The present invention relates to water splitting and particularly, to a Photoelectrochemical (PEC) module and a method for performing PEC water splitting.
Water splitting refers to a chemical reaction to dissociate the water into oxygen and hydrogen. Currently, a process, such as Photoelectrochemical (PEC) water splitting, is employed for dissociating water and thereby, to produce hydrogen gas. The PEC water splitting process includes a semiconductor electrode disposed in electrolyte solution. The semiconductor electrode is provided to convert solar energy directly into chemical energy to dissociate water. In particular, the semiconductor electrode converts the solar energy into electron-hole pairs to conduct redox reaction for water splitting.
Generally, the semiconductor electrode may be made of a wide-band semiconductor material or a narrow-band semiconductor material. The semiconductor electrode with the wide-band semiconductor material is capable of performing water splitting in presence of solar energy without any aid from an external voltage source. However, the wide-band semiconductor material fails to harness majority of solar spectrum to perform the water splitting.
Further, the semiconductor electrode with the narrow-band semiconductor material is capable of harnessing majority of solar spectrum. However, the narrow-band semiconductor material fails to generate adequate voltage required for the water splitting. Therefore, the semiconductor electrode with the narrow-band semiconductor material requires the external voltage source for providing the adequate voltage to perform the water splitting. Additionally, various high efficiency materials, such as Silicon and III-V semiconductors (Aluminum, Galium, Arsenide etc.), can be used in the semiconductor electrode. However, such high efficiency materials are not stable in the electrolytes, such as strong electrolytes, which render the usage of such high efficiency material in the semiconductor electrode. Hence, to effectively and efficiently perform the water splitting, geometrical scale-up of the semiconductor electrode is required.
However, the geometrical scale-up of the semiconductor electrode is not suitable due to resistive losses. In particular, the semiconductor electrode includes a substrate made of conducting materials. Generally, such conducting materials have a high sheet resistivity which leads to increase in the resistive losses, if a size of the semiconductor electrode is increased. Further, the resistive losses in the semiconductor electrode may lead to decrease in a flow of current harnessed from the solar spectrum by the semiconductor electrode.
U.S. Pat. No. 7,459,065, hereinafter referred to as '065 patent, discloses a large scale system for hydrogen production wherein the energy for water dissociation was mainly obtained from photovoltaic module submersed into the electrolyte. The application '065 discloses an apparatus for creating hydrogen from the disassociation of water using sunlight (photoelectrolysis) is provided. The system utilizes an aqueous fluid filled container which functions both to hold the water to be disassociated and as a light collecting lens. A photovoltaic module is positioned at a point to most efficiently accept the refracted light from the fluid filled container. A pair of electrodes which are coupled to the photovoltaic module are disposed within the fluid and configured to split the water into hydrogen and oxygen. However, the photovoltaic module disclosed in the '065 patent is unstable when submersed in the water to be disassociated.
U.S. Patent Application 2004/0003837, hereinafter referred to as '837 application, discloses an integrated photovoltaic-photoelectrochemical device. The '837 application discloses photovoltaic-photoelectrochemical devices each comprising a diode and a plurality of separate photocathode elements. Preferably, the devices are positioned in a container in which they are at least partially immersed in electrolyte. Preferably, the devices are positioned in a container which has at least one photocathode reaction product vent and at least one anode reaction product vent. Preferably, the devices are positioned in a container which has an internal partial wall extending from a top portion of the container toward, but not reaching, a bottom portion of the container, the internal partial wall being positioned between the photocathode elements and an anode element which is electrically connected to the p-region of the diode. However, it demands complicated process for the fabrication of the device for water splitting.
In an embodiment of the present disclosure, an electrode is provided. The electrode includes a substrate. The electrode also includes a first conducting layer disposed on the substrate. The first conducting layer is formed of at least one of an Indium Tin Oxide (ITO) and a Fluorine-doped Tin Oxide (FTO). The electrode includes at least one semiconductor layer disposed on the first conducting layer. Further, the electrode includes at least one connector distributed across the first conducting layer. The at least one connector is adapted to conduct an electric current from the electrode.
In another embodiment of the present disclosure, a Photoelectochemical (PEC) module for performing water splitting is disclosed. The PEC module includes a substrate and a plurality of electrodes arranged on the substrate. Each of the plurality of electrodes includes a first conducting layer disposed on the substrate. Further, each of the plurality of electrodes includes at least one semiconductor layer disposed on the first conducting layer. The PEC module includes at least one connector adapted to connect the plurality of electrodes. Further, the at least one connector is adapted to conduct an electric current from each of the plurality of electrodes.
In yet another embodiment of the present disclosure, a method of performing Photoelectrochemical (PEC) water splitting is disclosed. The method includes receiving a portion of solar spectrum by a plurality of electrodes of a PEC module. The method includes converting the portion of solar spectrum into an electric current. Each of the plurality of electrodes includes a substrate and a first conducting layer disposed on the substrate. Further, each of the plurality of electrodes includes at least one semiconductor layer disposed on the first conducting layer. Each of the plurality of electrodes includes at least one connector distributed across the first conducting layer. Further, the method includes conducting the electric current by the at least one connector, based on the portion of the solar spectrum. The method includes performing water splitting by the PEC module, based on the electric current.
To further clarify advantages and features of the present invention, a more particular description of the invention will be rendered by reference to specific embodiments thereof, which is illustrated in the appended drawings. It is appreciated that these drawings depict only typical embodiments of the invention and are therefore not to be considered limiting of its scope. The invention will be described and explained with additional specificity and detail with the accompanying drawings.
These and other features, aspects, and advantages of the present invention will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
Further, skilled artisans will appreciate that elements in the drawings are illustrated for simplicity and may not have been necessarily been drawn to scale. For example, the flow charts illustrate the method in terms of the most prominent steps involved to help to improve understanding of aspects of the present invention. Furthermore, in terms of the construction of the device, one or more components of the device may have been represented in the drawings by conventional symbols, and the drawings may show only those specific details that are pertinent understanding the embodiments of the present invention so as not to obscure the drawings with details that will be readily apparent to those of ordinary skill in the art having benefit of the description herein.
For the purpose of promoting an understanding of the principles of the invention, reference will now be made to the embodiment illustrated in the drawings and specific language will be used to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended, such alterations and further modifications in the illustrated system, and such further applications of the principles of the invention as illustrated therein being contemplated as would normally occur to one skilled in the art to which the invention relates. Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skilled in the art to which this invention belongs. The system, methods, and examples provided herein are illustrative only and not intended to be limiting.
Embodiments of the present invention will be described below in detail with reference to the accompanying drawings.
Referring to
Further, the reservoir 102 may be in fluid communication with the second compartment 106. The reservoir 102 may be adapted to store electrolyte solution 110, and to maintain a level of the electrolyte solution 110 in the first compartment 104 and the second compartment 106. In an embodiment, the electrolyte solution 110 may be embodied as one of water based electrolyte solution or any other aqueous solution known in the art, without departing from the scope of the present disclosure.
The second compartment 104 may be adapted to receive the electrolyte solution 110 from the reservoir 102. The second compartment 104 may include a second vent 114 to allow flow of gases from the second compartment 104.
Referring to
The PEC module 116 may be adapted to receive a portion of solar spectrum 122. In an embodiment, the PEC module 116 may receive the portion of solar spectrum 122 through a quartz window (not shown) formed in the first compartment 104. Further, the PEC module 116 may be adapted to convert the portion of solar spectrum 122 into an electrical energy for dissociating the electrolyte solution 110. Constructional and operational details of the PEC module 116 are explained in detail in the description of
In an embodiment, the working electrodes 204 may be arranged in a form of matrix (m×n) on the substrate 202. In such an embodiment, the terms ‘m’ and ‘n’ represents a number of working electrodes 204 arranged along a column and a row of the matrix, respectively. In an embodiment, the PEC module 116 may include at least one connector, such as the connector 120, adapted to connect the plurality of electrodes 204, and to conduct the electric current from each of the plurality of electrodes 204. In an embodiment, the working electrodes 204 may be electrically connected with each other through the connector 120. More specifically, the working electrodes 204 may be electrically connected to the counter electrode 118 through the connector 120. Constructional and operational details of each of the working electrodes 204 is explained in detail in the description of
Referring to
In one embodiment, the PEC module 116 may dissociate the electrolyte solution 110 in the first compartment 104 to produce oxygen. More specifically, each of the working electrodes 204 of the PEC module 116 may dissociate the electrolyte solution 110 in the first compartment 104 to produce oxygen, by initiating oxidation reaction as indicated by an equation (1) mentioned below:
H2O+2H+→2H++½O2↑ (1)
In such an embodiment, the PEC module 116 may also generate the electric current, upon receiving the portion of solar spectrum 122. The counter electrode 118 may receive the electric current from the PEC module 116 through the connector 120. Upon receiving the electric current, the counter electrode 118 may dissociate the electrolyte solution 110 in the second compartment 106 to produce gases, by initiating either oxidation reaction or reduction reaction in the electrolyte solution 110. The counter electrode 118 may dissociate the electrolyte solution 110 in the second compartment 106 to produce hydrogen, as indicated by an equation (2) mentioned below:
2H++2e−→H2↑ (2)
In another embodiment, the PEC module 116 may dissociate the electrolyte solution 110 in the first compartment 104 to produce hydrogen. More specifically, each of the working electrodes 204 of the PEC module 116 may dissociate the electrolyte solution 110 in the first compartment 104 to produce hydrogen, by initiating reduction reaction as indicated by an equation (3) mentioned below:
2H2O+2e−→2OH++H2↑ (3)
In such an embodiment, the counter electrode 118 may dissociate the electrolyte solution 110 to produce oxygen in the second compartment 106.
Again referring to
In an embodiment, the system 100 may also include a charge controller 126 in communication with the photovoltaic module 124, at least one battery 128 in communication with the charge controller 126, and a power supply unit 130 in communication with the at least one battery 126. The charge controller 124 may be adapted to control a rate of charging and a rate of discharging of the at least one battery 126. In an embodiment, the charge controller 124 may control a flow of electric current from the photovoltaic module 122 to the at least one battery 126, to prevent overcharging of the at least one battery 126. Further, the power supply unit 130 may be adapted to provide the electric current from the at least one battery at a desired output voltage to the PEC module 116.
For the sake of simplicity and better understanding, the present disclosure is explained with respect to only one working electrode of the PEC module 116. As would be appreciated by the person skilled in the art, the description of one working electrode is equally applicable to other working electrodes of the PEC module 116, without departing from the scope of the present disclosure.
Referring to
The connector 120 may be distributed across the first conducting layer 304. In an embodiment, the connector 120 may be embodied as a metallic connector. The connector 120 may be adapted to conduct the electric current from the working electrode 300. The connector 120 may be adhered to the first conducting layer 304 through a second conducting layer 306. The second conducting layer 306 may be disposed on the first conducting layer 304.
More specifically, the second conducting layer 306 may be deposited on the first conducting layer 304 to adhere the connector 120 on the first conducive layer 304. In one example, the second conducting layer 304 may be embodied as a silver paint. In another example, the second conducting layer 304 may be embodied as any other conductive adhesive known in the art, without departing from the scope of the present disclosure. Further, the working electrode 300 may include an ohmic contact between the connector 120 and the first conducting layer 304. In an embodiment, the ohmic contact may be formed by joining the connector 120 to the first conducting layer 304 through the second conducting layer 306. The ohmic contact between the first conducting layer 304 and the connector 120 allows a flow of charge carriers to the connector 120.
Further, the working electrode 300 may include a semiconductor layer 308 disposed on the substrate 302. In an embodiment, the semiconductor layer 308 may be disposed on the first conducting layer 304. The semiconductor layer 308 may be formed of a photoactive semiconductor material. In an example, the photoactive semiconductor material may be one of an n-type semiconductor and a p-type semiconductor. In one example, the photoactive semiconductor material may be embodied as the n-type semiconductor. In such an example, the working electrode 300 may dissociate the electrolyte solution 110 in the first compartment 104 to produce hydrogen gas. In another example, the photoactive semiconductor material may be embodied as the p-type semiconductor. In such an example, the working electrode 300 may dissociate the electrolyte solution 110 in the first compartment 104 to produce oxygen gas.
In an embodiment, the semiconductor layer 308 may be embodied as a thin film semiconductor material. The semiconductor layer 308 may be deposited on the substrate 302 by using various deposition techniques known in the art, without departing from the scope of the present disclosure. The various deposition techniques may include, but are not limited to, a Physical Vapour Deposition (PVD), a Chemical Vapour Deposition (CVD), an atomic layer deposition, an electrodeposition, a Molecular Beam Epitaxy (MBE), and a spray pyrolysis.
In one embodiment, a number of portions of the first conducting layer 304 may be masked prior to a deposition of the semiconductor layer 308 on the substrate 302 coated with the first conducting layer 304. In particular, the number of portions may be masked on the first conducting layer 304 for forming the ohmic contacts between the connector 120 and the substrate 302 coated with the first conducting layer 304. In another embodiment, the number of portions of the first conducting layer 304 may be masked after the deposition of the semiconductor layer 308 on the substrate 302. In particular, the number of portions may be masked to prevent short-circuiting of junctions, via the ohmic contacts, between the electrolyte solution 110 and the semiconductor layer 308.
In an embodiment, the semiconductor layer 308 may be adapted to receive the portion of the solar spectrum 122 to generate to the charge carriers. The charge carriers may be collected by the connector 120 adhered to the first conducting layer 304, and in contact with the semiconductor layer 308. The charge carrier collected by the connector 120 may generate the electric current which is further supplied to the counter electrode 118 through the connector 120.
Further, the working electrode 300 may include an insulating layer 310 to shield the connector 120. The insulating layer 310 may be provided to shield the connector 120 on working electrode from the electrolyte solution 110. In an embodiment, the insulating layer 310 may be deposited in the connector 120. The insulating layer 310 may be embodied as epoxy resin or any other insulating material known in the art, without departing from the scope of the present disclosure. Further, the insulating layer 310 may be provided to shield portions of the first conducting layer 304 which may be exposed to the electrolyte solution 110.
However, the working electrode 400 of the present embodiment includes a pair of connectors 402 disposed on the first conducting layer 304. The pair of connectors 402 may be adhered to the substrate 302 through the second conducting layer 306. In one example, the second conducting layer 306 may be embodied as a silver paint. In another example, the second conducting layer 306 may be embodied as any other conductive adhesive known in the art, without departing from the scope of the present disclosure. In an embodiment, each of the pair of connectors 402 may be adhered on an edge portion of the substrate 302 along a length 1′ of the substrate 302 through the second conducting layer 304. In an embodiment, the pair of connectors 402 disposed on the working electrode 400 may be connected to the connector 110 of the system 100.
Further, the working electrode 400 may include a pair of ohmic contacts between the pair of connectors 402 and the first conducting layer 304. In an embodiment, each of the pair of ohmic contacts may be formed by joining each of the pair of connectors 402 to the first conducting layer 304 through the second conducting layer 306. The pair of ohmic contacts between the first conducting layer 304 and the pair of connectors 402 allows a flow of the charge carriers to the pair of connectors 402 from the semiconductor layer 308. The charge carriers collected by the pair of connectors 402 may generate the electric current which is further supplied to the counter electrode 118 through the connector 110.
However, the working electrode 500 of the present embodiment includes a plurality of semiconductor layers 502 and a plurality of connectors 504. The working electrode 500 includes a patterned deposition of the plurality of semiconductor layers 502. Each of the plurality of semiconductor layers 502 may adjacently arranged on the first conducting layer 304. More specifically, each of the plurality of semiconductor layers 502 may be deposited on the substrate 302 coated with the first conducting layer 304, by masking a number of portions of the first conducting layer 304 for forming a plurality of ohmic contacts.
Further, each of the plurality of semiconductor layers 502 may have a width, such as a second width W1, and the length L. A value of the second width ‘W1’ may be selected based on a first set of parameters associated with the working electrode 500. The first set of parameters may include, but is not limited to, a value of resistive loses associated with the working electrode 500. In an embodiment, a maximum value of the second width ‘W1’ may be kept constant depending on the resistive loses. The second width ‘W1’ is smaller than the first width ‘W’ of the substrate 302. In an embodiment, a value of the first width ‘W’ of the working electrode 500 may be selected based on a number of semiconductor layers 502 to be deposited on the substrate 304 of the working electrode 500. Further, the length 1′ of the working electrode 500 may be selected based on a second set of parameters. The second set of parameters may include, but is not limited to, a set of dimensional parameters associated with the system 100 and a set of operational parameters associated with the system 100.
Further, the working electrode 500 may include the plurality of ohmic contacts between the plurality of connectors 504 and the first conducting layer 304. In an embodiment, each of the ohmic contacts may be formed by joining each of the plurality of connectors 504 to the first conducting layer 304 through the second conducting layer 306. The plurality of ohmic contacts between the first conducting layer 304 and the plurality of connectors 504 allows a flow of charge carriers to the plurality of connectors 504 from the plurality of semiconductor layer 502. The charge carrier collected by the plurality of connectors 504 may generate the electric current which is further supplied to the counter electrode 118 through the connector 110.
Further, the working electrode 500 may include the plurality of connectors 504 distributed across the first conducting layer 304. Each of the plurality of connectors 504 may be arranged at a distance equal to the second width ‘W1’ of each of the plurality of semiconductor layers 502. Such an arrangement of the plurality of connectors 504 and the plurality of the semiconductor layers 502 on the substrate 302 may reduce the resistive loses associated with the flow of charge carriers from the plurality of semiconductor layers 502 to the plurality of connectors 504. For instance, upon receiving the portion of solar spectrum 122, each of the plurality of semiconductor layers 502 may generate the charge carriers. As, each of the plurality of connectors 504 is adhered at the distance equal to the second width ‘W1’, a distance traveled by the charge carrier from each of the semiconductor layers 502 to each of the plurality of connectors 504 is reduced. Thereby, the resistive loses associated with the flow of charge carrier are substantially eliminated.
At block 602, the method 600 includes receiving, by the plurality of electrodes 300, 400, 500 of the PEC module 116, the portion of solar spectrum 122. The PEC module 116 positioned in the first compartment 104 filled with the electrolyte solution 110. At block 604, the method 600 may include converting the portion of solar spectrum 122 into an electric current, by the plurality of electrodes 300, 400, 500. Each of the plurality of electrodes 300, 400, 500 may include the substrate 302 and the first conducting layer 304 disposed on the substrate 302. Further, the plurality of electrodes 300, 400, 500 may include at least one semiconductor layer 308, 502 disposed on the first conducing layer 304, and at least one connector 120, 402, 504 distributed across the first conducting layer 304. The at least one semiconductor layer 308, 502 may generate the charge carrier to create the electric current, upon receiving the portion of the solar spectrum 122.
At block 606, the method 600 may include conducting the electric current based on the portion of the solar spectrum 122, by the at least one connector 120, 402, 504. The at least one connector 120, 402, 504 may be adhere to the first conducting layer 304 of the substrate 302 through the second conducting layer 306. The at least one connector 120, 402, 504 may receive the charge carriers from the at least one semiconductor layers 308, 502. At block 608, the method 600 may include performing water splitting based on the electric current, by the PEC module 116. Upon receiving the portion of the solar spectrum 122, the PEC module 116 may dissociate the electrolyte solution 110 to produce gases, by initiating either oxidation reaction or reduction reaction in the electrolyte solution 110.
As would be gathered, the present disclosure offers a working electrode 300, 400, 500, a PEC module 116, and the method 600 performing water splitting. The working electrode 300, 400, 500 may be provided with the patterned deposition of the plurality of semiconductor layers 502 on the substrate 302. More specifically, each of the plurality of semiconductor layers 502 may be adjacently arranged on the first conducting layer 304 of the substrate 302. Further, the working electrode 300, 400, 500 may include multiple ohmic contacts formed between the plurality of connectors 504 and the first conducting layer 304 of the substrate 302. Owing to multiple ohmic contacts and patterned arrangement of the plurality of semiconductor layers 502, the working electrode 300, 400, 500, may provide a uniform potential distribution and substantially reduction in the resistive loses.
Further, the PEC module 116 of the present disclosure includes the plurality of working electrodes 300, 400, 500. More specifically, the plurality of working electrodes 300, 400, 500 may be distributed on the substrate 302 of the PEC module 116. The plurality of working electrodes 300, 400, 500 may be electrically connected with each other through the connector 504. Each of the plurality of working electrodes 502 may be adapted to receive the portion of solar spectrum 122, thereby generating the charge carriers and dissociating the electrolyte solution 110. Owing to the plurality of working electrodes 300, 400, 500 in the PEC module 116, the PEC module 116 eliminate a requirement of the photovoltaic module 124 for providing additional bias to dissociate the electrolyte solution 118 to generate gases. Owing to the plurality of electrodes in the PEC module 116, water splitting is performed effectively and efficiently without any requirement of geometrical scale-up of a single working electrode. Thereby, eliminating a requirement of geometrical scale-up, any possibility of occurrence of resistive loses associated with the geometrical scale-up of the working electrode are eliminated. Hence, the present disclosure offers the electrode 300, 400, 500, the PEC module 116, and the method 600 that are efficient, economical, flexible, and effective for performing water splitting.
While specific language has been used to describe the present subject matter, any limitations arising on account thereto, are not intended. As would be apparent to a person in the art, various working modifications may be made to the method in order to implement the inventive concept as taught herein. The drawings and the foregoing description give examples of embodiments. Those skilled in the art will appreciate that one or more of the described elements may well be combined into a single functional element. Alternatively, certain elements may be split into multiple functional elements. Elements from one embodiment may be added to another embodiment.
Number | Date | Country | Kind |
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201721039690 | Nov 2017 | IN | national |