applying a compression bonding process to the heated assembled body to form a ‘leak-proof’ seal between the top and bottom portions of the high energy-density micro radioisotope power source device. Furthermore, the method includes cooling the assembled body and liquid state composite mixture such that liquid state composite mixture solidifies to provide a solid-state composite voltaic semiconductor, and thereby providing a solid-state high energy-density micro radioisotope power source device.
In yet other embodiments, the present disclosure provides a solid-state high energy-density micro radioisotope power source device. In such embodiments, the device includes a dielectric and radiation shielding body having an internal cavity formed therein. The device additionally includes a first electrode disposed a first end of the cavity, and a second electrode disposed at an opposing second end of the cavity and spaced apart from the first electrode such that a micro chamber is provided therebetween. The device further includes a solid-state composite voltaic semiconductor disposed within the micro chamber between and in contact with the first and second electrodes. The solid-state composite voltaic semiconductor fabricated by (1) combining at least one semiconductor material with at least one radioisotope material to provide a pre-voltaic semiconductor composition; (2) depositing the pre-voltaic semiconductor composition into the micro chamber; (3) heating the body to a temperature at which the pre-voltaic semiconductor composition will liquefy within the micro chamber such that the at least one semiconductor material and at least one radioisotope material are thoroughly and uniformly mixed to provide a liquid state composite mixture; and (4) cooling the body and liquid state composite mixture such that liquid state composite mixture solidifies to provide the solid-state composite voltaic semiconductor.
Further areas of applicability of the present teachings will become apparent from the description provided herein. It should be understood that the description and specific examples are intended for purposes of illustration only and are not intended to limit the scope of the present teachings.
The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present teachings in any way.
Corresponding reference numerals indicate corresponding parts throughout the several views of drawings.
The following description is merely exemplary in nature and is in no way intended to limit the present teachings, application, or uses. Throughout this specification, like reference numerals will be used to refer to like elements.
Referring to
Generally, the micro power source device 10 includes a dielectric and radiation shielding body 14 having an internal cavity 18 formed therein. Disposed at one end of the cavity 18 is an ohmic contact layer, or electrode, 22 and disposed at the opposing end of the cavity is a rectifying contact layer 26, or electrode, e.g., a Schottky contact layer. The ohmic contact layer 22 and rectifying contact layer 26 are spaced apart a selected distance, thereby defining a micro chamber 28. The internal cavity 18 can have any dimensions and volume necessary to provide the micro chamber 28 of any desired size and volume. The ohmic contact layer includes an ohmic lead 30 disposed on and/or extending from an exterior surface of the body 14. The rectifying contact layer 26 includes a rectifying lead 34 disposed on or extending from an exterior surface of the body 14. The micro power source device 10 additionally includes a solid-state composite voltaic semiconductor 38 disposed within the micro chamber 28, between and in contact with the ohmic contact layer 22 and the rectifying layer 34.
The ohmic contact layer 22 can comprise any suitable electrically conductive material. For example, in various embodiments, the ohmic contact layer 22 comprises nickel. The rectifying contact layer 26 can comprise any suitable electrically conductive material, for example, in various embodiments the rectifying contact layer 26 comprises aluminum. The voltaic semiconductor 38 is a composite comprising one or more semiconductor materials integrated with one or more radioisotope materials. In various embodiments, the voltaic semiconductor 38 can further include one or more dopants, i.e., impurities or doping materials, such as phosphorus, boron, carbon, etc. The one or more dopants can be employed to control various behavioral characteristics of the micro power source device 10. In various embodiments, the voltaic semiconductor 38 can comprise the semiconductor material Selenium (Se) integrated with the radioisotope material Sulfur-35 (35S) and the dopant phosphorus.
Referring now to
Then, a dielectric and radiation shielding material 14B is deposited onto the substrate 14A around the rectifying contact layer and over the Schottkey lead 34 to provide a bottom portion 28A of the micro chamber 28, as indicated at 204 in
Subsequently, the pre-voltaic semiconductor composition 38A is disposed into the bottom portion micro chamber 28, as indicated at 208 in
Then, the top dielectric and radiation shielding substrate 14C with the ohmic contact layer 22 is placed over the bottom portion of the micro chamber 25 filled with the pre-voltaic semiconductor composition 38A, and in contact with the dielectric and radiation shielding material 14, as indicated at 212 in
While the bottom substrate 14A, the dielectric and radiation shielding material 14B, the top substrate 14C, and the liquefied composite mixture 38B are being heated, a thermo compression bonding process is applied to bond the top substrate 14C to the dielectric and radiation shielding material 14B, thereby forming the body 14 (comprised of the bonded together bottom substrate 14A, dielectric and radiation shielding material 14B, and top substrate 14C), as indicated at 216 in
Next, the sealed body 14 and liquefied mixture are allowed to cool such that the liquefied mixture solidifies to form the solid-state voltaic semiconductor 38, thereby providing the micro radioisotope power source device 10, as indicated at 218 in
Referring now to
When the rectifying contact layer 26, having work function qΦm, contacts the solid-state voltaic semiconductor 38, having a work function qΦs, charge transfer occurs until the Fermi levels align at equilibrium. When Φm>Φs, the solid-state voltaic semiconductor 38 Fermi level is initially higher than that of the rectifying contact layer 26 before contact is made. At the junction of the rectifying contact layer 26 and solid-state voltaic semiconductor 38, an electric field is generated in the depletion region. When the ionizing radiation deposits energy throughout the depletion region near the junction of the rectifying contact layer 26 and solid-state voltaic semiconductor 38, the electric field will separate the electron-hole pairs in different directions (electrons toward the semiconductor 38 and holes toward the rectifying contact layer 26). This results in a potential difference between the rectifying and ohmic contact layers 26 and 22.
It is envisioned that the contact area between the solid-state voltaic semiconductor 38, and the ohmic and rectifying contact layers 22 and 26 can be increased to increase the conversion efficiency, i.e., increase the creation of electron-hole pairs (EHP).
For example, referring to
The thickness of the ohmic and rectifying contact layer fingers 22A and 26A can be adjusted to increase the efficiency of the micro power source device 10. Beta particles can penetrate the thin metal structures and contribute EHP generation within solid-state voltaic semiconductor 38 disposed between the ohmic and rectifying contact layer fingers 22A and 26A.
Referring now to
In various implementations, the nanostructures 42 and/or 46 can be grown, deposited or formed on the interior surfaces of the respective ohmic and/or rectifying contact layers 22 and/or 26 using a porous alumina oxide (PAO) template. The PAO template can be controlled to form any desirable size nanostructures. For example, the PAO template can be utilized to grow, deposit or form, the nanostructures 42 and/or 46 having diameters between 100 nm and 400 nm with heights between 15 μm and 30 μm. Alternatively, the nanostructures 42 and/or 46 can be grown, deposited or formed on the interior surfaces of the respective ohmic and/or rectifying contact layers 22 and/or 26 by electroplating a suitable metal, such as Ni, Au, Cu, Pd, Al, Ag, and Co, through a seed layer.
An exemplary method of growing, depositing or forming the nanostructures 42 and/or 46 on the interior surfaces of the respective ohmic and/or rectifying contact layers 22 and 26 can be as follow. First, the rectifying contact layer 26 can be deposited on the glass substrate 14A by sputtering, e.g., a 0.5 μm thick layer of nickel. Then a second metal layer can be deposited on top of the bottom electrode, e.g., a 0.2 μm thick layer of aluminum. Next, the second layer is anodized with oxalic acid to create porous membranes, e.g., porous aluminum membranes. Then, the same metal as that used for the rectifying contact layer 26, e.g., nickel, is deposited through the porous membranes by electroplating. In various implementations, the electrolyte can comprise NiSO4.6H2O of 15 g/L, H3BO3 of 35 g/L, and Di water with 0.3-0.6 mA/cm2. Subsequently, the porous membranes, e.g., the aluminum porous membranes, are removed by an aqueous solution, e.g., NaOH, thereby providing the nanostructures 46 on the rectifying contact layer 26. The nanostructures 42 can be grown, deposited or formed on the ohmic contact layer 22 in a substantially similar manner.
An exemplary high energy-density micro radioisotope power source device 10 was constructed as described herein and tested. The test procedure and results are as follows.
In this example, selenium (Se) was used as the semiconductor materials and Sulfur-35 (35S) was used as the radioisotope material. Sulfur-35 was used for two main reasons. Firstly, 35S is a pure beta emitter source with maximum decay energy of 0.167 MeV, an average beta decay energy of 49 keV and a half-life of 87.3 days. The range of the 49 keV beta is less than 50 microns in selenium which is ideal for depositing all of the decay energy in the voltaic semiconductor 38. Secondly, 35S is chemically compatible with selenium. Selenium has semiconducting properties in both the solid (amorphous) and liquid state. The chemical bond model of amorphous selenium is categorized to be lone pair semiconductors (twofold coordination) because the electron configuration is [Ar]3d104S24p4, which implies that the properties of Se are primarily influenced by the two non-bonding p-orbitals of group 16 chalcogen, which exhibited in covalent interaction bonding. Se atoms tend to bond in lone pairs within the semiconductor in either helical chain (trigonal phase) formation or Se8 ring (monoclinic phase) formation. Once Se melts (Tm=221° C.), the structure of the liquid phase Se is mostly a planar chain polymer with the average of 104˜106 atoms per chain near Tm, and a small fraction of Se8 ring.18
The liquefied composite mixture 38B naturally wets the surface of the electrodes, i.e., the ohmic and rectifying contact layers 22 and 26, very well and enhances the electrical contact by reducing contact resistance at both the rectifying and ohmic contacts. In addition, the melting point of the pre-voltaic semiconductor mixture 38A can be lower than the original melting temperatures of the individual materials by employing an eutectic mixture.
First, the heterogeneous equilibrium between solid and liquid phases of a two-component selenium-sulfur system was investigated. A binary phase diagram shown in
Different metals were used to form a rectifying junction, e.g., a Schottky junction, and an ohmic junction. The characteristics of a semiconductor diode can be determined by the barriers at metal-semiconductor junctions due to the different work functions. High work function metal such as nickel (5.1-5.2 eV) or gold (5.1-5.4 eV) can be used as an ohmic contact, which results in easy hole flow across the junction. For rectifying behavior for p-type semiconductor (amorphous selenium), aluminum with a low work function (ϕm) of 4.1-4.3 eV can be used.
In the present example, the composited selenium-sulfur was placed inside the 20 μm thick of SU8 polymer reservoir with 1 cm2 active area and sandwiched by two electrodes, i.e., between the ohmic and rectifying contact layers 22 and 26. A 0.3 μm-thick aluminum layer was deposited on the bottom glass substrate 14A to provide a rectifying, or Schottky, contact electrode and a 0.3 μm-thick nickel was deposited on the top glass substrate 14C to provide an ohmic contact electrode. The mixed selenium-sulfur Se35S was deposited in the bottom portion 28A of the micro chamber 28 and the top substrate 14C with the rectifying contact electrode disposed thereon, was placed on top. The device was rapidly heated to 275° C. followed by thermo compression bonding to create a leak-tight package. The I-V characteristic curves were measured by the Semiconductor Parameter Analyzer (Keithley 2400) with current measure resolution of 1 fA (10−15 A).
Referring now to
Referring now to
Additionally, the dark current was observed with a short-circuit current (ISC) of 0.15 nA. This negative current without external bias could be driven by thermionic emission due to the thermal generation of carriers of liquid semiconductor. As further shown in
Consequently, a total power efficiency of 1.207% from both beta flux and heat flux was obtained.
Although the micro radioisotope power source device 10 has been exemplarily described herein as including the semiconductor material Selenium (Se) integrated with radioactive source material Sulfur-35 (35S), it is envisioned that the micro radioisotope power source device 10 can include other suitable semiconductor materials and/or other suitable chemically compatible radioactive source materials. For example, in various embodiments, the micro radioisotope power source device 10 can include one or more other semiconductor materials, such as Te, Si, etc., and the respective semiconductor material can be integrated with one or more other beta or alpha emitting radionuclides, such as Pm-147 and Ni-63, that decay with essentially no gamma emission.
Additionally, the mixing ratio of the semiconductor material(s), the radioisotope material(s) and dopant(s) can be varied to provide any desired performance of the micro power source device 10 at any selected ambient temperature. Hence, the high energy-density micro radioisotope power source device 10, as described herein, can efficiently operate at a wide range of temperatures, e.g., from approximately 0° C., or less, to 250° C., or greater.
The high energy-density micro radioisotope power source device 10, as described herein, offers the potential to revolutionize the application of MEMS technologies, particularly when the MEMS systems are employed in extreme and/or inaccessible environments. The ability to use MEMS as thermal, magnetic and optical sensors and actuators, as micro chemical analysis systems, and as wireless communication systems in such environments can have a major impact in future technological developments. For example, it could increase public safety by providing an enabling technology for employing imbedded sensor and communication systems in transportation infrastructure (e.g. bridges and roadbeds).
Additionally, some advantages of the high energy-density micro radioisotope power source device 10, as described herein, are (1) energy densities that are 104 to 106 times greater than that available from chemical systems, (2) constant output even at extreme temperatures and pressures, and (3) long lifetimes (with the appropriate choice of isotope). Additionally, the high energy-density micro radioisotope power source device 10, as described herein, overcomes fundamental drawbacks, such as lattice displacement damage, of using alpha emitting isotopes in solid-state conversion devices.
Still further advantages include the elimination of radiation self-absorption losses and losses between the radioisotope and the betavoltaic cell, common in known radioisotope power sources. This is due to the radioactive material and the semiconductor material being mixed together within the micro chamber 28. For the selection of the radioactive source, high beta spectrum energy and high specific activity are two main parameters to be considered. Furthermore, common interaction losses can be reduced by adjusting the thickness of solid-state composite voltaic semiconductor 38. The thickness of solid-state composite voltaic semiconductor 38 has to be thin enough so that the beta radiation can cover whole volume of the solid-state composite voltaic semiconductor 38 encapsulated within the micro chamber 28.
Another advantage is that the encapsulation of the solid-state composite voltaic semiconductor 38 within the micro chamber, as described herein, can provide secure self-shielding and eliminate the need of extra shielding structures. It provides a device that is considerably smaller than the conventional devices, and it is very cost effective because the solid-state composite voltaic semiconductor 38, as described herein, does not contain costly silicon-based materials.
The description herein is merely exemplary in nature and, thus, variations that do not depart from the gist of that which is described are intended to be within the scope of the teachings. Such variations are not to be regarded as a departure from the spirit and scope of the teachings.
This application is a divisional of U.S. patent application Ser. No. 12/723,370 filed on Mar. 12, 2010, which claims the benefit of U.S. Provisional Application No. 61/209,954, filed on Mar. 12, 2009. The disclosures of the above applications are incorporated herein by reference in their entirety.
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20140159541 A1 | Jun 2014 | US |
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61209954 | Mar 2009 | US |
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Child | 14182908 | US |