Anionic Polymerization Calculator: Mₙ & DP Tool

Anionic Polymerization Calculator

Living Polymerization: Mₙ, DP, PDI

Enter monomer, initiator, and conversion to compute molecular weight and chain length.

Monomer MW (g/mol)

Initiator [I]₀ (mol)

Monomer [M]₀ (mol)

Conversion (%)

Polymer Chain

Polymer Properties

Number Average MW (Mₙ) = — g/mol

Degree of Polymerization (DPₙ) = —

Polydispersity Index (PDI) = 1.00

Chain Length = — units

The Anionic Polymerization Calculator is a scientifically precise, interactive tool that computes **number average molecular weight (Mₙ)**, **degree of polymerization (DPₙ)**, **polydispersity index (PDI)**, and **chain length** in **living anionic polymerization**. Based on **Szwarc’s living polymer theory** and **Flory’s equal reactivity principle**, it assumes **no termination or transfer** (PDI → 1.0). Ideal for synthesizing **block copolymers**, **biodegradable plastics**, and **precision nanomaterials**. Achieve lab-grade polymer design instantly. Explore sustainable polymers at Agri Care Hub.

What is Anionic Polymerization?

**Anionic polymerization** is a chain-growth mechanism using carbanions (R⁻) as active centers. Discovered by **Michael Szwarc (1956)**, it enables **living polymers** with:

No termination
Controlled MW
Narrow PDI (~1.0–1.1)
Block copolymer synthesis

Learn more on Anionic Polymerization ScienceDirect.

Scientific Foundation: Living Kinetics

Degree of polymerization:

DP_n = \frac{[M]_0 \times p}{[I]_0}

Molecular weight:

M_n = DP_n \times M_{monomer}

PDI = 1.0 (ideal living system)

Importance of Anionic Polymerization

Enables:

Polystyrene (PS): Packaging
Polybutadiene (PB): Tires
SBS Block Copolymers: Adhesives
PLA/PGA: Bioplastics
Nanoparticles: Drug delivery

In agriculture, **biodegradable mulch films** reduce plastic waste — a focus at Agri Care Hub.

User Guidelines

Steps:

Enter monomer MW (e.g., styrene = 104.15)
Enter initial moles of monomer and initiator
Set conversion %
Click “Calculate Anionic Polymerization”

Use n-BuLi, sec-BuLi, or Grignard as initiator

When and Why to Use

Use when you need to:

Design 10 kDa PS standard
Synthesize ABA triblock for mulch film
Predict PDI in lab reactor
Teach polymer kinetics
Scale up biodegradable packaging

Purpose of the Calculator

To make polymer design **predictable and reproducible**. It eliminates trial-and-error in **living systems** and supports **green chemistry**.

Example: Styrene with n-BuLi

Monomer: 104.15 g/mol, 1.0 mol
Initiator: 0.001 mol
Conversion: 100%
Mₙ = 104,150 g/mol, DPₙ = 1,000

Applications in Agriculture

Anionic methods enable:

Biodegradable mulch films
Controlled-release fertilizers
Smart hydrogels for irrigation
Seed coatings

Learn more at Agri Care Hub.

Scientific Validation

Based on:

Szwarc (1956) “Living Polymers”
Flory (1953) Principles of Polymer Chemistry
Hadjiandreou & Jasse (1983)
Peer-reviewed studies on Anionic Polymerization

Benefits

100% accurate
PDI = 1.0
Mobile-friendly
No login
SEO-optimized

Conclusion

The Anionic Polymerization Calculator is your essential tool for precision polymer science. From lab synthesis to sustainable agriculture, it delivers **living control** and **green innovation**. Start designing tomorrow’s materials today with Agri Care Hub.

At Agri Care Hub, we’re dedicated to helping you cultivate vibrant gardens and farms. With our expert tips and passion for sustainable practices, we provide the guidance you need to keep your plants and crops healthy and thriving, enhancing the beauty and productivity of your green spaces.