SilEcoCell™ Technology  ·  Australian Innovation  ·  Next-Gen Anodes

TURNING BIO WASTE
INTO BATTERY POWER

SilEcoCell™ converts rice husk, corn husk, and biomass residues into advanced graphite–silicon anode materials — delivering cleaner, scalable solutions for next-generation lithium-ion batteries.

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SCROLL
80% CO₂ Reduction ·
SilEcoCell™ Proprietary Process ·
Biomass Pyrolysis ·
Circular Material Economy ·
EV Battery Ready ·
Australia Prestons NSW ·
Nanovace Technologies Group ·
BioGraphite BioSilicon Outputs ·
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Biomass Feedstocks
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Core Process Steps
Circular Value Chain
Company Profile

AUSTRALIAN
INNOVATION

Enersil Pty Ltd is a subsidiary of Nanovace Technologies Ltd. — an Australian innovation company focused on transforming underutilized agricultural waste into high-value battery materials.

Through our proprietary SilEcoCell™ process, we enable the production of sustainable anode materials that reduce emissions, improve supply chain resilience, and create circular value.

Global battery supply chains face increasing pressure to decarbonize. Enersil offers a low-carbon, scalable, and locally deployable alternative supporting the transition to cleaner energy.

🌾
WASTE TO RESOURCE
Agricultural residues transformed into high-value battery inputs
🔋
DROP-IN READY
Compatible with existing lithium-ion battery systems
🌏
SUPPLY SECURITY
Localised, traceable, resilient material sourcing
📉
DECARBONISATION
Up to 80% reduction in lifecycle CO₂ emissions
enersil_profile.json
entity_nameEnersil Pty Ltd
parent_companyNanovace Technologies
domicilePrestons, NSW, AU
core_techSilEcoCell™
feedstock_inputsRice · Corn · Biomass
primary_outputBioGraphite–BioSilicon
co2_reduction↓ 80% lifecycle
compatibilityLi-ion drop-in
supply_modelLocal & Traceable
statusActive · Seeking Partners
SilEcoCell™ Process

A BREAKTHROUGH IN
ANODE MATERIALS

SilEcoCell™ converts biomass into advanced graphite–silicon anode materials compatible with existing lithium-ion battery systems — delivering performance and sustainability without compromise.

01
BIOMASS PYROLYSIS
Agricultural residues thermally decomposed in oxygen-free environment producing carbon-rich biochar
02
CATALYTIC GRAPHITISATION
Biochar transformed into ordered graphitic carbon via controlled catalytic temperature processing
03
SILICA REDUCTION
Natural silica from biomass reduced at low temperatures to yield high-purity nanosilicon
04
Si–C COMPOSITE
BioGraphite and BioSilicon combined into silicon-carbon composite optimised for anode performance
// FEEDSTOCK INPUTS
Rice husk
Corn husk
Silica-rich agricultural residues
PROCESS
// MATERIAL OUTPUTS
BioGraphite–BioSilicon composite
Nanosilicon
Carbon & alumina by-products
80%
LOWER CARBON
Up to 80% reduction in lifecycle CO₂ vs conventional anode production
CIRCULAR VALUE
Waste-to-resource transformation closes the loop on agricultural by-products
$↓
COST ADVANTAGE
Abundant, low-cost feedstocks combined with efficient processing
🔒
SUPPLY SECURITY
Localised, traceable sourcing reduces geopolitical risk
// APPLICATIONS
⚡ ELECTRIC VEHICLE BATTERIES 🏭 STATIONARY ENERGY STORAGE 📱 CONSUMER ELECTRONICS 🔬 NEXT-GEN Li-ION MANUFACTURING
Collaboration Ecosystem

BUILT FOR THE ENTIRE
CLEAN ENERGY ECOSYSTEM

🔋
BATTERY MANUFACTURERS & EV SUPPLY CHAIN
ENERGY SOLUTIONS DEVELOPERS
💼
STRATEGIC INVESTORS & VENTURE PARTNERS
🏛
GOVERNMENT & RESEARCH BODIES
🧪
ADVANCED MATERIALS & CLEAN-TECH