Electrochromic window with high reflectivity modulation
First Claim
1. A multi-layered electrochromic device having a high reflectivity modulation, a high transmissivity modulation, and a low absorptivity comprising:
- a transparent substrate;
a first thin film electrochromic electrode, said first electrode capable of receiving, storing and delivering cations and electrons to be transported to a second thin film electrochromic electrode for reversible transformation of said device into an optically transparent state, said second thin film electrochromic electrode capable of receiving, storing and delivering cations and electrons to be transported to said first electrode for reversible transformation of said device into an optically reflective state;
a thin film, inorganic, solid-state, amorphous electrolyte disposed between said first and said second electrodes, said electrolyte comprising a mixed compound of lithium, oxygen and at least one element selected from the group consisting of phosphorus, nitrogen, aluminum, titanium, tantalum and niobium, said electrolyte formed byi) thermally evaporating onto a surface of said first electrode a material having a composition which comprises at least one first component of said electrolyte, andii) simultaneously and concurrently exposing said first electrode surface and said thermally evaporated material to at least one source of energetic ions, said at least one ion source having an ion beam energy of less than 100 eV, said at least one ion source having an elemental ion composition which comprises at least one second component of said electrolyte, wherein said energetic ions and said thermally evaporated material combine to form said thin film of said electrolyte;
said electrolyte having an ionic conductivity of at least 1×
10-6 S/cm and an electronic resistivity greater than 1013 ohm·
cm, said electrolyte capable of conveying a plurality of cations to said first and second electrodes, said cations conveyed to said first electrode for reversibly transforming at least one of said first and second electrodes into said optically reflective state, said cations conveyed to said second electrode for reversibly transforming at least one of said first and second electrodes into said optically transparent state, whereby, upon application of a predetermined voltage or current of a first polarity across said first and second electrodes, said cations and said electrons are inserted into said first electrode and, upon application of a predetermined voltage or current of a second polarity across said first and second electrodes, said cations and said electrons are extracted from said first electrode; and
said device having an optical absorptivity of less than 50% at a plurality of wavelengths in both said optically transparent and said optically reflective states, said device having a transmissivity modulation of at least 50% and a reflectivity modulation of at least 40% at a plurality of wavelengths when said device is reversibly transformed between said optically transparent and said optically reflective states.
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Accused Products
Abstract
A multi-layered, active, thin film, solid-state electrochromic device having a high reflectivity in the near infrared in a colored state, a high reflectivity and transmissivity modulation when switching between colored and bleached states, a low absorptivity in the near infrared, and fast switching times, and methods for its manufacture and switching are provided. In one embodiment, a multi-layered device comprising a first indium tin oxide transparent electronic conductor, a transparent ion blocking layer, a tungsten oxide electrochromic anode, a lithium ion conducting-electrically resistive electrolyte, a complimentary lithium mixed metal oxide electrochromic cathode, a transparent ohmic contact layer, a second indium oxide transparent electronic conductor, and a silicon nitride encapsulant is provided. Through elimination of optional intermediate layers, simplified device designs are provided as alternative embodiments. Typical colored-state reflectivity of the multi-layered device is greater than 50% in the near infrared, bleached-state reflectivity is less than 40% in the visible, bleached-state transmissivity is greater than 60% in the near infrared and greater than 40% in the visible, and spectral absorbance is less than 50% in the range from 0.65-2.5 μm.
207 Citations
23 Claims
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1. A multi-layered electrochromic device having a high reflectivity modulation, a high transmissivity modulation, and a low absorptivity comprising:
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a transparent substrate; a first thin film electrochromic electrode, said first electrode capable of receiving, storing and delivering cations and electrons to be transported to a second thin film electrochromic electrode for reversible transformation of said device into an optically transparent state, said second thin film electrochromic electrode capable of receiving, storing and delivering cations and electrons to be transported to said first electrode for reversible transformation of said device into an optically reflective state; a thin film, inorganic, solid-state, amorphous electrolyte disposed between said first and said second electrodes, said electrolyte comprising a mixed compound of lithium, oxygen and at least one element selected from the group consisting of phosphorus, nitrogen, aluminum, titanium, tantalum and niobium, said electrolyte formed by i) thermally evaporating onto a surface of said first electrode a material having a composition which comprises at least one first component of said electrolyte, and ii) simultaneously and concurrently exposing said first electrode surface and said thermally evaporated material to at least one source of energetic ions, said at least one ion source having an ion beam energy of less than 100 eV, said at least one ion source having an elemental ion composition which comprises at least one second component of said electrolyte, wherein said energetic ions and said thermally evaporated material combine to form said thin film of said electrolyte; said electrolyte having an ionic conductivity of at least 1×
10-6 S/cm and an electronic resistivity greater than 1013 ohm·
cm, said electrolyte capable of conveying a plurality of cations to said first and second electrodes, said cations conveyed to said first electrode for reversibly transforming at least one of said first and second electrodes into said optically reflective state, said cations conveyed to said second electrode for reversibly transforming at least one of said first and second electrodes into said optically transparent state, whereby, upon application of a predetermined voltage or current of a first polarity across said first and second electrodes, said cations and said electrons are inserted into said first electrode and, upon application of a predetermined voltage or current of a second polarity across said first and second electrodes, said cations and said electrons are extracted from said first electrode; andsaid device having an optical absorptivity of less than 50% at a plurality of wavelengths in both said optically transparent and said optically reflective states, said device having a transmissivity modulation of at least 50% and a reflectivity modulation of at least 40% at a plurality of wavelengths when said device is reversibly transformed between said optically transparent and said optically reflective states. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19)
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20. A low temperature deposition method for making a dense, thin film, amorphous electrochromic device electrolyte having a high decomposition potential, a high ionic conductivity and high electronic resistivity comprising the steps of:
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thermally evaporating onto an electrode surface a material having a composition which comprises at least one first component of said electrolyte; simultaneously and concurrently exposing said electrode surface and said thermally evaporated material to at least one source of energetic ions, said at least one ion source having an ion beam energy of less than 100 eV, said at least one ion source having an elemental ion composition which comprises at least one second component of said electrolyte; and combining said energetic ions and said thermally evaporated material to form said electrolyte film on said electrode surface, said electrolyte having an ionic conductivity of at least 1×
10-6 S/cm and an electronic resistivity greater than 1013 ohm·
cm, said electrolyte having a decomposition potential of at least 6 volts. - View Dependent Claims (21)
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22. A low temperature deposition method for making a dense, thin film electrochromic electrode comprising the steps of:
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thermally evaporating onto a surface of one layer of a multi-layer electrochromic device a material having a composition which comprises at least one first component of said electrode; simultaneously and concurrently exposing said layer surface and said thermally evaporated material to at least one source of energetic ions, said at least one ion source having an ion beam energy of less than 100 eV, said at least one ion source having an elemental ion composition which comprises at least one second component of said electrode; and combining said energetic ions and said thermally evaporated material to form said electrode film on said layer surface. - View Dependent Claims (23)
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Specification