Silicon Carbon TRGT-200 Battery Anode Material

Overview of Silicon Carbon TRGT-2000

Silicon Carbon TRGT-2000 represents the cutting edge in high-capacity anode technology. This material is engineered to deliver an ultra-high specific capacity, pushing the boundaries of energy density for the next generation of lithium-ion batteries. By mastering the integration of silicon into a carbon matrix, TRGT-2000 achieves a remarkable typical capacity of over 2000 mAh/g while maintaining critical structural stability. It is the ideal solution for battery manufacturers aiming to develop longer-range electric vehicles and more durable high-end electronics, without compromising on cycle life.

Features of Silicon Carbon TRGT-2000

• Ultra-High Energy Density: Offers an exceptional typical capacity of 2018 mAh/g, one of the highest available in silicon-carbon composite materials.
• Engineered Low Expansion: Formulated to manage the volume change of silicon, ensuring electrode integrity and supporting a long cycle life.
• High First-Coulomb Efficiency: Features a high initial efficiency (≥89.2%), maximizing active lithium inventory and improving overall energy output.
• Optimized Particle Design: A controlled particle size distribution ensures excellent processability and electrochemical performance.

Applications of Silicon Carbon TRGT-2000

TRGT-2000 is designed for advanced battery systems where maximizing energy is paramount. Its primary applications include:

• Next-Generation Solid-State Batteries
• High-Energy-Density Semi-Solid-State Batteries
• Advanced Liquid Electrolyte Batteries for premium applications

Specification Table of Silicon Carbon TRGT-2000

Item	Parameter	Unit	Standard	Typical Value
Particle Size	D50	μm	11.0±1.0	11.39
Tap Density	TAP	g/cc	0.6±0.1	0.62
Specific Surface Area	SSA	m²/g	17±2	16.68
Capacity (1.5V)	–	mAh/g	2000±100	2018
Initial Coulombic Efficiency (1.5V)	–	%	≥89.2%	89.46

Company Profile

Rboschco is a trusted global chemical material supplier & manufacturer with over 12-year-experience in providing super high-quality chemicals and nanomaterials, including boride powder, nitride powder, graphite powder, sulfide powder, 3D printing powder, etc.

The company has a professional technical department and Quality Supervision Department, a well-equipped laboratory, and equipped with advanced testing equipment and after-sales customer service center.

If you are looking for high-quality Battery Materials, please feel free to contact us or click on the needed products to send an inquiry. 

Payment Term

L/C, T/T, Western Union, Paypal, Credit Card etc.

Shipment Term

By sea, by air, by express, as customers request.

5 FAQs of Silicon Carbon TRGT-2000

1. How does TRGT-2000’s capacity compare to TRGT-800 and graphite?
TRGT-2000 offers an ultra-high capacity of ~2000 mAh/g, which is more than double that of TRGT-800 (~810 mAh/g) and over five times that of conventional graphite (~360 mAh/g).

2. The tap density is lower than TRGT-800. What does this mean for cell design?
A lower tap density (0.62 g/cc for TRGT-2000 vs. 1.12 g/cc for TRGT-800) indicates a more porous material. While this may slightly impact electrode volumetric density, the vastly higher specific capacity ultimately results in a significantly higher overall energy density at the cell level.

3. Why is the specific surface area (SSA) higher for TRGT-2000?
The higher SSA (16.68 m²/g) is typical for materials with very high silicon content and a porous structure designed to accommodate volume expansion. This is managed through specialized binder and electrolyte systems to ensure good performance.

4. Is this material suitable for fast charging?
The data shows testing at 0.8C rates, confirming good rate capability. For very high-power applications, further cell design optimization may be recommended to fully leverage the high capacity.

5. Can TRGT-2000 be used in existing battery production lines?
Yes, it is designed for use in standard battery manufacturing processes for solid-state, semi-solid, and liquid electrolyte systems, making it a drop-in solution for upgrading energy density.