Product type
Water-based SWCNT conductive slurry.
Water-based SWCNT slurry
TYBH Water-Based SWCNT Conductive Slurry
A water-based SWCNT conductive slurry developed for LFP, ESS, and other aqueous electrode systems requiring stable dispersion and process-friendly rheology.
Water-Based System
LFP
ESS
Aqueous Electrode Process
Aqueous-process review
- SWCNT
- 0.40 wt.%
- Dispersant
- 0.60 wt.%
- Viscosity
- 1728 mPa·s
- pH
- 7.16
Primary fit
LFP, ESS, and other aqueous electrode programs that need a water-based conductive slurry route.
Rheology profile
Pseudoplastic and thixotropic behavior intended to support processing while maintaining storage stability.
Quick facts
Discuss Aqueous Fit
What TYBH is and where it fits
Primary fit
LFP and ESS.
Main advantage
Stable aqueous dispersion.
Rheology
Pseudoplastic and thixotropic.
Format
Slurry.
Screening stage
Aqueous process-fit and formulation evaluation.
Technical specifications
Public TYBH values for early screening
| Parameter | Value |
|---|---|
| SWCNT | 0.40 wt.% |
| Dispersant | 0.60 wt.% |
| Deionized Water | 99.00 wt.% |
| Solid Content | 0.97 |
| Optical Density | 0.586 |
| Viscosity | 1728 mPa·s |
| pH | 7.16 |
Values shown are based on the TYBH test report.
Best fit applications
Where TYBH is most likely to fit
LFP cathodes
A fit for LFP programs that need a water-based conductive slurry route during early formulation screening.
Energy storage systems (ESS)
Relevant to ESS programs that are evaluating aqueous processing and stable dispersion behavior together.
Water-based electrode systems
Designed for teams working inside aqueous electrode systems rather than NMP-based process routes.
Aqueous conductive-slurry screening
Useful when the main question is whether a water-based SWCNT slurry fits the current formulation path.
Why TYBH
A water-based view of TYBH
TYBH is positioned for water-based conductive-slurry evaluation rather than non-aqueous process routes. It is intended for teams working in aqueous systems where dispersion stability, rheology behavior, and process fit all matter early in screening.
The product is described as environmentally friendlier than NMP-based slurry positioning and is designed for stable aqueous dispersion. Its pseudoplastic and thixotropic behavior is part of the practical engineering story: the slurry is intended to maintain storage stability while remaining flow-capable during processing.
For technical buyers, that means TYBH can be evaluated as a water-based SWCNT slurry for LFP, ESS, and related aqueous electrode systems, especially when process-friendly rheology is part of the decision rather than an afterthought.
TYBH is usually a good fit when
- You need a water-based conductive slurry.
- You are evaluating LFP or ESS systems.
- You want to assess aqueous dispersion stability.
- Your team needs process-friendly rheology in a water-based formulation.
TYBH is less ideal when
- Your workflow is specifically NMP-based.
- You are comparing only oil-based conductive slurry options.
- You need a different process format than aqueous slurry.
Validation checklist
What engineers should validate next
1. pH fit with the current aqueous formulation
Confirm whether the measured pH aligns with the rest of the water-based formulation window.
2. Coating behavior under process shear
Check whether rheology remains workable through the coating and handling conditions used in the current line.
3. Storage stability versus process flow
Review whether the slurry stays stable in storage while still flowing as needed during processing.
4. Dispersion uniformity in water-based systems
Confirm that dispersion stays uniform enough for meaningful formulation comparison in aqueous systems.
5. Formulation fit for LFP or ESS performance targets
Review whether the slurry fits the target LFP or ESS formulation path before scaling conclusions too far.
Related technical pages
Related technical pages
Use these pages to place TYBH inside the most relevant aqueous-process and application context.
Review SWCNT fit in LFP and ESS programs
Use the application page to frame TYBH around aqueous-friendly LFP and storage use cases.
Review water-based electrode processing guidance
Connect TYBH to the main water-based electrode application route.
Read the SWCNT engineering screening guide
Use a structured screening guide before drawing conclusions from the first aqueous trials.
See how CNT conductive slurry supports electrode design
Use the article for broader engineering context on conductive-network design.
Downloads & resources
Resources for TYBH evaluation
Download Data Sheet
Technical documents are available upon request through the inquiry flow.
Read Technical Guide
Use the HTML technical guide to organize early screening and formulation review.
Contact for Sample Evaluation
Start an aqueous-process discussion around sample evaluation and formulation fit.
FAQ
TYBH FAQ
What is TYBH best suited for?
TYBH is best suited for LFP cathodes, energy storage systems, water-based electrode systems, and teams screening aqueous conductive slurry options.
Is TYBH a water-based conductive slurry?
Yes. TYBH is a water-based SWCNT conductive slurry intended for aqueous electrode systems rather than NMP-based workflows.
What rheology behavior does TYBH show?
TYBH is described as pseudoplastic and thixotropic, which means it is positioned to maintain storage stability while remaining flow-capable during processing.
What should engineers validate first when screening TYBH?
Start with pH fit in the current aqueous formulation, coating behavior under process shear, storage stability versus process flow, dispersion uniformity in water-based systems, and formulation fit for LFP or ESS targets.
Is TYBH more suitable for LFP and ESS than NMP-based systems?
Based on the visible page positioning, TYBH is more suitable for LFP, ESS, and other aqueous electrode systems than for specifically NMP-based process routes.
Next step
Request a TYBH sample or discuss aqueous-process evaluation with our team.
Use the inquiry flow to share your water-based formulation path, coating questions, and LFP or ESS goals so the technical discussion starts with the right context.