Revolutionizing
Battery Tech & Recycling for Renewable Energy
The future is Solid-state Sodium Silicate Batteries
Wide Range of Applications
These batteries provide reliable and sustainable energy solutions for various sectors, contributing to the overall efficiency and sustainability of renewable energy systems.
Drones, and Biomedical Devices
Mobile
Electronics
E-mobility
Stationary
Storage
Electronics
Do business with us using our
solutions & become
part of the change!
Entity2's batteries are designed to minimize environmental impact while offering cost-effective and advanced battery solutions. They are safer and have a longer cycle life, addressing critical issues such as resource dependency, high production costs, and limited recyclability.
At Mobility, we are your premier source for renewable energy storage and sustainable battery technology. Our Solid-state Sodium Silicate Batteries (SSSB) represent a groundbreaking advancement, utilizing locally available materials like phyllosilicate.
Breakthrough
Next-Generation Solid-State Batteries
Solid-state Sodium Silicate Batteries (SSSB):
A groundbreaking technology utilizing locally available materials like phyllosilicate, offering low environmental impact, cost-effectiveness, enhanced safety, and longer cycle life.
These advancements hold immense potential for Green Energy Tech Companies striving for innovative solutions in the renewable energy sector.
Patented Technology
Microbial Electrochemical Cell (MECC) revolutionizes waste recycling with a patented process achieving over 96% recovery efficiency.
Environment-Friendly Batteries
Innovative solid-state sodium silicate batteries offer a greener alternative with reduced environmental impact and enhanced safety.
Long Cycle
Life
Solid-state sodium silicate batteries provide extended lifespan and superior performance, making them ideal for sustainable energy solutions.
Batteries Developed for Various Segments
Advanced batteries from ENTITY 2 support diverse applications including e-mobility, stationary storage, and consumer electronics.
Advancing energy sustainability: Next-gen batteries and eco-recycling
Explore Our Products
Attached to a Hydrogen Producing Fuel Cell this becomes a star performer for electricity from Hydrogen
Coin cell made from Solid State Sodium Silicate Technology
The Mini-Magic - a storage device capable of recharging phones and laptops
the HKBFC - an unique Base Fructum Cone for new cell applications
The Prismatic Super Performance
Battery for automotive drive chain applications
Meet Entity 2's Leadership Team of Experts Devoted to Success
Pankaj Agrawal
Chairman
Kaushik Palicha
Founder & Inventor
Dr. Harinipriya
Chief Scientist
Mita Samant
Director Finance & Investor Relations
Besky Christopher
Director Accounts & Compliances
Dr. Ruchir Gupta
Advisor
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Dr. Chinmaya K A
Energy Systems Design Engineer
Latest news
Revolutionary Flexible Solar Cells in Renewable Energy
5 November 2024
The Future of Renewable Energy Storage Solutions
13 July 2024
Innovative Materials for Efficient Energy Storage
25 September 2024
MSDS OF 2D NANOBORON SHEETS
1 October 2024
Frequently asked
questions
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What is ENTITY 2?ENTITY 2 is a groundbreaking project focused on revolutionizing battery technology and recycling for renewable energy. Our goal is to develop safer, more sustainable alternatives to traditional lithium-ion batteries and to enhance recycling methods to support a circular economy.
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What are Solid-state Sodium Silicate Batteries (SSSB)?Solid-state Sodium Silicate Batteries (SSSB) utilize locally available materials like phyllosilicate, offering low environmental impact, cost-effectiveness, enhanced safety, and longer cycle life. These batteries are essential for Green Energy Tech Companies seeking innovative solutions in renewable energy.
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What is a Microbial Electrochemical Cell (MECC)?Microbial Electrochemical Cell (MECC) is a patented solution for recycling and recovering materials from waste, including batteries. It addresses environmental concerns associated with traditional recycling methods and supports sustainability and resource efficiency.
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How efficient is the MECC recycling process?The MECC recycling process boasts a high recovery efficiency of over 96%, making it a leading technology in circular economy initiatives. It effectively repurposes waste materials, significantly contributing to carbon footprint reduction.
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What are the benefits of using sodium and magnesium-based batteries?Sodium and magnesium-based batteries offer several benefits over traditional lithium-ion batteries, including: Enhanced safety Lower environmental impact Cost-effectiveness Longer cycle life These features make them ideal for Renewable Energy Systems and sustainable energy storage solutions.
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How do Quasi-Solid State Magnesium Batteries compare to traditional batteries?Quasi-Solid State Magnesium Batteries (QSSMgBs) offer improved safety, specific capacity, and gravimetric energy density compared to traditional batteries. They are particularly suited for stationary storage and low-power electronics.
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What is the significance of CAM and Electrolyte conductivity in batteries?CAM (Cathode Active Material) and Electrolyte conductivity are critical parameters in battery performance. High conductivity ensures efficient energy transfer and longer battery life, essential for advanced battery technologies like SSMgBs and SSSBs.
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How does MECC contribute to reducing carbon emissions?MECC contributes to reducing carbon emissions by ensuring complete recovery of minerals, metals, and other components from spent batteries. It also converts plastics into methane and hydrogen, further aiding in greenhouse gas emission reduction.
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What advancements are being made in battery technology by ENTITY 2?ENTITY 2 is pioneering several advancements in battery technology, including: Solid-state Sodium Silicate Batteries (SSSB) Quasi-Solid State Magnesium Batteries (QSSMgBs) Microbial Electrochemical Cell (MECC) for efficient recycling These technologies promise enhanced safety, sustainability, and efficiency for renewable energy applications.
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Why is sustainable recycling important for the renewable energy sector?Sustainable recycling is crucial for the renewable energy sector because it: Reduces environmental pollution Supports resource efficiency Contributes to a circular economy Helps in lowering greenhouse gas emissions Innovations like MECC ensure that recycling processes are environmentally friendly and efficient.
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What is the environmental impact of traditional recycling methods?Traditional recycling methods often lead to environmental pollution and hazardous by-products. In contrast, MECC offers a green and sustainable solution, with zero waste generation and no environmental hazards.
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How can companies benefit from ENTITY 2's technologies?Companies can benefit fromENTITY 2's technologies by: Adopting safer, more sustainable battery alternatives Leveraging efficient recycling methods to reduce waste Enhancing their renewable energy systems with advanced battery solutions Contributing to global carbon emission reduction efforts
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How does ENTITY 2 support the circular economy?ENTITY 2 supports the circular economy by: Developing technologies like MECC that ensure complete recovery of valuable materials Promoting the reuse and repurposing of waste products Reducing the environmental impact of battery production and disposal
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What are the applications of the advanced batteries developed by ENTITY 2?The advanced batteries developed by ENTITY 2 have a wide range of applications, including: E-mobility Stationary storage Low power electronics Mobile electronics These batteries provide reliable and sustainable energy solutions for various sectors.
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How can I learn more about ENTITY 2 and its technologies?To learn more about ENTITY 2 and its groundbreaking technologies, visit our website or contact our team. Stay updated on our latest developments and innovations in battery technology and recycling for renewable energy.
Breakthrough
Next-Generation Solid-State Batteries
The present invention targets utilization of sodium-based phyllosilicates that are environmentally benign and naturally available as solid-state electrolyte (SSE) solid-state sodium silicate battery (SSSB). SSSB assembly is having sodium meta silicate as Cathode active material (CAM), carbon black as anode active material (AAM), and SSE formed by
coating a separator membrane with a naturally Sodium (Na) and Calcium (Ca) rich material
(Na-Ca rich material), wherein the Na-Ca-rich material is further enriched with sodium (Na).
The SSSB exhibits a specific capacity of up to 208.48 mAh/g, and a cycle stability of up to10,000 cycles and 45.52 hours at 0.1 C-rate at 0.022A/g discharge current density in anoperating potential window between -2 to 2 V. The SSSB exhibits a Gravimetric EnergyDensity of 1.705 kWh/kg.
Magnesium Air
The product is a novel disclosure for the utilisation of a natural phyllosilicate soaked in Mg-enriched alkaline medium, as solid-state electrolyte (SSE) for Magnesium-Air (Mg-Air) fuel cell. Mg-Air hydroxyl-ion-doped cathode, a Magnesium anode, and an electrolyte containing a Mg-rich material. The cathode directly supplies OHions to the anode for the formation of Mg(OH)2 and subsequent formation of MgO without involving Oxygen reduction reaction (ORR). This eliminates the internal resistance associated with ORR and improves the performance of Mg-Air fuel cell. The Mg-Air Fuel Cell of the present disclosure possess specific capacity of 2075 mAh/g and an energy density of 323 Wh/kg.
Bio Battery
The current discovery provides a non-enzymatic biodegradable electrochemical cathode comprising Microtubules (MTs) isolated from natural sources, preferably from plant sources, and a process for fabricating the cathode. In an aspect of the present disclosure, a biodegradable electrochemical cell is provided using the biodegradable electrochemical cathode, wherein the anode material includes a carbon rich material such as Carbon Black (CB), graphite or graphene, or the anode includes a biopolymer such as ethyl cellulose. The specific capacity and gravimetric energy were achieved as 63.20 mAh/g and 13.53 kWh/kg, respectively, and exhibited cycling stability upto 10000.
The product is a novel disclosure for the utilisation of a natural phyllosilicate soaked in Mg-enriched alkaline medium, as solid-state electrolyte (SSE) for Magnesium-Air (Mg-Air) fuel cell. Mg-Air hydroxyl-ion-doped cathode, a Magnesium anode, and an electrolyte containing a Mg-rich material. The cathode directly supplies OHions to the anode for the formation of Mg(OH)2 and subsequent formation of MgO without involving Oxygen reduction reaction (ORR). This eliminates the internal resistance associated with ORR and improves the performance of Mg-Air fuel cell. The Mg-Air Fuel Cell of the present disclosure possess specific capacity of 2075 mAh/g and an energy density of 323 Wh/kg.
Magnesium Air
The current discovery provides a non-enzymatic biodegradable electrochemical cathode comprising Microtubules (MTs) isolated from natural sources, preferably from plant sources, and a process for fabricating the cathode. In an aspect of the present disclosure, a biodegradable electrochemical cell is provided using the biodegradable electrochemical cathode, wherein the anode material includes a carbon rich material such as Carbon Black (CB), graphite or graphene, or the anode includes a biopolymer such as ethyl cellulose. The specific capacity and gravimetric energy were achieved as 63.20 mAh/g and 13.53 kWh/kg, respectively, and exhibited cycling stability upto 10000.
Bio Battery
Breakthrough
Next-Generation Solid-State Batteries
The present invention targets utilization of sodium-based phyllosilicates that are environmentally benign and naturally available as solid-state electrolyte (SSE) solid-state sodium silicate battery (SSSB). SSSB assembly is having sodium meta silicate as Cathode active material (CAM), carbon black as anode active material (AAM), and SSE formed by
coating a separator membrane with a naturally Sodium (Na) and Calcium (Ca) rich material
(Na-Ca rich material), wherein the Na-Ca-rich material is further enriched with sodium (Na).
The SSSB exhibits a specific capacity of up to 208.48 mAh/g, and a cycle stability of up to10,000 cycles and 45.52 hours at 0.1 C-rate at 0.022A/g discharge current density in anoperating potential window between -2 to 2 V. The SSSB exhibits a Gravimetric EnergyDensity of 1.705 kWh/kg.
Magnesium Air
The product is a novel disclosure for the utilisation of a natural phyllosilicate soaked in Mg-enriched alkaline medium, as solid-state electrolyte (SSE) for Magnesium-Air (Mg-Air) fuel cell. Mg-Air hydroxyl-ion-doped cathode, a Magnesium anode, and an electrolyte containing a Mg-rich material. The cathode directly supplies OHions to the anode for the formation of Mg(OH)2 and subsequent formation of MgO without involving Oxygen reduction reaction (ORR). This eliminates the internal resistance associated with ORR and improves the performance of Mg-Air fuel cell. The Mg-Air Fuel Cell of the present disclosure possess specific capacity of 2075 mAh/g and an energy density of 323 Wh/kg.
The product is a novel disclosure for the utilisation of a natural phyllosilicate soaked in Mg-enriched alkaline medium, as solid-state electrolyte (SSE) for Magnesium-Air (Mg-Air) fuel cell. Mg-Air hydroxyl-ion-doped cathode, a Magnesium anode, and an electrolyte containing a Mg-rich material. The cathode directly supplies OHions to the anode for the formation of Mg(OH)2 and subsequent formation of MgO without involving Oxygen reduction reaction (ORR). This eliminates the internal resistance associated with ORR and improves the performance of Mg-Air fuel cell. The Mg-Air Fuel Cell of the present disclosure possess specific capacity of 2075 mAh/g and an energy density of 323 Wh/kg.
Magnesium Air
The current discovery provides a non-enzymatic biodegradable electrochemical cathode comprising Microtubules (MTs) isolated from natural sources, preferably from plant sources, and a process for fabricating the cathode. In an aspect of the present disclosure, a biodegradable electrochemical cell is provided using the biodegradable electrochemical cathode, wherein the anode material includes a carbon rich material such as Carbon Black (CB), graphite or graphene, or the anode includes a biopolymer such as ethyl cellulose. The specific capacity and gravimetric energy were achieved as 63.20 mAh/g and 13.53 kWh/kg, respectively, and exhibited cycling stability upto 10000.
Bio Battery
Bio Battery
The current discovery provides a non-enzymatic biodegradable electrochemical cathode comprising Microtubules (MTs) isolated from natural sources, preferably from plant sources, and a process for fabricating the cathode. In an aspect of the present disclosure, a biodegradable electrochemical cell is provided using the biodegradable electrochemical cathode, wherein the anode material includes a carbon rich material such as Carbon Black (CB), graphite or graphene, or the anode includes a biopolymer such as ethyl cellulose. The specific capacity and gravimetric energy were achieved as 63.20 mAh/g and 13.53 kWh/kg, respectively, and exhibited cycling stability upto 10000.