Semiconductor Sensor
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Accused Products
Abstract
A semiconductor sensor determines physical and/or chemical properties of a medium, in particular a pH sensor. The semiconductor sensor has an electronic component with a sensitive surface, said component being constructed for its part on the basis of semiconductors with a large band gap (wide-gap semiconductor). The sensitive surface is provided at least in regions with a functional layer sequence which has an ion-sensitive surface. The functional layer sequence has at least one layer which is impermeable at least for the medium and/or the materials or ions to be determined.
84 Citations
76 Claims
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1-31. -31. (canceled)
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32. A semiconductor sensor for determining at least one of physical properties and chemical properties of a medium, comprising:
an electronic component with a sensitive surface, the electronic component being constructed on the basis of semiconductors with a large band gap, the sensitive surface, at least in regions with a functional layer sequence, having an ion-sensitive surface, the ion-sensitive surface being orientated away from the sensitive surface and is coated with at least one layer, the functional layer sequence being impermeable at least for at least one of (a) the medium and (b) one of materials and ions to be determined.
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33. The semiconductor sensor according to claim 32, wherein the sensor is a pH sensor.
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34. The semiconductor sensor according to claim 32, wherein an uppermost layer of the functional layer sequence is chemically resistant.
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35. The semiconductor sensor according to claim 33, wherein the uppermost layer is resistant to at least one of lyes and acids.
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36. The semiconductor sensor according to claim 34, wherein the lyes include sodium hydroxide (NaOH) and the acids include nitric acid (HNO3).
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37. The semiconductor sensor according to claim 33, wherein the uppermost layer comprises a material that includes at least one of an oxide, a metal oxide, a titanium oxide, an aluminium oxide, a magnesium oxide, a metal, a ceramic, a nitride-based material, carbon-containing compounds, and mixtures thereof.
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38. The semiconductor sensor according to claim 35, wherein each of the at least one of the compounds and the components of the material has one of a stoichiometric and non-stoichiometric ratio.
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39. The semiconductor sensor according to claim 35, wherein the nitride-based material includes at least one of titanium nitride and silicon nitride.
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40. The semiconductor sensor according to claim 35, wherein the carbon-containing compounds includes at least one of diamond and diamond-like carbon (DLC).
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41. The semiconductor sensor according to claim 35, wherein the uppermost layer is an oxide, the layer being produced as a layer by at least one of (a) a thermal oxidation of the surface of a previously applied non-oxidised layer, (b) an electrochemical deposition and (c) a sputter deposition of the oxide.
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42. The semiconductor sensor according to claim 35, wherein the uppermost layer is an oxide, the layer being produced as a layer by a thermal subsequent oxidation.
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43. The semiconductor sensor according to claim 32, wherein the functional layer sequence has an ion-selective diffusion barrier layer which is impermeable for at least one type of ions.
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44. The semiconductor sensor according to claim 32, wherein the functional layer sequence has a bonding layer which is disposed between the component and further layers of the functional layer sequence.
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45. The semiconductor sensor according to claim 32, wherein the bonding layer includes at least one of titanium (Ti), aluminium (Al), titanium-tungsten alloy (TiW), silicon (Si) and a polymer.
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46. The semiconductor sensor according to claim 32, wherein the semiconductor with a large band gap has a band gap=2 eV.
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47. The semiconductor sensor according to claim 46, wherein the semiconductor with a large band gap includes at least one diamond, gallium nitride (GaN) and silicon carbide (SiC).
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48. The semiconductor sensor according to claim 32, wherein the electronic component comprises one of a doped volume material, an undoped volume material, and a heterostructure disposed at least in regions.
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49. The semiconductor sensor according to claim 48, wherein the volume material is a III-V semiconductor.
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50. The semiconductor sensor according to claim 48, wherein the volume material is gallium nitride (GaN).
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51. The semiconductor sensor according to claim 32, wherein the electronic component is one of (a) one of a lateral component and a laterally constructed component and (b) one of a vertical component and a vertically constructed component.
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52. The semiconductor sensor according to claim 32, wherein the electronic component is a high electron one of mobility transistor (HEMT), a MODFET (modulation-doped field effect transistor), a metal semiconductor field effect transistor (MESFET, metal semiconductor FET), a d-FET, a SIT (static induction transistor) and a heterostructure bipolar transistor (heterojunction bipolar transistor, HBT), the gate electrode being formed one of on and by the ion-sensitive surface of the functional layer sequence.
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53. The semiconductor sensor according to claim 52, wherein the electronic component has an uppermost semiconductor layer which is orientated towards the functional layer sequence and comprises one of aluminium nitride (AlN), gallium nitride (GaN), indium nitride (InN), aluminium gallium nitride, indium gallium nitride, and indium aluminium nitride.
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54. The semiconductor sensor according to claim 53, wherein the aluminium gallium nitride has a formula AlxGa1-xN where x is at least 0.01 and at most 0.3, the indium gallium nitride has a formula InxGa1-xN where x is at least 0.01 and at most 0.3, and the indium aluminium nitride has a formula InxAl1-xN where x is greater than 0 and less than 1.
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55. The semiconductor sensor according to claim 32, further comprising:
an encapsulation, the surface of the sensor being covered by the encapsulation except in at least parts of the exposed surface of the functional layer sequence.
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56. The semiconductor sensor according to claim 55, wherein the surface of the sensor is covered by the encapsulation with the exception at least of parts of electrical contacts.
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57. The semiconductor sensor according to claim 55, wherein the encapsulation includes at least one of an epoxy resin and polyimides.
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58. The semiconductor sensor according to claim 55, wherein the encapsulation includes at least one of at least one electrically insulating resistant, at least one chemically resistant and a chemically inert material.
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59. The semiconductor sensor according to claim 32, wherein the electronic component is disposed one of directly and above intermediate layers on a substrate.
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60. The semiconductor sensor according to claim 59, wherein the substrate includes at least one of silicon (Si), sapphire (Al2O3), silicon carbide (SiC), diamond, iridium (Ir) and combinations thereof.
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61. The semiconductor sensor according to claim 59, further comprising:
a buffer intermediate layer disposed between the substrate and the electronic component.
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62. The semiconductor sensor according to claim 61, wherein the buffer layer includes at least one of gallium nitride (GaN), aluminium nitride (AlN), aluminium gallium nitride (AlGaN), diamond and combinations thereof.
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63. The semiconductor sensor according to claim 32, wherein the electronic component has at least one ohmic contact region.
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64. The semiconductor sensor according to claim 63, wherein at least one electrical contact is disposed on the electronic component to conduct away electrical signals from the electronic component, at least one of the electrical contacts being connected to at least one of the ohmic contact regions in one of an electrically conductive manner and a semiconductive manner.
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65. The semiconductor sensor according to claim 32, wherein the electronic component is disposed on a carrier.
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66. The semiconductor sensor according to claim 32, wherein the electronic component is disposed on a carrier together with the substrate.
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67. The semiconductor sensor according to claim 65, wherein the carrier is connected to one of the electronic component and the substrate by at least one of glueing, soldering and flip-chip.
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68. The semiconductor sensor according to claim 32, wherein in order to conduct signals of the electronic component to the exterior, the electronic component has at least one ohmic contact region and the carrier has at least one strip conductor as electrical contact which is connected to at least one of the ohmic contact regions of the electrical component in one of an electrically conductive manner and a semiconductive manner.
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69. The semiconductor sensor according to claim 32, wherein the electronic component and the functional layer sequence are disposed at least twofold on one of the carrier and the substrate.
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70. The semiconductor sensor according to claim 69, wherein at least two of the repeatedly-disposed structures are disposed in the layer plane of one of the carrier and the substrate one next to the other.
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71. The semiconductor sensor according to claim 69, wherein an ion-sensitive surface of one of the at least two adjacently disposed structures is covered with a further non-sensitive layer.
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72. Use of a semiconductor sensor for detecting at least one of physical properties and chemical properties of a medium, the sensor comprising an electronic component with a sensitive surface, the electronic component being constructed on the basis of semiconductors with a large band gap, the sensitive surface, at least in regions with a functional layer sequence, having an ion-sensitive surface, the ion-sensitive surface being orientated away from the sensitive surface and is coated with at least one layer, the functional layer sequence being impermeable at least for at least one of (a) the medium and (b) one of materials and ions to be determined.
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73. The use of the semiconductor sensor of claim 72, wherein the sensor is one of a pH sensor and an oxygen sensor.
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74. The use of the semiconductor sensor of claim 72, wherein the sensor operates in one of following ranges:
- a range between 10°
C. and 500°
C., at room temperature range, a range between 50°
C. and 500°
C. and a range between 150°
C. and 450°
C.
- a range between 10°
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75. The use of the semiconductor sensor of claim 72, wherein the sensor includes at least one of a reference electrode and a counter-electrode.
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76. The use of the semiconductor sensor of claim 72, wherein the medium is a fluid including one of gases and liquids.
Specification