RU2011118354A

RU2011118354A - CATALYTIC MATERIALS, PHOTOANODES AND PHOTOELECTRIC CELLS FOR ELECTROLYSIS OF WATER AND OTHER ELECTROCHEMICAL TECHNOLOGIES

Info

Publication number: RU2011118354A
Application number: RU2011118354/07A
Authority: RU
Inventors: Дэниел Г. НОСЕРА (US); Дэниел Г. НОСЕРА; Мэттью В. КАНАН (US); Мэттью В. КАНАН; Йогеш СУРЕНДРАНАТХ (US); Йогеш СУРЕНДРАНАТХ; Стивен Й. РИС (US); Стивен Й. РИС; Артур Дж. ЭССВАЙН (US); Артур Дж. ЭССВАЙН
Original assignee: Массачусетс Инститьют Оф Текнолоджи (Us); Массачусетс Инститьют Оф Текнолоджи; Сан Каталитикс Корпорейшн (Us); Сан Каталитикс Корпорейшн
Priority date: 2008-10-08
Filing date: 2009-10-08
Publication date: 2012-11-20
Also published as: AU2009302811A1; MX2011003719A; EP2350347A1; JP2012505310A; BRPI0920386A2; WO2010042196A1; IL212188A0; US20100133111A1; KR20110084225A; CN102224279A

Abstract

1. Способ формирования фотоанода, включающий: ! предоставление фотоактивного электрода; и ! побуждение металлического ионного компонента, первого типа анионных компонентов, содержащего гидроксидные и/или оксидные ионы, и второго типа анионных компонентов к формированию каталитического материала, связанного с фотоактивным электродом, посредством приложения напряжения к фотоактивному электроду. ! 2. Способ формирования фотоанода, включающий: ! предоставление фотоактивного электрода; и ! побуждение металлического ионного компонента и анионного компонента к формированию каталитического материала, связанного с фотоактивным электродом, посредством приложения напряжения к фотоактивному электроду, при этом напряжение прикладывают к фотоактивному электроду посредством воздействия на фотоактивный электрод электромагнитного излучения. ! 3. Способ формирования фотоанода, включающий: ! предоставление раствора, содержащего ионы кобальта и/или никеля и анионный компонент, содержащий фосфор и/или бор; ! предоставление фотоактивного электрода; и ! побуждение ионов кобальта и/или никеля и анионного компонента, содержащего фосфор и/или бор, к формированию каталитического материала, связанного с фотоактивным электродом, посредством приложения напряжения к фотоактивному электроду. ! 4. Способ получения кислорода из воды, включающий следующие этапы: ! предоставление фотоэлектрохимической ячейки, содержащей: ! фотоактивный электрод; ! электролит; и ! каталитический материал, полностью связанный с фотоактивным электродом, данный каталитический материал содержит металлический ионный компонент и анионный компонен 1. A method of forming a photoanode, including:! provision of a photoactive electrode; and! causing the metal ionic component, the first type of anionic components containing hydroxide and / or oxide ions, and the second type of anionic components to form a catalytic material associated with the photoactive electrode by applying a voltage to the photoactive electrode. ! 2. A method of forming a photoanode, including:! provision of a photoactive electrode; and! causing the metal ionic component and the anionic component to form a catalytic material associated with the photoactive electrode by applying a voltage to the photoactive electrode, wherein a voltage is applied to the photoactive electrode by exposing the photoactive electrode to electromagnetic radiation. ! 3. A method of forming a photoanode, including:! providing a solution containing cobalt and / or nickel ions and an anionic component containing phosphorus and / or boron; ! provision of a photoactive electrode; and! causing the cobalt and / or nickel ions and the phosphorus and / or boron anionic component to form a catalytic material associated with the photoactive electrode by applying a voltage to the photoactive electrode. ! 4. A method for obtaining oxygen from water, including the following steps:! provision of a photoelectrochemical cell containing:! photoactive electrode; ! electrolyte; and! catalytic material fully bonded to the photoactive electrode, this catalytic material contains a metallic ionic component and an anionic component

Claims

1. The method of forming a photoanode, including:

provision of a photoactive electrode; and

inducing a metal ionic component, a first type of anionic components containing hydroxide and / or oxide ions, and a second type of anionic components to form a catalytic material bonded to the photoactive electrode by applying voltage to the photoactive electrode.

2. A method of forming a photo anode, including:

provision of a photoactive electrode; and

causing the metal ion component and the anion component to form a catalytic material bonded to the photoactive electrode by applying voltage to the photoactive electrode, wherein voltage is applied to the photoactive electrode by exposing the photoactive electrode to electromagnetic radiation.

3. A method of forming a photo anode, including:

providing a solution containing cobalt and / or nickel ions and an anionic component containing phosphorus and / or boron;

provision of a photoactive electrode; and

inducing cobalt and / or nickel ions and an anionic component containing phosphorus and / or boron to form catalytic material bonded to the photoactive electrode by applying a voltage to the photoactive electrode.

4. A method of producing oxygen from water, comprising the following steps:

providing a photoelectrochemical cell containing:

photoactive electrode;

electrolyte; and

a catalytic material fully bonded to the photoactive electrode, the catalytic material contains a metal ion component and an anion component, and the catalytic material contains a metal ion component, a first type of anionic components containing hydroxide and / or oxide ions, and a second type of anionic components; and

irradiating the photoelectrochemical cell with electromagnetic radiation to thereby obtain oxygen from water.

5. Photoanode containing:

photoactive electrode; and

catalytic material associated with a photoactive electrode and containing cobalt ions and / or nickel ions and an anionic component containing phosphorus and / or boron.

6. Photoanode containing:

a photoactive electrode containing a photoactive composition, and

a catalytic material containing a metal ionic component, a first type of anionic components and a second type of anionic components, in which the metal ionic component in the oxidized state (n + x) and the first type and / or second type of anionic components form a substantially non-crystalline composition and have a K value _sp , which is at least 10 ³ times less than the K _sp value of the composition containing the metal ionic component in the oxidized state (n) and the first type and / or second type of anionic components.

7. A photo anode containing:

a photoactive electrode containing a photoactive composition, and

a catalytic material containing a metal ionic component and an anionic component in which the metalic ionic component in the oxidized state (n + x) and the anionic component form a substantially non-crystalline composition and have a K _sp value, at a pH of less than 11, which is less than at least 10 ³ times the K _sp value of the composition containing the metal ionic component in the oxidized state (n) and the anionic component.

8. A photo anode containing:

photoactive electrode; and

a catalytic material containing a metal ionic component and an anionic component, wherein the catalytic material is formed by applying a voltage to the photoactive electrode, and the catalytic material contains a metal ionic component, a first type of anionic components containing hydroxide and / or oxide ions, and a second type of anionic components .

9. A photoelectrochemical cell containing:

a photoanode containing a photoactive electrode and a catalytic material containing a metal ionic component and an anionic component, the catalytic material containing a metal ionic component, a first type of anionic components containing hydroxide and / or oxide ions, and a second type of anionic components;

second electrode; and

electrolyte.

10. A method of producing oxygen and / or hydrogen from water, comprising the following steps:

providing a device comprising:

a photoactive electrode containing catalytic material;

electrolyte; and

water at a pH of from about 3 to about 11;

irradiating the device with light in order to obtain oxygen from water, with a total energy conversion efficiency of the device irradiated with simulated radiation of AM 1.5, at least about 1.0%.

11. A device for producing oxygen and / or hydrogen from water, containing:

photoactive composition; and

an electrolyte, at a pH of from about 2 to about 12, in contact with the possibility of electrochemical reactions with the photoactive composition,

however, the device operates with a total energy conversion efficiency when irradiated with simulated radiation of AM 1.5 of at least about 1.0%.