人工光合成の世界市場予測：触媒、タイプ（光電気化学セル、光電池駆動型電解槽）、技術、地域別の世界分析（～2028年）

世界の人工光合成の市場規模は、2021年は5,600万米ドルで、予測期間中に16.6％のCAGRで成長し、2028年には1億6,410万米ドルに達すると予測されています。

当レポートでは、世界の人工光合成市場を調査しており、市場の概要、市場規模や予測、動向、成長要因および抑制要因、触媒・タイプ・技術・地域別の分析など包括的な情報を提供しています。

目次

第1章 エグゼクティブサマリー

第2章 序文

第3章 市場動向分析

• 促進要因
• 抑制要因
• 市場機会
• 脅威
• 技術分析
• 用途分析
• 新興市場
• COVID-19の影響

第4章 ポーターのファイブフォース分析

第5章 世界の人工光合成市場：触媒別

• 水素触媒
• フォトシンセサイザー
• 水酸化触媒

第6章 世界の人工光合成市場：タイプ別

• 光電気化学セル（PECs）
• 光電池駆動型電解槽
• 懸濁ナノ粉末光触媒

第7章 世界の人工光合成市場：技術別

• 共電解
• 光-電気触媒作用
• その他の技術
  • ナノテクノロジー
  • ハイブリッドプロセス

第8章 世界の人工光合成市場：用途別

• 炭化水素
• 化学薬品
• 工業
  • 機械設備
  • 自動車
  • 航空宇宙および防衛
  • 発電
  • 農業

第9章 世界の人工光合成市場：地域別

• 北米
  • 米国
  • カナダ
  • メキシコ
• 欧州
  • ドイツ
  • 英国
  • イタリア
  • フランス
  • スペイン
  • その他欧州
• アジア太平洋
  • 日本
  • 中国
  • インド
  • オーストラリア
  • ニュージーランド
  • 韓国
  • その他アジア太平洋
• 南米
  • アルゼンチン
  • ブラジル
  • チリ
  • その他南米
• 中東・アフリカ
  • サウジアラビア
  • アラブ首長国連邦
  • カタール
  • 南アフリカ
  • その他中東

第10章 主な発展

• 契約、パートナーシップ、コラボレーション、ジョイントベンチャー
• 買収と合併
• 新製品の発売
• 拡張
• その他の主要戦略

第11章 企業プロファイル

• Engie
• Panasonic Corporation
• FUJIFILM Corporation
• Mitsubishi Chemical Corporation
• Toshiba Corporation
• Toyota Central R&D Labs., Inc.
• Siemens Energy
• FUJITSU
• Twelve(Formerly Known As, Op. 12)
• Evonik Industries AG

List of Tables

• Table 1 Global Artificial Photosynthesis Market Outlook, By Region (2020-2028) (US $MN)
• Table 2 Global Artificial Photosynthesis Market Outlook, By Catalyst (2020-2028) (US $MN)
• Table 3 Global Artificial Photosynthesis Market Outlook, By Hydrogen Catalyst (2020-2028) (US $MN)
• Table 4 Global Artificial Photosynthesis Market Outlook, By Photo Synthesizer (2020-2028) (US $MN)
• Table 5 Global Artificial Photosynthesis Market Outlook, By Water-Oxidizing Catalyst (2020-2028) (US $MN)
• Table 6 Global Artificial Photosynthesis Market Outlook, By Type (2020-2028) (US $MN)
• Table 7 Global Artificial Photosynthesis Market Outlook, By Photoelectrochemical Cells (PECs) (2020-2028) (US $MN)
• Table 8 Global Artificial Photosynthesis Market Outlook, By Photovoltaic Cell-driven Electrolysers (2020-2028) (US $MN)
• Table 9 Global Artificial Photosynthesis Market Outlook, By Suspended Nanopowder Photocatalysts (2020-2028) (US $MN)
• Table 10 Global Artificial Photosynthesis Market Outlook, By Technology (2020-2028) (US $MN)
• Table 11 Global Artificial Photosynthesis Market Outlook, By Co-electrolysis (2020-2028) (US $MN)
• Table 12 Global Artificial Photosynthesis Market Outlook, By Photo-Electro Catalysis (2020-2028) (US $MN)
• Table 13 Global Artificial Photosynthesis Market Outlook, By Other Technologies (2020-2028) (US $MN)
• Table 14 Global Artificial Photosynthesis Market Outlook, By Nanotechnology (2020-2028) (US $MN)
• Table 15 Global Artificial Photosynthesis Market Outlook, By Hybrid process (2020-2028) (US $MN)
• Table 16 Global Artificial Photosynthesis Market Outlook, By Application (2020-2028) (US $MN)
• Table 17 Global Artificial Photosynthesis Market Outlook, By Hydrocarbons (2020-2028) (US $MN)
• Table 18 Global Artificial Photosynthesis Market Outlook, By Chemicals (2020-2028) (US $MN)
• Table 19 Global Artificial Photosynthesis Market Outlook, By Industrial (2020-2028) (US $MN)
• Table 20 Global Artificial Photosynthesis Market Outlook, By Machinery and Equipment (2020-2028) (US $MN)
• Table 21 Global Artificial Photosynthesis Market Outlook, By Automotive (2020-2028) (US $MN)
• Table 22 Global Artificial Photosynthesis Market Outlook, By Aerospace and Defense (2020-2028) (US $MN)
• Table 23 Global Artificial Photosynthesis Market Outlook, By Electricity Production (2020-2028) (US $MN)
• Table 24 Global Artificial Photosynthesis Market Outlook, By Agriculture (2020-2028) (US $MN)
• Table 25 North America Artificial Photosynthesis Market Outlook, By Country (2020-2028) (US $MN)
• Table 26 North America Artificial Photosynthesis Market Outlook, By Catalyst (2020-2028) (US $MN)
• Table 27 North America Artificial Photosynthesis Market Outlook, By Hydrogen Catalyst (2020-2028) (US $MN)
• Table 28 North America Artificial Photosynthesis Market Outlook, By Photo Synthesizer (2020-2028) (US $MN)
• Table 29 North America Artificial Photosynthesis Market Outlook, By Water-Oxidizing Catalyst (2020-2028) (US $MN)
• Table 30 North America Artificial Photosynthesis Market Outlook, By Type (2020-2028) (US $MN)
• Table 31 North America Artificial Photosynthesis Market Outlook, By Photoelectrochemical Cells (PECs) (2020-2028) (US $MN)
• Table 32 North America Artificial Photosynthesis Market Outlook, By Photovoltaic Cell-driven Electrolysers (2020-2028) (US $MN)
• Table 33 North America Artificial Photosynthesis Market Outlook, By Suspended Nanopowder Photocatalysts (2020-2028) (US $MN)
• Table 34 North America Artificial Photosynthesis Market Outlook, By Technology (2020-2028) (US $MN)
• Table 35 North America Artificial Photosynthesis Market Outlook, By Co-electrolysis (2020-2028) (US $MN)
• Table 36 North America Artificial Photosynthesis Market Outlook, By Photo-Electro Catalysis (2020-2028) (US $MN)
• Table 37 North America Artificial Photosynthesis Market Outlook, By Other Technologies (2020-2028) (US $MN)
• Table 38 North America Artificial Photosynthesis Market Outlook, By Nanotechnology (2020-2028) (US $MN)
• Table 39 North America Artificial Photosynthesis Market Outlook, By Hybrid process (2020-2028) (US $MN)
• Table 40 North America Artificial Photosynthesis Market Outlook, By Application (2020-2028) (US $MN)
• Table 41 North America Artificial Photosynthesis Market Outlook, By Hydrocarbons (2020-2028) (US $MN)
• Table 42 North America Artificial Photosynthesis Market Outlook, By Chemicals (2020-2028) (US $MN)
• Table 43 North America Artificial Photosynthesis Market Outlook, By Industrial (2020-2028) (US $MN)
• Table 44 North America Artificial Photosynthesis Market Outlook, By Machinery and Equipment (2020-2028) (US $MN)
• Table 45 North America Artificial Photosynthesis Market Outlook, By Automotive (2020-2028) (US $MN)
• Table 46 North America Artificial Photosynthesis Market Outlook, By Aerospace and Defense (2020-2028) (US $MN)
• Table 47 North America Artificial Photosynthesis Market Outlook, By Electricity Production (2020-2028) (US $MN)
• Table 48 North America Artificial Photosynthesis Market Outlook, By Agriculture (2020-2028) (US $MN)
• Table 49 Europe Artificial Photosynthesis Market Outlook, By Country (2020-2028) (US $MN)
• Table 50 Europe Artificial Photosynthesis Market Outlook, By Catalyst (2020-2028) (US $MN)
• Table 51 Europe Artificial Photosynthesis Market Outlook, By Hydrogen Catalyst (2020-2028) (US $MN)
• Table 52 Europe Artificial Photosynthesis Market Outlook, By Photo Synthesizer (2020-2028) (US $MN)
• Table 53 Europe Artificial Photosynthesis Market Outlook, By Water-Oxidizing Catalyst (2020-2028) (US $MN)
• Table 54 Europe Artificial Photosynthesis Market Outlook, By Type (2020-2028) (US $MN)
• Table 55 Europe Artificial Photosynthesis Market Outlook, By Photoelectrochemical Cells (PECs) (2020-2028) (US $MN)
• Table 56 Europe Artificial Photosynthesis Market Outlook, By Photovoltaic Cell-driven Electrolysers (2020-2028) (US $MN)
• Table 57 Europe Artificial Photosynthesis Market Outlook, By Suspended Nanopowder Photocatalysts (2020-2028) (US $MN)
• Table 58 Europe Artificial Photosynthesis Market Outlook, By Technology (2020-2028) (US $MN)
• Table 59 Europe Artificial Photosynthesis Market Outlook, By Co-electrolysis (2020-2028) (US $MN)
• Table 60 Europe Artificial Photosynthesis Market Outlook, By Photo-Electro Catalysis (2020-2028) (US $MN)
• Table 61 Europe Artificial Photosynthesis Market Outlook, By Other Technologies (2020-2028) (US $MN)
• Table 62 Europe Artificial Photosynthesis Market Outlook, By Nanotechnology (2020-2028) (US $MN)
• Table 63 Europe Artificial Photosynthesis Market Outlook, By Hybrid process (2020-2028) (US $MN)
• Table 64 Europe Artificial Photosynthesis Market Outlook, By Application (2020-2028) (US $MN)
• Table 65 Europe Artificial Photosynthesis Market Outlook, By Hydrocarbons (2020-2028) (US $MN)
• Table 66 Europe Artificial Photosynthesis Market Outlook, By Chemicals (2020-2028) (US $MN)
• Table 67 Europe Artificial Photosynthesis Market Outlook, By Industrial (2020-2028) (US $MN)
• Table 68 Europe Artificial Photosynthesis Market Outlook, By Machinery and Equipment (2020-2028) (US $MN)
• Table 69 Europe Artificial Photosynthesis Market Outlook, By Automotive (2020-2028) (US $MN)
• Table 70 Europe Artificial Photosynthesis Market Outlook, By Aerospace and Defense (2020-2028) (US $MN)
• Table 71 Europe Artificial Photosynthesis Market Outlook, By Electricity Production (2020-2028) (US $MN)
• Table 72 Europe Artificial Photosynthesis Market Outlook, By Agriculture (2020-2028) (US $MN)
• Table 73 Asia Pacific Artificial Photosynthesis Market Outlook, By Country (2020-2028) (US $MN)
• Table 74 Asia Pacific Artificial Photosynthesis Market Outlook, By Catalyst (2020-2028) (US $MN)
• Table 75 Asia Pacific Artificial Photosynthesis Market Outlook, By Hydrogen Catalyst (2020-2028) (US $MN)
• Table 76 Asia Pacific Artificial Photosynthesis Market Outlook, By Photo Synthesizer (2020-2028) (US $MN)
• Table 77 Asia Pacific Artificial Photosynthesis Market Outlook, By Water-Oxidizing Catalyst (2020-2028) (US $MN)
• Table 78 Asia Pacific Artificial Photosynthesis Market Outlook, By Type (2020-2028) (US $MN)
• Table 79 Asia Pacific Artificial Photosynthesis Market Outlook, By Photoelectrochemical Cells (PECs) (2020-2028) (US $MN)
• Table 80 Asia Pacific Artificial Photosynthesis Market Outlook, By Photovoltaic Cell-driven Electrolysers (2020-2028) (US $MN)
• Table 81 Asia Pacific Artificial Photosynthesis Market Outlook, By Suspended Nanopowder Photocatalysts (2020-2028) (US $MN)
• Table 82 Asia Pacific Artificial Photosynthesis Market Outlook, By Technology (2020-2028) (US $MN)
• Table 83 Asia Pacific Artificial Photosynthesis Market Outlook, By Co-electrolysis (2020-2028) (US $MN)
• Table 84 Asia Pacific Artificial Photosynthesis Market Outlook, By Photo-Electro Catalysis (2020-2028) (US $MN)
• Table 85 Asia Pacific Artificial Photosynthesis Market Outlook, By Other Technologies (2020-2028) (US $MN)
• Table 86 Asia Pacific Artificial Photosynthesis Market Outlook, By Nanotechnology (2020-2028) (US $MN)
• Table 87 Asia Pacific Artificial Photosynthesis Market Outlook, By Hybrid process (2020-2028) (US $MN)
• Table 88 Asia Pacific Artificial Photosynthesis Market Outlook, By Application (2020-2028) (US $MN)
• Table 89 Asia Pacific Artificial Photosynthesis Market Outlook, By Hydrocarbons (2020-2028) (US $MN)
• Table 90 Asia Pacific Artificial Photosynthesis Market Outlook, By Chemicals (2020-2028) (US $MN)
• Table 91 Asia Pacific Artificial Photosynthesis Market Outlook, By Industrial (2020-2028) (US $MN)
• Table 92 Asia Pacific Artificial Photosynthesis Market Outlook, By Machinery and Equipment (2020-2028) (US $MN)
• Table 93 Asia Pacific Artificial Photosynthesis Market Outlook, By Automotive (2020-2028) (US $MN)
• Table 94 Asia Pacific Artificial Photosynthesis Market Outlook, By Aerospace and Defense (2020-2028) (US $MN)
• Table 95 Asia Pacific Artificial Photosynthesis Market Outlook, By Electricity Production (2020-2028) (US $MN)
• Table 96 Asia Pacific Artificial Photosynthesis Market Outlook, By Agriculture (2020-2028) (US $MN)
• Table 97 South America Artificial Photosynthesis Market Outlook, By Country (2020-2028) (US $MN)
• Table 98 South America Artificial Photosynthesis Market Outlook, By Catalyst (2020-2028) (US $MN)
• Table 99 South America Artificial Photosynthesis Market Outlook, By Hydrogen Catalyst (2020-2028) (US $MN)
• Table 100 South America Artificial Photosynthesis Market Outlook, By Photo Synthesizer (2020-2028) (US $MN)
• Table 101 South America Artificial Photosynthesis Market Outlook, By Water-Oxidizing Catalyst (2020-2028) (US $MN)
• Table 102 South America Artificial Photosynthesis Market Outlook, By Type (2020-2028) (US $MN)
• Table 103 South America Artificial Photosynthesis Market Outlook, By Photoelectrochemical Cells (PECs) (2020-2028) (US $MN)
• Table 104 South America Artificial Photosynthesis Market Outlook, By Photovoltaic Cell-driven Electrolysers (2020-2028) (US $MN)
• Table 105 South America Artificial Photosynthesis Market Outlook, By Suspended Nanopowder Photocatalysts (2020-2028) (US $MN)
• Table 106 South America Artificial Photosynthesis Market Outlook, By Technology (2020-2028) (US $MN)
• Table 107 South America Artificial Photosynthesis Market Outlook, By Co-electrolysis (2020-2028) (US $MN)
• Table 108 South America Artificial Photosynthesis Market Outlook, By Photo-Electro Catalysis (2020-2028) (US $MN)
• Table 109 South America Artificial Photosynthesis Market Outlook, By Other Technologies (2020-2028) (US $MN)
• Table 110 South America Artificial Photosynthesis Market Outlook, By Nanotechnology (2020-2028) (US $MN)
• Table 111 South America Artificial Photosynthesis Market Outlook, By Hybrid process (2020-2028) (US $MN)
• Table 112 South America Artificial Photosynthesis Market Outlook, By Application (2020-2028) (US $MN)
• Table 113 South America Artificial Photosynthesis Market Outlook, By Hydrocarbons (2020-2028) (US $MN)
• Table 114 South America Artificial Photosynthesis Market Outlook, By Chemicals (2020-2028) (US $MN)
• Table 115 South America Artificial Photosynthesis Market Outlook, By Industrial (2020-2028) (US $MN)
• Table 116 South America Artificial Photosynthesis Market Outlook, By Machinery and Equipment (2020-2028) (US $MN)
• Table 117 South America Artificial Photosynthesis Market Outlook, By Automotive (2020-2028) (US $MN)
• Table 118 South America Artificial Photosynthesis Market Outlook, By Aerospace and Defense (2020-2028) (US $MN)
• Table 119 South America Artificial Photosynthesis Market Outlook, By Electricity Production (2020-2028) (US $MN)
• Table 120 South America Artificial Photosynthesis Market Outlook, By Agriculture (2020-2028) (US $MN)
• Table 121 Middle East & Africa Artificial Photosynthesis Market Outlook, By Country (2020-2028) (US $MN)
• Table 122 Middle East & Africa Artificial Photosynthesis Market Outlook, By Catalyst (2020-2028) (US $MN)
• Table 123 Middle East & Africa Artificial Photosynthesis Market Outlook, By Hydrogen Catalyst (2020-2028) (US $MN)
• Table 124 Middle East & Africa Artificial Photosynthesis Market Outlook, By Photo Synthesizer (2020-2028) (US $MN)
• Table 125 Middle East & Africa Artificial Photosynthesis Market Outlook, By Water-Oxidizing Catalyst (2020-2028) (US $MN)
• Table 126 Middle East & Africa Artificial Photosynthesis Market Outlook, By Type (2020-2028) (US $MN)
• Table 127 Middle East & Africa Artificial Photosynthesis Market Outlook, By Photoelectrochemical Cells (PECs) (2020-2028) (US $MN)
• Table 128 Middle East & Africa Artificial Photosynthesis Market Outlook, By Photovoltaic Cell-driven Electrolysers (2020-2028) (US $MN)
• Table 129 Middle East & Africa Artificial Photosynthesis Market Outlook, By Suspended Nanopowder Photocatalysts (2020-2028) (US $MN)
• Table 130 Middle East & Africa Artificial Photosynthesis Market Outlook, By Technology (2020-2028) (US $MN)
• Table 131 Middle East & Africa Artificial Photosynthesis Market Outlook, By Co-electrolysis (2020-2028) (US $MN)
• Table 132 Middle East & Africa Artificial Photosynthesis Market Outlook, By Photo-Electro Catalysis (2020-2028) (US $MN)
• Table 133 Middle East & Africa Artificial Photosynthesis Market Outlook, By Other Technologies (2020-2028) (US $MN)
• Table 134 Middle East & Africa Artificial Photosynthesis Market Outlook, By Nanotechnology (2020-2028) (US $MN)
• Table 135 Middle East & Africa Artificial Photosynthesis Market Outlook, By Hybrid process (2020-2028) (US $MN)
• Table 136 Middle East & Africa Artificial Photosynthesis Market Outlook, By Application (2020-2028) (US $MN)
• Table 137 Middle East & Africa Artificial Photosynthesis Market Outlook, By Hydrocarbons (2020-2028) (US $MN)
• Table 138 Middle East & Africa Artificial Photosynthesis Market Outlook, By Chemicals (2020-2028) (US $MN)
• Table 139 Middle East & Africa Artificial Photosynthesis Market Outlook, By Industrial (2020-2028) (US $MN)
• Table 140 Middle East & Africa Artificial Photosynthesis Market Outlook, By Machinery and Equipment (2020-2028) (US $MN)
• Table 141 Middle East & Africa Artificial Photosynthesis Market Outlook, By Automotive (2020-2028) (US $MN)
• Table 142 Middle East & Africa Artificial Photosynthesis Market Outlook, By Aerospace and Defense (2020-2028) (US $MN)
• Table 143 Middle East & Africa Artificial Photosynthesis Market Outlook, By Electricity Production (2020-2028) (US $MN)
• Table 144 Middle East & Africa Artificial Photosynthesis Market Outlook, By Agriculture (2020-2028) (US $MN)

According to Stratistics MRC, the Global Artificial Photosynthesis Market is accounted for $56.00 million in 2021 and is expected to reach $164.10 million by 2028 growing at a CAGR of 16.6% during the forecast period. Artificial Photosynthesis is a process that converts and stores the energy from sunlight in the chemical bonds of a fuel. It replicates the natural process of photosynthesis. It could offer faster and more efficient production of hydrogen on a large scale which could accelerate the use of fuel cell vehicles.

Market Dynamics:

Driver:

Government Funding's And Increased Research & Development

Government funding's and grants for the research and development of it technology is the important driving factors for the growth of the market. In, the US Department of Energy (DOE) announced a plan to invest up to USD 100 million over five years in it research to produce fuels from sunlight. The Department's projected expenditure in the Fuels from Sunlight Hub program marks a long-term commitment of US scientific and technology resources to this aggressively competitive and promising field of study. In Europe, Germany, Spain, and France are the prominent countries that are emphasizing the research activities of artificial Photosynthesis for various applications, including hydrogen generation, hydrocarbon generation. Several research institutes are collaborating with the OEMs to accelerate the research activities. In Germany, Evonik and Siemens Energy have begun a pilot plant using carbon dioxide and water to make chemicals, The project termed as Rheticus, is funded by the German Federal Ministry of Education and Research (BMBF) with a total of Euro 6.3 million. The pilot facility located in Marl, implements artificial photosynthesis technology to produce chemicals from CO2 and water through electrolysis with the help of bacteria. The project aims to close carbon cycle and reduce CO2 emission.

Restraint:

High Cost

As it is a difficult process that joins in the hydrogen and carbon dioxide to obtain valuable fuels. Since the basic chemical process is extremely challenging to replicate, natural photosynthesis uses abundant resources of sunlight, water, and carbon dioxide to produce oxygen and energy-rich carbohydrates. Though artificial leaves may be the fuel cells of the future, manufacturing costs remain a key concern. One of the most significant roadblocks to artificial photosynthesis achieving high efficiency. During the research, the scientists attempted to achieve higher operating efficiency, however, using an expensive catalyst. Furthermore, the compatibility of the photocatalyst to achieve a high-efficiency rate, add up to the research cost. Hence, the high initial capital and research cost for the set-up acts as a restraint on the market.

Opportunity:

Rising Demand of Green H2 and Eco-Friendly Liquid Fuels

The preponderance of hydrogen now in use comes from a process known as steam methane reforming, which involves reacting methane and high-temperature steam with a catalyst to produce hydrogen, carbon monoxide, and a little amount of carbon dioxide. Carbon monoxide, steam, and a catalyst react in a later step to make additional hydrogen and carbon dioxide. Finally, contaminants and carbon dioxide are eliminated, leaving just pure hydrogen. A research team from Liquid Sunlight Alliance (LiSA) and Berkeley Lab's Chemical Sciences Division in California, US, has developed a prototype of an artificial photosynthesis device component that converts sunlight and carbon dioxide into two promising renewable fuels: ethylene and hydrogen. The demand for green hydrogen and clean fuel has witnessed a progressive rise supplemented by increasing funding and grants. For instance, The US Department of Energy (DOE) is investing up to USD 100 million in hydrogen and fuel cell research and development. Furthermore, major economies such as Chile, Japan, Germany, Saudi Arabia, and Australia are all investing heavily in green hydrogen. The findings also demonstrate the degradation phenomenon of the experimental set-up as well as suggest preventive measures. The team also shed light on electrons and charge carriers known as "holes" contributing to photosynthetic degradation in artificial Photosynthesis.

Threat:

Need For Optimized Catalyst and Stability of Photo Anode Material

Sunlight is used in artificial photosynthesis to produce high-value compounds from available resources. It is regarded as the most promising technology for producing sustainable fuels and chemicals. Recent research has resulted in effective light-absorbing semiconductors with high photoelectrochemical output, as well as effective catalysts for converting raw materials into a variety of products. These accomplishments demonstrate that artificial Photosynthesis is conceivable, although there are obstacles to overcome. Water splitting into H2 and O2 necessitates the use of integrated light gathering and catalytic conversion devices. The photoanode material's stability and performance must be increased. For the conversion of CO2 to products like CO, methane, or ethylene, optimised catalysts are required. Finding the correct transition metal catalyst for each desired reaction while balancing activity, selectivity, and stability can be difficult.

Photo-Electro Catalysis segment is expected to be the largest during the forecast period

Photoelectrocatalysis is a powerful method derived from the combination of heterogeneous photocatalysis and electrochemical techniques. The method is based on the use of a semiconductor irradiated by light energy equal to or greater than its bandgap energy simultaneously biased by a gradient potential. The catalyst approach to artificial photosynthesis enables separate optimization of key chemical steps in a given process, including light absorption, charge separation, the transformation of electrical to chemical energy, and catalytic conversion.

The Photoelectrochemical Cells (PECs) segment is expected to have the highest CAGR during the forecast period

Photoelectrochemical cells have been used as one of the most common artificial photosynthetic approaches to mimic natural photosynthetic water splitting reactions. A photoelectrochemical cell (PEC) is a type of device that utilizes a light source onto a semiconductor or photosensitizer to produce electrical energy (similar to a dye-sensitized solar cell) or to trigger chemical reactions to store energy in the form of chemical bonds, i.e. the production of the hydrogen by the splitting of water.

Region with highest share:

The Asia Pacific is projected to hold the highest market share. The province has been segmented, by country, into Japan, China, India, and South Korea. The province faces a tough challenge to reduce its carbon footprint from various fossil-fuel-powered operations, including power generation. The Asia Pacific is one of the leading markets that have adopted green technologies to meet the targets set by the governments for reducing greenhouse gas emissions. Additionally, countries such as Japan and South Korea are increasing their investments in innovative energy & fuel generation technologies, such as fuel cells, carbon recycling, and others.

Region with highest CAGR:

North America is projected to have the highest CAGR, owing to the presence of supportive policies and incentives in the US for sustainable development projects. The rise in demand for uninterrupted power supply in the region will also boost the market growth during the forecast period. This has encouraged the use of clean fuels, such as hydrogen, for various energy requirements. For instance, in the US, the Hydrogen and Fuel Cell Technical Advisory Committee (HTAC) was established under Section 807 of the Energy Policy Act of 2005 to provide technical and programmatic advice to the Energy Secretary on the Department of Energy's (DOE) hydrogen research. The availability of research grants from the US Department of Energy (DOE) has fuelled research activities for an energy-efficient system in the country; this is expected to drive the research activities related to artificial photosynthesis in the province.

Key players in the market:

Some of the key players profiled in the Artificial Photosynthesis Market include Engie, Panasonic Corporation, FUJIFILM Corporation, Mitsubishi Chemical Corporation, Toshiba Corporation, Toyota Central R&D Labs., Inc., Siemens Energy, FUJITSU, Twelve (Formerly Known As, Op. 12), Evonik Industries AG.

Key developments:

In January 2020: ENGIE announced that it along with 8 partner institutes worked on a project named CONDOR. CONDOR is aimed at the production of fuels by using carbon dioxide (CO2) as feedstock and sunlight as the sole energy source. The project proposes a photosynthetic device made of two compartments a photoelectrochemical cell that splits water and CO2 and generates oxygen and syngas, a mixture of H2 and CO, and a (photo)reactor that converts syngas into methanol and dimethylether (DME), via bi-functional heterogeneous catalysts.

In October 2016: FUJITSU and University of Tokyo collaborated for the testing of artificial Photosynthesis developed by FUJITSU. Crystal Interface laboratory of University of Tokyo (Japan) was the site for testing. FUJITSU is continuing to work on further advances in photocatalyst materials and process technology to improve the characteristics of photoreactive electrodes and is working on developing technologies for the dark-reaction part (CO2-reducing reactions) and the overall system, with the goal of implementing artificial photosynthesis technology.

Catalysts Covered:

• Hydrogen Catalyst
• Photo Synthesizer
• Water-Oxidizing Catalyst

Types Covered:

• Photoelectrochemical Cells (PECs)
• Photovoltaic Cell-driven Electrolysers
• Suspended Nanopowder Photocatalysts

Technology's Covered:

• Co-electrolysis
• Photo-Electro Catalysis
• Other Technologies

Applications Covered:

• Hydrocarbons
• Chemicals
• Industrial

Regions Covered:

• North America
  • US
  • Canada
  • Mexico
• Europe
  • Germany
  • UK
  • Italy
  • France
  • Spain
  • Rest of Europe
• Asia Pacific
  • Japan
  • China
  • India
  • Australia
  • New Zealand
  • South Korea
  • Rest of Asia Pacific
• South America
  • Argentina
  • Brazil
  • Chile
  • Rest of South America
• Middle East & Africa
  • Saudi Arabia
  • UAE
  • Qatar
  • South Africa
  • Rest of Middle East & Africa

What our report offers:

• Market share assessments for the regional and country-level segments
• Strategic recommendations for the new entrants
• Covers Market data for the years 2020, 2021, 2022, 2025 and 2028
• Market Trends (Drivers, Constraints, Opportunities, Threats, Challenges, Investment Opportunities, and recommendations)
• Strategic recommendations in key business segments based on the market estimations
• Competitive landscaping mapping the key common trends
• Company profiling with detailed strategies, financials, and recent developments
• Supply chain trends mapping the latest technological advancements

Free Customization Offerings:

All the customers of this report will be entitled to receive one of the following free customization options:

• Company Profiling
  • Comprehensive profiling of additional market players (up to 3)
  • SWOT Analysis of key players (up to 3)
• Regional Segmentation
  • Market estimations, Forecasts and CAGR of any prominent country as per the client's interest (Note: Depends on feasibility check)
• Competitive Benchmarking
  • Benchmarking of key players based on product portfolio, geographical presence, and strategic alliances

Table of Contents

1 Executive Summary

2 Preface

• 2.1 Abstract
• 2.2 Stake Holders
• 2.3 Research Scope
• 2.4 Research Methodology
  • 2.4.1 Data Mining
  • 2.4.2 Data Analysis
  • 2.4.3 Data Validation
  • 2.4.4 Research Approach
• 2.5 Research Sources
  • 2.5.1 Primary Research Sources
  • 2.5.2 Secondary Research Sources
  • 2.5.3 Assumptions

3 Market Trend Analysis

• 3.1 Introduction
• 3.2 Drivers
• 3.3 Restraints
• 3.4 Opportunities
• 3.5 Threats
• 3.6 Technology Analysis
• 3.7 Application Analysis
• 3.8 Emerging Markets
• 3.9 Impact of Covid-19

4 Porters Five Force Analysis

• 4.1 Bargaining power of suppliers
• 4.2 Bargaining power of buyers
• 4.3 Threat of substitutes
• 4.4 Threat of new entrants
• 4.5 Competitive rivalry

5 Global Artificial Photosynthesis Market, By Catalyst

• 5.1 Introduction
• 5.2 Hydrogen Catalyst
• 5.3 Photo Synthesizer
• 5.4 Water-Oxidizing Catalyst

6 Global Artificial Photosynthesis Market, By Type

• 6.1 Introduction
• 6.2 Photoelectrochemical Cells (PECs)
• 6.3 Photovoltaic Cell-driven Electrolysers
• 6.4 Suspended Nanopowder Photocatalysts

7 Global Artificial Photosynthesis Market, By Technology

• 7.1 Introduction
• 7.2 Co-electrolysis
• 7.3 Photo-Electro Catalysis
• 7.4 Other Technologies
  • 7.4.1 Nanotechnology
  • 7.4.2 Hybrid process

8 Global Artificial Photosynthesis Market, By Application

• 8.1 Introduction
• 8.2 Hydrocarbons
• 8.3 Chemicals
• 8.4 Industrial
  • 8.4.1 Machinery and Equipment
  • 8.4.2 Automotive
  • 8.4.3 Aerospace and Defense
  • 8.4.4 Electricity Production
  • 8.4.5 Agriculture

9 Global Artificial Photosynthesis Market, By Geography

• 9.1 Introduction
• 9.2 North America
  • 9.2.1 US
  • 9.2.2 Canada
  • 9.2.3 Mexico
• 9.3 Europe
  • 9.3.1 Germany
  • 9.3.2 UK
  • 9.3.3 Italy
  • 9.3.4 France
  • 9.3.5 Spain
  • 9.3.6 Rest of Europe
• 9.4 Asia Pacific
  • 9.4.1 Japan
  • 9.4.2 China
  • 9.4.3 India
  • 9.4.4 Australia
  • 9.4.5 New Zealand
  • 9.4.6 South Korea
  • 9.4.7 Rest of Asia Pacific
• 9.5 South America
  • 9.5.1 Argentina
  • 9.5.2 Brazil
  • 9.5.3 Chile
  • 9.5.4 Rest of South America
• 9.6 Middle East & Africa
  • 9.6.1 Saudi Arabia
  • 9.6.2 UAE
  • 9.6.3 Qatar
  • 9.6.4 South Africa
  • 9.6.5 Rest of Middle East & Africa

10 Key Developments

• 10.1 Agreements, Partnerships, Collaborations and Joint Ventures
• 10.2 Acquisitions & Mergers
• 10.3 New Product Launch
• 10.4 Expansions
• 10.5 Other Key Strategies

11 Company Profiling

• 11.1 Engie
• 11.2 Panasonic Corporation
• 11.3 FUJIFILM Corporation
• 11.4 Mitsubishi Chemical Corporation
• 11.5 Toshiba Corporation
• 11.6 Toyota Central R&D Labs., Inc.
• 11.7 Siemens Energy
• 11.8 FUJITSU
• 11.9 Twelve (Formerly Known As, Op. 12)
• 11.10 Evonik Industries AG