Reversible electrochemical mirror (REM) state monitoring
First Claim
1. A method for determining the thickness of a mirror metal deposit on a mirror electrode of a reversible electrochemical mirror device for controlling the propagation of electromagnetic radiation, of the type includinga mirror electrode, a counter electrode, at least one of the mirror and counter electrodes being substantially transparent to at least a portion of the spectrum of electromagnetic radiation, and an electrolyte disposed between and in electrical contact with the mirror and counter electrodes, wherein the electrolyte contains cations of an electrodepositable mirror metal, such that a negative electrical potential applied to the mirror electrode relative to the counter electrode tends to cause mirror metal to dissolve from the counter electrode into the electrolyte and to electrodeposit from the electrolyte onto the mirror electrode as a mirror deposit, and such that a positive electrical potential applied to the mirror electrode relative to the counter electrode tends to cause mirror metal to dissolve from the mirror electrode into the electrolyte and to electrodeposit onto the counter electrode, the thickness of deposited mirror metal subsisting on the mirror electrode affecting the reflectance of the device for electromagnetic radiation, comprising the steps of:
- (1) measuring the electrical resistance between two locations on the mirror electrode; and
(2) comparing said measured resistance with a known electrical resistance for a mirror metal deposit having a known thickness, and calculating the mirror deposit thickness corresponding to the measured resistance based on the known resistance and the known thickness.
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Accused Products
Abstract
Reversible electrochemical mirror (REM) devices typically comprise a conductive oxide mirror electrode that is substantially transparent to radiation of some wavelengths, a counter electrode that may also be substantially transparent, and an electrolyte that contains ions of an electrodepositable metal. A voltage applied between the two electrodes causes electrodeposition of a mirror deposit on the mirror electrode and dissolution of the mirror deposit on the counter electrode, and these processes are reversed when the polarity of the applied voltage is changed. Such REM devices provide precise control over the reflection and transmission of radiation and can be used for a variety of applications, including smart windows and automatically adjusting automotive mirrors. According to the present invention, measurements of the sheet resistance of the mirror electrode in a REM device are correlated with the thickness of electrodeposited mirror metal and can be used to monitor the reflectance of the device. Sheet resistance measurements can be performed while the mirror state of the device is being switched if adequate isolation between the measurement and switching circuits is provided. This can be accomplished by use of external resistors or more sophisticated circuitry, or by taking advantage of the relatively high sheet resistance of the mirror electrode itself. Monitoring the reflectance of REM devices according to this invention provides significant cost and performance advantages.
178 Citations
19 Claims
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1. A method for determining the thickness of a mirror metal deposit on a mirror electrode of a reversible electrochemical mirror device for controlling the propagation of electromagnetic radiation, of the type including
a mirror electrode, a counter electrode, at least one of the mirror and counter electrodes being substantially transparent to at least a portion of the spectrum of electromagnetic radiation, and an electrolyte disposed between and in electrical contact with the mirror and counter electrodes, wherein the electrolyte contains cations of an electrodepositable mirror metal, such that a negative electrical potential applied to the mirror electrode relative to the counter electrode tends to cause mirror metal to dissolve from the counter electrode into the electrolyte and to electrodeposit from the electrolyte onto the mirror electrode as a mirror deposit, and such that a positive electrical potential applied to the mirror electrode relative to the counter electrode tends to cause mirror metal to dissolve from the mirror electrode into the electrolyte and to electrodeposit onto the counter electrode, the thickness of deposited mirror metal subsisting on the mirror electrode affecting the reflectance of the device for electromagnetic radiation, comprising the steps of: -
(1) measuring the electrical resistance between two locations on the mirror electrode; and
(2) comparing said measured resistance with a known electrical resistance for a mirror metal deposit having a known thickness, and calculating the mirror deposit thickness corresponding to the measured resistance based on the known resistance and the known thickness. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9)
applying a direct voltage, measuring the direct current response to the direct voltage, and using Ohm'"'"'s law to calculate the resistance. -
7. The method of claim 1, further comprising the steps of:
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(3) measuring the reflectance of a device having a mirror metal deposit of known thickness; and
(4) comparing the mirror metal deposit thickness determined in step (2) with the thickness of a mirror metal deposit of known device reflectance to determine the device reflectance corresponding to said measured electrical resistance.
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8. The method of claim 1, wherein the known deposit thickness is determined from the charge required for deposition of the mirror metal deposit.
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9. The device of claim 1, wherein at least one of said electrical contacts is also used to apply the voltage tending to cause the mirror metal to electrodeposit upon or dissolve from the mirror electrode.
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10. A device for determining the thickness of a mirror metal deposit on a mirror electrode of a reversible electrochemical mirror device for controlling the propagation of electromagnetic radiation, of the type including
a mirror electrode, a counter electrode, at least one of the mirror and counter electrodes being substantially transparent to at least a portion of the spectrum of electromagnetic radiation, and an electrolyte disposed between and in electrical contact with the mirror and counter electrodes, wherein the electrolyte contains cations of an electrodepositable mirror metal, such that a negative electrical potential applied to the mirror electrode relative to the counter electrode tends to cause mirror metal to dissolve from the counter electrode into the electrolyte and to electrodeposit from the electrolyte onto the mirror electrode as a mirror deposit, and such that a positive electrical potential applied to the mirror electrode relative to the counter electrode tends to cause mirror metal to dissolve from the mirror electrode into the electrolyte and to electrodeposit onto the counter electrode, the thickness of deposited mirror metal subsisting on the mirror electrode affecting the reflectance of the device for electromagnetic radiation, comprising: -
(1) first and second electrical contacts located on the mirror electrode;
(2) means for measuring the electrical resistance between said electrical contacts;
(3) means for correlating said measured resistance to a resistance for a known thickness of deposited mirror metal; and
(4) means for calculating the thickness of the mirror metal deposit corresponding to said measured resistance. - View Dependent Claims (11, 12, 13, 14, 15, 16, 17)
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18. A method for determining the thickness of a mirror metal deposit on a mirror electrode of a reversible electrochemical mirror device for controlling the propagation of electromagnetic radiation, of the type including
a mirror electrode, a counter electrode, at least one of the mirror and counter electrodes being substantially transparent to at least a portion of the spectrum of electromagnetic radiation, and an electrolyte disposed between and in electrical contact with the mirror and counter electrodes, wherein the electrolyte contains cations of an electrodepositable mirror metal, such that a negative electrical potential applied to the mirror electrode relative to the counter electrode tends to cause mirror metal to dissolve from the counter electrode into the electrolyte and to electrodeposit from the electrolyte onto the mirror electrode as a mirror deposit, and such that a positive electrical potential applied to the mirror electrode relative to the counter electrode tends to cause mirror metal to dissolve from the mirror electrode into the electrolyte and to electrodeposit onto the counter electrode, the thickness of deposited mirror metal subsisting on the mirror electrode affecting the reflectance of the device for electromagnetic radiation, comprising the steps of: -
(1) measuring the electrical resistance between two locations on the mirror electrode;
(2) comparing said measured resistance with a known electrical resistance for a mirror metal deposit having a known thickness, and calculating the mirror deposit thickness corresponding to the measured resistance based on the known resistance and the known thickness;
(3) measuring the reflectance of a device having a mirror metal deposit of known thickness; and
(4) comparing the mirror metal deposit thickness determined in step (2) with the thickness of a mirror metal deposit of known device reflectance to determine the device reflectance corresponding to said measured electrical resistance. - View Dependent Claims (19)
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Specification