Classifications

• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
  • H01L31/00—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof
  • H01L31/18—Processes or apparatus specially adapted for the manufacture or treatment of these devices or of parts thereof
• • G—PHYSICS
  • G21—NUCLEAR PHYSICS; NUCLEAR ENGINEERING
  • G21H—OBTAINING ENERGY FROM RADIOACTIVE SOURCES; APPLICATIONS OF RADIATION FROM RADIOACTIVE SOURCES, NOT OTHERWISE PROVIDED FOR; UTILISING COSMIC RADIATION
  • G21H1/00—Arrangements for obtaining electrical energy from radioactive sources, e.g. from radioactive isotopes, nuclear or atomic batteries
  • G21H1/06—Cells wherein radiation is applied to the junction of different semiconductor materials
• • Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
  • Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
  • Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
  • Y02E10/00—Energy generation through renewable energy sources
  • Y02E10/50—Photovoltaic [PV] energy
  • Y02E10/547—Monocrystalline silicon PV cells

Definitions

• This invention relates to converters of ionizing radiation energy to electricity (EMF) and can be used in drone aviation, highly explosive areas, e.g. in mines, in nighttime indicators located in difficultly accessible areas, in medicine (cardiac pacemakers) etc.
• EMF ionizing radiation energy to electricity
• Disadvantages of the structure are the relatively small volume of the irradiated semiconducting material due to the small irradiated surface area and the limited penetration depth of ionizing beta radiation (less than 25 ⁇ ) the short minority carrier charge lifetime due to the structural defects during vanadium doping of the working area.
• the surface of the microchannel walls as well as the front and rear surfaces of semiconductor wafer have microtextures, almost the entire semiconductor wafer surface except its side surface comprises a doped layer forming a p-n junction and a diode structure, doped layer is covered with a radioactive semiconductor layer acting as a current collecting contact in to the diode structure and is a beta radiation source, the doped layer and the bottom layer replicate the shape of the textured surface, and the contact to the base region of the semiconductor wafer is located on the side surface.
• Disadvantages of the semiconductor converter are the complex technology of its production and filling of the penetrating channels with solid- state radioactive isotopes. Low quality of the textured surface of penetrating channels and hence intense leakage that do not allow achieving high specific power of the converter.
• the prototype of the first object of this invention is a 3D structure of a semiconductor beta-voltaic converter, transforming radiation to electricity (US 20080199736, publ. 21.08.2008) wherein at the top surface of a low-doped n (p) conductivity type semiconductor wafer vertical are located channels, the surfaces of which comprise heavily doped p + ⁇ n + ) regions forming vertical p-n junctions with the semiconductor wafer, the channels are filled with conducting radioactive isotope material forming the electrode, i.e. anode (cathode) of the converter diode, and the bottom wafer surface a horizontal heavily doped n + (p + ) contact layer is located the surface of which a metallic electrode of anode (cathode) is situated .
• the prototype of the second subject of this invention is the method of fabricating a 3D structure of a semiconductor diode used as a beta-voltaic converter of the beta radiation of 63 Ni isotope to electricity (US 20080199736, publ. 21.08.2008) which comprises the formation of a horizontal heavily doped n + (p + ) conductivity type layer on the bottom surface of a low-doped n (p) conductivity type wafer, the formation of vertical channels by etching the top surface of the semiconductor wafer, doping of the channel wall surfaces, the deposition of radioactive isotope metal for electrode, i.e.
• anode onto the top surface of the wafer and into the channels, and the deposition of a metal layer for electrode, i.e. anode (cathode), onto the bottom surface of the wafer.
• a metal layer for electrode i.e. anode (cathode) onto the bottom surface of the wafer.
• Disadvantages of the known method are the complex and insufficiently reproducible technology of synthesizing p-n junctions in the channels reducing the efficiency of the converter and, most importantly, a high level of dark current (I D ) of the bulk p-n junction dramatically reducing the idle voltage (Ui d ) of the converter and hence the maximum output power (P max ) because
• the technical result of the first subject of this invention is an increase in the energy E u per unit volume of the converter due to the large emitting surface of the radioactive isotope (S em ) and hence the area of the bulk p-n junction (S pn>b ).
• the design of the ionizing radiation converter with cross-linked structure comprises a weakly doped n(p) conductivity type semiconductor wafer the bulk of which comprises vertical channels one end of which is connected to the wafer surface, and the channel wall surfaces comprise heavily doped p + ⁇ n + ) conductivity type regions forming vertical p-n junctions with the semiconductor wafer.
• the channels are filled with conducting radioactive isotope material forming the electrode, i.e. anode (cathode), of the converter diode and the bottom surface of the wafer comprises a horizontal heavily doped n + (p + ) conductivity type layer the surface of which comprises a metallic electrode, i.e. anode (cathode), of the converter.
• conducting radioactive isotope material forming the electrode, i.e. anode (cathode) of the converter diode and the bottom surface of the wafer comprises a horizontal heavily doped n + (p + ) conductivity type layer the surface of which comprises a metallic electrode, i.e. anode (cathode), of the converter.
• the top surface of the wafer comprises a horizontal heavily doped p + (n + ) conductivity type region forming a horizontal p-n junction.
• the surfaces of the vertical channels are low-doped and have the n(p) conductivity type, wherein one end of each of the vertical channels is connected to the bottom wafer surface and the other end, i.e. the bottom of each of the vertical channels is at a distance from the top surface of the wafer, the distance being greater than the total depth of the horizontal p-n junction in the space charge region formed by it.
• the technical result of the second subject of this invention includes a simplification of the converter fabrication technology.
• the fabrication method comprises the formation of a horizontal heavily doped n + (p + ) conductivity type layer on the bottom surface of a low-doped n (p) conductivity type wafer, the formation of vertical channels by etching the top surface of the semiconductor wafer, doping of the channel wall surfaces, the deposition of radioactive isotope metal for electrode, i.e. anode (cathode), onto the top surface of the wafer and into the channels, and the deposition of a metal layer for electrode, i.e. anode (cathode), onto the bottom surface of the wafer.
• the vertical channels are formed by etching the bottom surfaces of the low-doped n(p) conductivity type wafer, following which the channel wall surfaces are doped with a donor (acceptor) impurity and a horizontal p-n junction is formed on the top surface of the wafer by doping with an acceptor (donor) impurity.
• FIG. 1 shows a section of the converter structure for the first structure example
• Fig. 2 shows a bottom view of the converter structure for the first structure example
• Fig. 3 shows a section of the converter structure for the second structure example
• Fig. 4 shows a bottom view of the converter structure for the second structure example.
• the design of the converter of this invention comprises a low-doped n(p) conductivity type semiconductor wafer (1), the bottom surface of the wafer comprises an n + (p + ) conductivity type contact layer (2), the wafer bulk comprises vertical channels (3) wherein one end of each of the vertical channels is connected to the bottom wafer surface, the top wafer surface comprises an n + (p + ) conductivity type region (4) of a horizontal p-n junction wherein the region forms a space charge region (5) with the wafer, the surface of the n + (p + ) conductivity type region comprises metallic radioactive isotope forming the anode (6) of the diode, and the bottom wafer surface and the channels comprise metallic radioactive isotope forming the cathode (7).
• the operation principle of the converter of this invention is based on the ionization of the semiconducting material (e.g. silicon) by beta radiation of isotopes, e.g. nickel, tritium, strontium, cobalt etc..
• the electron/hole pairs forming due to the irradiation are separated by the field of the p-n junction in the space charge region and produce a difference of potentials between the p + and n regions of the converter (the photovoltaic EMF). Simultaneously, part of the electron/hole pairs can alternatively be accumulated by the field of the p-n junction in the quasi-neutral region at the diffusion length distance.
• Embodiments of the Invention Different examples of beta converter design are possible that differ in their technical parameters.
• the converter shown in Figs. 1&2 has the highest unit power but is quite expensive due to the large quantity of nickel in the channels.
• the converter shown in Figs. 3&4 requires far smaller quantity of 63 Ni and is therefore cheaper while having a lower unit power.
• the isotope source can be selected, for example, as 63 Ni having a long half decay time of 50 years and emitting electron radiation with an average energy of 17 keV and a maximum energy of 64 keV which bears almost no hazard for health. This electron energy is lower than the defect formation energy in silicon which is 160 keV.
• the absorption depth of electrons with an average energy of 17 keV in silicon is approx. 3.0 ⁇ ; for 90% absorption this depth is 12 ⁇ ⁇ ⁇ .
• the radiation source can be not necessarily a beta radiation source but alternatively an alpha radiation
• the fabrication method of the converter of this invention comprises the following sequence of process steps.
• the leakage current of the equal area p-n junction formed in the channel is three orders of magnitude greater:
• ⁇ is the thermal potential and I sc is the short circuit current generated by the radioactive radiation.
• the converter power is determined by the following relationship:
• P max . p i is 1.7 nW
• P max.b is 0.08 nW.
• the technical advantage of this invention are an increase in the unit power and the efficiency of the converter and a simplification and a lower price of its technology.
• the ionization current receiver is a horizontal (not vertical) p-n junction having a relatively small area (S p-n , nsi ) located on a high quality polished top surface of the wafer, this minimizing the dark current and increasing the idle voltage and hence the unit power of the converter.

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• Manufacturing & Machinery (AREA)
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• Computer Hardware Design (AREA)
• Microelectronics & Electronic Packaging (AREA)
• Power Engineering (AREA)
• Photovoltaic Devices (AREA)
• Light Receiving Elements (AREA)
• Crystals, And After-Treatments Of Crystals (AREA)
• Dc-Dc Converters (AREA)

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• 2017
  • 2017-01-31 RU RU2017103167A patent/RU2659618C1/ru active
  • 2017-09-11 DE DE112017006974.2T patent/DE112017006974T5/de not_active Withdrawn
  • 2017-09-11 KR KR1020197024967A patent/KR102595089B1/ko active IP Right Grant
  • 2017-09-11 WO PCT/RU2017/000663 patent/WO2018143838A1/en active Application Filing
  • 2017-09-11 JP JP2019541228A patent/JP2020507073A/ja active Pending
  • 2017-09-11 CN CN201780089174.1A patent/CN110494929A/zh active Pending
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