Triisobutyl Phosphate: A Versatile Additive for Textile Processing and Paper Manufacturing, Providing Defoaming, Wettability, and Anti-Static Properties

High-Performance 1,3-Bis[3-(dimethylamino)propyl]urea: The "Swiss Army Knife" of Polyurethane Catalysis
By Dr. Linus Polymers, Senior Formulation Chemist at NovaFoam Labs

Let’s talk about catalysts — not the kind that gets you through a Monday morning (though coffee might qualify), but the ones that make polyurethanes go brrr. In the world of foam, elastomers, and coatings, timing is everything. You want your reaction to start just right — not too fast, not too slow — like Goldilocks’ porridge, but with more exotherms and fewer bears.

Enter 1,3-Bis[3-(dimethylamino)propyl]urea, or as I like to call it affectionately, “Bis-Urea” 🧪 — a molecule so cleverly designed it practically moonlights as both a comedian and a chemist. It’s got dual functionality: tertiary amine groups for catalytic punch and a urea core for hydrogen-bonding finesse. This isn’t just a catalyst; it’s a multitasking maestro in a beaker.

⚛️ What Exactly Is Bis-Urea?

At first glance, Bis-Urea looks like someone took two dimethylaminopropylamines, tied them together with a urea bridge, and said, “Let’s see what happens.” And what happened was… magic.

Its chemical structure features:

Two tertiary amine groups – excellent for promoting isocyanate–polyol reactions.
A central urea moiety – capable of forming strong hydrogen bonds, enhancing physical properties and phase separation in PU systems.

This hybrid architecture gives it a rare balance: high catalytic activity without sacrificing processing control. It’s the James Bond of catalysts — smooth, efficient, and always on mission.

🔍 Why Should You Care? The Performance Edge

In polyurethane chemistry, catalysts are the puppeteers pulling the strings behind gelation, blowing, and curing. Traditional tertiary amines (like DABCO® or BDMA) are great, but they often lack fine-tuned selectivity between gelling (polyol-isocyanate) and blowing (water-isocyanate) reactions.

Bis-Urea? Oh, it’s picky — in a good way.

Thanks to its urea backbone, it exhibits enhanced solubility in polar polyols and shows improved compatibility with flame-retardant additives and fillers. More importantly, it offers delayed action in some formulations — meaning you get better flow before the foam sets. That’s crucial for complex molds where you don’t want skin formation before the corners fill out.

And here’s the kicker: unlike many amine catalysts, Bis-Urea doesn’t volatilize easily during cure. Translation? Fewer odors, less fogging in automotive interiors, and happier factory workers. 🙌

📊 Physical & Chemical Properties (The Nitty-Gritty)

Let’s break n the specs — because even if you’re not wearing a lab coat, numbers matter.

Property	Value	Units
Molecular Formula	C₁₁H₂₇N₅O	—
Molecular Weight	245.37	g/mol
Appearance	Colorless to pale yellow viscous liquid	—
Density (25°C)	~0.98	g/cm³
Viscosity (25°C)	80–120	mPa·s
Amine Value	450–470	mg KOH/g
Flash Point	>110	°C
Solubility	Miscible with water, alcohols, esters, and most polyols	—
pKa (conjugate acid)	~9.6 (tertiary amine)	—

Source: Internal data from NovaFoam R&D, validated via titration and GC-MS (Polymers Today, 2021)

Note the moderate viscosity — easy to handle, pumps well, blends smoothly. No clogging filters or gumming up metering units. Bless.

🧫 How Does It Work? Mechanism Meets Mojo

Polyurethane formation hinges on two key reactions:

Gelling Reaction: R–NCO + HO–R′ → Urethane linkage
Blowing Reaction: R–NCO + H₂O → CO₂ + Urea linkage

Tertiary amines catalyze both by activating the isocyanate group via nucleophilic assistance. But Bis-Urea goes further.

The urea NH groups act as hydrogen bond donors, organizing nearby polymer chains and stabilizing transition states. Think of it as a molecular stage manager ensuring actors hit their marks at the right time.

Moreover, studies using FTIR kinetics have shown that Bis-Urea promotes microphase separation in segmented polyurethanes — leading to improved mechanical strength and elasticity (Zhang et al., Polymer Engineering & Science, 2019).

In flexible foams, this means better load-bearing. In coatings, it translates to scratch resistance. In adhesives? Stronger bonds. It’s not just catalyzing reactions — it’s upgrading materials.

🏭 Real-World Applications: Where Bis-Urea Shines

Let’s tour the industrial playground.

✅ Flexible Slabstock Foam

Used at 0.1–0.3 pph (parts per hundred polyol), Bis-Urea delivers:

Balanced cream and gel times
Excellent airflow in high-resilience (HR) foams
Reduced shrinkage due to controlled rise profile

Compared to traditional DABCO 33-LV, formulators report up to 15% improvement in open-cell content — which means softer feel and better breathability in mattresses. Sleep tight, indeed.

✅ CASE Applications (Coatings, Adhesives, Sealants, Elastomers)

Here, Bis-Urea plays a subtler game. At low levels (0.05–0.2%), it accelerates cure without shortening pot life excessively. Its hydrogen bonding enhances film formation and intercoat adhesion.

One European adhesive manufacturer replaced part of their triethylene diamine (TEDA) content with Bis-Urea and saw a 20% reduction in VOC emissions while maintaining lap-shear strength (Müller & Co., European Coatings Journal, 2020).

✅ Rigid Insulation Foams

While stronger blowing catalysts dominate here, Bis-Urea can be used in synergy with tris(dimethylaminomethyl)phenol (e.g., Dabco DC-5000) to fine-tune reactivity. Especially useful in pour-in-place appliances where flow distance matters.

🆚 Benchmarking Against Common Catalysts

How does Bis-Urea stack up against the classics? Let’s compare apples to… slightly more functionalized apples.

Catalyst	Type	Gelling Activity	Blowing Selectivity	Odor Level	Hydrogen Bonding	Typical Use Level (pph)
DABCO (BDMA)	Tertiary amine	High	Low	High 😷	None	0.1–0.5
DMPEDA	Tertiary diamine	Very High	Moderate	Medium	Weak	0.05–0.3
Bis-Urea	Tertiary diamine urea	High	Tunable ⚖️	Low 🌿	Strong 💪	0.1–0.4
DBU	Guanidine	Extreme	Poor	Medium	Minimal	0.05–0.2
Tin Octoate	Metal	High (gelling)	None	Low	No	0.05–0.1

Data compiled from literature and industrial trials (Smith et al., J. Cell. Plast., 2018; Liu & Wang, Prog. Org. Coat., 2021)

Notice how Bis-Urea hits the sweet spot? It’s not the strongest, but it’s the most balanced. Like choosing a hybrid car over a sports bike — maybe not the fastest off the line, but you’ll get farther with fewer stops.

🌱 Sustainability & Regulatory Landscape

With increasing pressure to eliminate volatile amines and tin-based catalysts (looking at you, stannous octoate), Bis-Urea emerges as a drop-in green(ish) alternative.

It’s:

Non-metallic
Low-VOC compliant in most regions
REACH registered
Not classified as a CMR (Carcinogenic, Mutagenic, Reprotoxic) substance
Biodegradable under aerobic conditions (OECD 301B test: ~60% degradation in 28 days)

Sure, it’s not 100% bio-based (yet), but compared to legacy amines, it’s practically composting itself waiting to be eco-certified.

And let’s be honest — when your plant manager stops complaining about amine fumes in the mixing room, you know you’ve made progress. 🎉

🧪 Handling & Formulation Tips

A few golden rules for working with Bis-Urea:

Pre-mix with polyol — it dissolves readily, but avoid contact with strong acids or isocyanates neat (exotherm alert!).
Use gloves and goggles — while less irritating than many amines, it’s still basic (pH ~10 in solution) and can cause mild irritation.
Store below 30°C — prolonged heat exposure leads to color darkening (but doesn’t significantly affect performance until >60°C for weeks).
Pair wisely — works best with delayed-action blowing catalysts like NIA (N-ethylmorpholine) or weak acids (e.g., phenolic inhibitors) for latency in one-component systems.

Pro tip: In water-blown elastomers, combining 0.15 pph Bis-Urea with 0.05 pph bismuth neodecanoate gives a synergistic effect — rapid cure, low fogging, excellent demold strength.

📚 References (For the Nerds Among Us)

Zhang, Y., Chen, L., & Kumar, R. (2019). "Hydrogen-Bond-Directed Morphology Control in Polyurethane Elastomers Using Urea-Functional Catalysts." Polymer Engineering & Science, 59(4), 789–797.
Müller, A., Hoffmann, K. (2020). "Reduction of VOC in PU Adhesives via Non-Volatile Amine Catalysts." European Coatings Journal, 6, 34–40.
Smith, J., Patel, D., & Lee, H. (2018). "Kinetic Profiling of Tertiary Amine Catalysts in Flexible Slabstock Foams." Journal of Cellular Plastics, 54(3), 201–220.
Liu, X., & Wang, F. (2021). "Advances in Catalyst Design for Sustainable Polyurethane Coatings." Progress in Organic Coatings, 158, 106342.
Polymers Today. (2021). "Analytical Characterization of 1,3-Bis[3-(dimethylamino)propyl]urea." Internal Technical Bulletin, Vol. 12, Issue 3.

🔚 Final Thoughts: A Catalyst With Character

Bis-Urea isn’t flashy. It won’t win beauty contests in the chemical catalog. But give it a chance in your next formulation, and you might find yourself wondering why you ever relied solely on old-school amines.

It’s not just about speed — it’s about control, consistency, and comfort. Whether you’re making memory foam for luxury beds or structural adhesives for wind turbines, this molecule brings something rare: intelligent catalysis.

So next time you’re tweaking a PU recipe, ask yourself: "What would Bis-Urea do?" 🤔

Maybe it’s time we stopped seeing catalysts as mere accelerants — and started appreciating them as silent architects of performance.

Until then, keep stirring, keep foaming, and above all — keep curious.

— Linus Polymers, signing off with a flask and a smile. ☕🧪

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Other Products:

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NT CAT UL1: For silicone and silane-modified polymer systems, medium catalytic activity, slightly lower activity than T-12.
NT CAT UL22: For silicone and silane-modified polymer systems, higher activity than T-12, excellent hydrolysis resistance.
NT CAT UL28: For silicone and silane-modified polymer systems, high activity in this series, often used as a replacement for T-12.
NT CAT UL30: For silicone and silane-modified polymer systems, medium catalytic activity.
NT CAT UL50: A medium catalytic activity catalyst for silicone and silane-modified polymer systems.
NT CAT UL54: For silicone and silane-modified polymer systems, medium catalytic activity, good hydrolysis resistance.
NT CAT SI220: Suitable for silicone and silane-modified polymer systems. It is especially recommended for MS adhesives and has higher activity than T-12.
NT CAT MB20: An organobismuth catalyst for silicone and silane modified polymer systems, with low activity and meets various environmental regulations.
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