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Short Summary
Developing cutting-edge materials to build a sustainable, carbon-neutral, renewable energy & future & researching technologies such as next-generation rechargeable batteries, bioplastics, quantum dot, metal-organic framework & artificial photosynthesis
Highlights
- Plant biomass based biodegradable plastics, resin, coating, paint, chemical
- Lithium sulfur battery, aluminium battery, Black mass recycled type battery
- Platinum less (free) fuel cell, Perovskite Solar Cell
- CO2 capture and utilization (CCU), Artificial Photosynthesis
- Cutting edge materials such as quantum dot, metal organic framework etc...
Overview
| Target | 300,000,000 |
| Minimum | 8,000,000 |
| Investment Raised | 0 |
| Previous Rounds | 0 |
| Stage | Breaking Even |
| Investor Role | Any |
The Business
Principles No more Petroleum, no more Fossil Fuels Problems 1) Global warming, climate change caused by the increase in CO2 emission. 2) Environmental problems such as plastic pollution, water pollution, food shortages, etc. Solutions and Opportunities 1) Plant or natural biomass-based biodegradable plastics, biomass-based chemicals 2) Next-generation rechargeable batteries 3) Platinumless (free) fuel cell 4) Perovskite Solar Cell 5) CO2 capture and utilization 6) Quantum dot-based special nano fertilizer from organic waste 7) Water harvesting from air 8) Advanced materials such as quantum dots, metal-organic framework, etc. All of these technologies are based on material design and synthesis at a molecular level.
The Market
World Market Size in Billion USD Bioplastics 2023 13.36 2030 44.77 Bio-based Coating 2022 11.5 2032 28.5 Bio-based Adhesive 2022 5.3 2032 14.1 Bio-based Ink, Paint 2023 195.5 2032 703.1 Bio-based Plasticizer 2024 3.22 2030 5.32 Bio-based Lubricant, Cutting Fluid 2023 2.6 2030 3.7 Bio 3D Printing 2023 2.3 2030 5.3 Bio-based UV curable Resin Products 2022 5.0 2027 8.0 Cellulose Fiber 2024 3.9 2034 5.2 Biochar 2023 0.2 2030 4.5 Bio-based Chemical Products Total 2022 - 2023 47.6 2030 - 2032 116.0 TAM 116 SAM 60 TOM 12 Rechargeable Battery 2022 70 2032 387 TAM 387 SAM 387 TOM 387 We can say this because we have very unique battery technology
Progress/Proof
1) Green Science Alliance Co., Ltd. was selected as one of the Climate Tech Startup Companies supported by the United Nations Program in 2020, Kobe, Japan (UNOPS S3i Innovation Centre Japan). 2) We have many biodegradable, biomass, and bioplastics certificates from TUV Rheinland, Japan BioPlastics Association, and Japan Organics Recycling Association. 3) We developed a black mass recycled type lithium-ion battery (https://www.prnewswire.com/news-releases/green-science-alliance-made-lithium-ion-battery-cathode-directly-from-recycle-material-named-black-mass-301905799.html) 4) https://www.prnewswire.com/news-releases/green-science-alliance-developed-lithium-sulfur-battery-as-next-generation-rechargeable-battery-301146187.html
Objectives/Future
In principle, because the CEO (Dr Ryohei Mori) has a PhD in Engineering, all of the company's products and business ideas come from his strong passion for building energy and environmentally friendly carbon neutral, sustainable society. He strives for cutting-edge research and tries to materialize those products and businesses as fast as possible with his strong will. He makes all the cutting-edge materials from molecular-level ideas and thoughts which can be applied to a wide range of products. 2024 - 2026 Business expansion of - Bioplastics, bio-based chemical products - Battery 2026 - 2032 - Quantum dot-based nano fertilizer - Water harvesting from air - Fuel Cell - Solar Cell - Artificial photosynthesis
The Team
Members in Japan Dr. Ryohei Mori (CEO), Ph.D in Engineering: All the Cutting Edge Technology Dr. Hideki Yoshioka, Ph.D in Engineering: Rechargeable Battery Dr. Tsutomu Konihata, Ph. D in Life Science: Fuel Cell Dr. Inubushi, Ph.D in Engineering: Rechargeable Battery Dr. Umemoto, Ph.D in Engineering: Bio-based Chemicals. Mr. Hironisa Iwabayashi: PhD in Engineering Candidate: CO2 capture and utilization Mr. Katsuji Konishi Mr. Tetsuro Kajino Members in Toronto, Canada Mr. Shida (Ex. one of Sony's representative in North America) Mr. Nakanishi Mr. Itoh and a few other members Members in Mexico Dr. Haneji: Environmental Technology Mr. Mateus Partner in USA. Mr. Trevor Tovsen Member in Switzerland Dr. Ryohei Mori
Ryohei Mori
CEO
CEO of Green Science Alliance Co., Ltd. CEO of Fuji Pigment Co., Ltd. CEO of Quantum Materials Technology Born : Hyogo, Japan (November, 9 , 1973) Summary of Professional Experience ? Research and Development, sales of highly advanced materials and products in the field of energy and environmentally friendly area. (Green Science Alliance Co., Ltd) 1. Rechargeable Alumininiuim Air Battery 2. Lithium ion battery, all solid state Lithium Ion Battery 3. Fuel Cell 4. Solar Cell 5. Carbon Nanotube Dispersion 6. Heterocatalysts 7. Theremoelectric Materials 8. Quantum dot, Quantum Dot Composite Materials 9. Metal Nanocolloids, Nanoparticles 10. Conductive Inks, Silver inks, Silver nanowire 11. Oxide Nanomaterials, Nanoparticles 12. Metal Organic Framework (MOF), Porous Coordination Polymers (PCP) 13. Hydroxyapatite 14. Nano Cellulose, Cellulose Nanofiber, Nano Cellulose and Resin Composite Materials 15. Ionic Liquid, Deep Eutectic Solvent 16. Chemicals for Water Cleaning. 17. Redox Flow Battery 18. Visible Light type Photocatalytic Materials 19. Materials for Artificial Photosynthesis 20. Biodegradable plastic, Biomass Plastic, Bioplastic, Biodegradable resin + Nano Cellulose Composite Materials, Starch based Biodegradable Plastic, Paper, Waste Paper based Biodegradable Plastic, Wood, Plant, Bamboo based Biodegradable Plastic. Biodegradable Plastic composed of 100 % Nature derived Materials (No Petroleum), 21. Bioethanol, Biofuel made of non edible biomass (Plant, Wood, Waste Wood, Waste Paper, Food Waste) ? Research and Development, sales of various type of color materials including Inkjet Ink, stationery ink, stamp inks and TV display inks etc… (Fuji Pigment Co., Ltd) ? Professional Translator (mainly Science and Technical documents) (Japanese to English, English to Japanese) WORK EXPERIENCE Fuji Pigment Co., LTD Research Department ?April, 2003 ? May 2007? (Hyogo, Japan) Nissha Co., LTD Sales Engineer ?April, 2008 ? March, 2009? (Kyogo, Japan and Oulu, Finland) ? Designing Touch panel screen for Nokia mobile phone with CAD. (Kyoto, Japan) ? Intermediate the research, technological and manufacturing issues between Nokia and Nissha (Oulu, Finland) Fuji Pigment Co., LTD Research Department ?April, 2009 ? May 2019? CEO (January, 2016 ? now) Green Science Alliance Co., Ltd. Establishment of Green Science Alliance as internal startup company within Fuji Pigment Co.,Ltd Research and Sales Department and CEO (January, 2010 ? now) EDUCATIONAL BACKGROUND 2021 General Management Program, Harvard Business School. (Massachusetts, USA) 1999-2003 Ph.D. in Engineering, Graduate School of Engineering, Kyoto University, (Kyoto,Japan) 1997-1999 M.Sc. in Science, Graduate School of Science, Kyoto University (Kyoto,Japan) 1993-1997 B.Sc.. in Agriculture, Faculty of Textile Science, Kyoto Institute of Technology, (Kyoto, Japan) 1992-1993… Inagawa High School (Hyogo, Japan) 1990-1992… McnaryHigh School (Oregon, USA) 1989-1990 Inagawa High School (Hyogo, Japan) 1980-1989 Ikeda Elementary and Junior High School attached to Osaka Kyoiku University LANGUAGE SKILLS Japanese-mother tongue, English-advanced, Very Basic German PUBLICATIONS 1. R. Mori, M. Takahashi and T. Yoko, 2D spinodal phase separated TiO2 film prepared by sol-gel process and photocatalytic activity, Materials Research Bulletin, 34, 1451 (2004) 2. R. Mori, M. Takahashi and T. Yoko, Photoelectrochemical and photocatalytic properties of TiO2 thin film with spinodal phase separation structure. Journal of Materials Research, 20, 121 (2005) 3. R. Mori, M. Takahashi and T. Yoko, Domain Size change of Spinodal Phase Separation Structure in the TiO2 Thin Film, Journal of Materials Research, 21, 270 (2006) 4. R.Mori, T. Ueta, K. Sakai, Y. Niida, Y. Koshiba, L. Lei, K. Nakamae, Y. Ueda, Organic solvent based TiO2 dispersion paste for dye sensitized solar cells prepared by industrial production level procedure, J. Material. Science,46, 1341 (2011). 5. R. Mori, A new structured aluminium - air secondary battery with a ceramic aluminium ion conductor, RSC Advances, 3, 29 (2013) 6. H. Mieda, A. Mineshige, T. Nishimoto, M. Tange, Y. Daiko, T. Yazawa, H. Yoshioka, R. Mori, Solid Oxide Fuel Cells Using Lanthanum Silicate Electrolyte Films, ECS Transactions, 57,1135 (2013). 7. R. Mori, A novel aluminium - Air rechargeable battery with A2lO3 as the buffer to suppress byproduct accumulation directly onto an aluminium anode and air cathode, RSC Advances, 4, 30346 (2014) 8. R. Mori, A novel aluminium - air secondary battery with long term stability, RSC Advances, 4, 1982 (2014) 9. H. Yoshioka, H. Mieda, T. Funahashi, A. Mineshige, T. Yazawa, R. Mori, Fabrication of apatite-type lanthanum silicate films and anode supported solid oxide fuel cells using nano-sized printable paste, Journal of the European Ceramic Society, 34, 373 (2014) 10. R. Mori, Lithium Ion Secondary Cell Prepared by a Printing Procedure, and Its Application to All-Solid-State Inorganic Lithium Ion Cells, Journal of Electronic Materials, 3, 1166 (2014). 11. H. Mieda, A. Mineshige, A. Saito, T. Yazawa, H. Yoshioka, R. Mori, Influence of nano-sized LSCF cathode and its firing temperature on electrochemical performance in oxygen-excess-type solid electrolyte (OESE)-based fuel cells, Journal of Power Sources, 272, 422 (2014) 12. R. Mori, Addition of Ceramic Barriers to Aluminum–Air Batteries to Suppress By-product Formation on Electrodes, Journal of Electrochemical Society, 162, 288 (2015) 13. R. Mori, Inorganic–organic hybrid biodegradable polyurethane resin derived from liquefied Sakura wood, Wood Science and Technology, 49, 3, 507 (2015) 14. R. Mori, Capacity recovery of aluminium air battery by refilling salty water with cell structure modification, J. Applied Electrochemistry, 45, 821 (2015) 15. R. Mori, Semi-rechargeable Aluminum - Air Battery with a TiO2 Internal Layer with Plain Salt Water as an Electrolyte, Journal of Electronic Materials, 45, 3375 (2016) 16. R. Mori, Electrochemical properties of a rechargeable aluminum - air battery with a metal organic framework as air cathode material, RSC Advances, 7 ,6389 (2017) 17. R. Mori, Suppression of byproduct accumulation in rechargeable aluminum - air batteries using non-oxide ceramic materials as air cathode materials, Sustainable Energy Fuels., 1 1082 (2017) 18. R. Mori, Rechargeable Aluminum–Air Battery Using Various Air-Cathode Materials and Suppression of Byproducts Formation on Both Anode and Air Cathode, ECS Transactions, 80,10, 377 (2017). 19. R. Mori, Semi solid-state aluminium air batteries with electrolytes composed of aluminium chloride hydroxide with various hydrophobic additives, R. Mori, Physical Chemistry Chemical Physics, 20, 29983 (2018) 20. R. Mori, All solid state rechargeable aluminum - air battery with deep eutectic solvent based electrolyte and suppression of byproducts formation, RSC Adv., 9, 22220-22226 (2019). 21. R. Mori, Recent Developments for Aluminum–Air Batteries, Electrochemical Energy Reviews,?3, 344 (2020) 22. A. Mineshige, A. Saito, M. Kobayashi, H. Hayakawa, M. Momai, T. Yazawa, H. Yoshioka, M. Sakao, R. Mori, Y. Takayama, Y. Kagoshima, J. Matsui, Lanthanum silicate-based layered electrolyte for intermediate-temperature fuel cell application, Journal of Power Sources, 475, 1, 228543 (2020) 23. R. Mori, Replacing all petroleum-based chemical products with natural biomass-based chemical products: a tutorial review, RSC Sustainability, 1,179 (2023). 24. R. Mori, Cathode materials for lithium-sulfur battery: a review, J. Solid State Electrochem., 27, 813 (2023). 25. R. Mori, Separator Materials for Lithium Sulfur Battery - A Review, Electrochem, 4(4) 485 (2023). 26. R. Mori, CO2 Photocatalytic Reduction with Robust and Stable Metal Organic Framework – A Review, Materials for Renewable and Sustainable Energy. Accepted for Publication. (2024). International Conferences. 1. R. Mori, All Solid-State Printable Inorganic Type Lithium Ion Battery, ECerS 2011 XII, 19/June/2011, Stockholm, Sweden. 2. R. Mori, H. Yoshioka, H. Mieda, A. Mineshige, Preparation of Lanthanum Silicate Electrolyte Film with nano sized dispersed particle paste and its application to middle temperature ranged SOFC, 63 rd annual meeting of the international society of electrochemistry, 19/August/2012?Prague, Czech Republic 3. R. Mori, H. Yoshioka, H. Mieda, A. Mineshige, Fabrication of Anode Supported SOFC with Apatite type Lanthanum Silicate Paste Films, 3/June/2013, Acers Meeting, 10th Pacific Rim Conference on Ceramic and Glass Technology, San Diego, USA 4. R. Mori, A. Mineshige, T. Yazawa, H. Yoshioka, Preparation of Lanthanum Silicate Electrolyte Film with nano sized dispersed particle paste and its application to middle temperature ranged SOFC, 11th European SOFC and SOE Forum 2014, 1/July/2014, Lucerne Switzerland. 5. R. Mori, New Structured Aluminium – Air Secondary Battery with Long Term Stability, 225 th ECS Meeting 11/May/2014?Orland, Florida, USA 6. R. Mori, Rechargeable Aluminum-Air Battery Using Various Air-Cathode Materials and Suppression of Byproducts Formation on both Anode and Air Cathode., 232 ECS Meeting, 1.October/2017, Washington, National Harbour, MD, USA 7. R. Mori, Rechargeable Aluminum-Air Battery Using Various Air-Cathode Materials and Suppression of Byproducts Formation on both Anode and Air Cathode, 3rd Green Sustainable Chemistry Conference, 13/May/2018, Berlin, Germany 8. R. Mori, Nano cellulose composite, International Symposium on Nanocellulosic Materials, 17/May/2019, Tianjin, China 9. R. Mori, All solid state rechargeable aluminium air battery, 25-29/August/2019, American Chemical Society, National Meeting and Expo, San Diego, USA 10. R. Mori, 100% nature biomass based biodegradable material made from wood, stone and natural deep eutectic solvent, 21-25/August/2022, American Chemical Society, ACS Meeting and Expo, Chicago, USA On top of above publications, over 60 scientific publications in Japanese and over 40 times of scientific lecture in Japanese. Those topic includes rechargeable aluminium air battery, lithium ion battery, lithium sulfur battery, nano technology, quantum dot, metal organic framework, rare metal extraction, bioplastic and bio based chemicals etc… Award 1. New Value Creation Exhibition (2015) Best H!NT Award Received 2. S ? P Global Platts Global Metal Award (2018) Nominated 3. Green Science Alliance Co., Ltd. was selected as United Nation Startup Program in Sustainability by UNOPG GIC KOBE (2020) 4. Dr. Ryohei Mori research article titled “Replacing all petroleum-based chemical products with natural biomass-based chemical products: a tutorial review” makes front cover of British scientific journal "RSC Sustainability". Memberships American Chemical Society
The Deal
Looking for PKR 3,277,000,000 - Min per Investor PKR 8,200,000 5 - 20 million USD against 2 -10 % Equity. Negotiable.