1. Hōʻikeʻike
PoneThayynene (PE) is a polymer produced by polymerisation of the monomer ethylene (CH₂=CH₂).
First commercialised in the 1930s, PE is now available in multiple engineered forms whose properties are defined by molecular weight, chain architecture (branching), and processing (including crosslinking).
PE’s combination of chemical inertness, Kālā, low cost and a spectrum of mechanical behaviors—from flexible films to ultra-tough solids—explains its ubiquity across packaging, kūkulu hoʻi, halihali, consumer, medical and industrial sectors.
2. What Is Polyethylene (PE)?
PoneThayynene (PE) is a family of semi-crystalline thermoplastics produced by polymerizing ethylene (CH₂=CH₂).
It is the world’s most widely used plastic because of its combination of low cost, 'Oiʻai lāʻau, wide processing window and a tunable range of mechanical behaviours — from soft, flexible films to very tough, wear-resistant solids.
Nā mea nui
- Kūleʻa kimemika: excellent to most acids, Alkaliis, solvents and fuels.
- Puiahuhu: wide range — LDPE is soft and extensible; HDPE is stiff and strong; UHMWPE combines high strength with exceptional impact toughness.
- Thermal: melting points typically ~105–135 °C depending on grade; service temperatures are generally limited compared with engineering plastics.
- Moisture: essentially non-hygroscopic (negligible water uptake).
- ʻAʻa & kuiahuli: UHMWPE has outstanding low friction and abrasion resistance.
3. Commercial PE grades and what makes them different
PE is typically categorised as follows:
- LDPE (Low-Density Polyethylene): density ~0.910–0.925 g/cm³; hikiwawe, good clarity (nā kiʻiʻoniʻoni), low tensile strength. Common for squeeze bottles, nā kiʻiʻoniʻoni, cable jackets.
- LLDPE (Linear Low-Density Polyethylene): density similar to LDPE; superior tensile strength and puncture resistance in films due to short-chain branching. Widely used for stretch film and co-extruded structures.
- MDPE (Medium-Density PE): density ~0.926–0.940 g/cm³; used for gas pipes and some blow moulding.
- HDPE (High-Density Polyethylene): density ~0.940–0.970 g/cm³; stiff, good chemical resistance, used for pipe, nā popala, rotomoulding parts.
- Uhmwpe (Ultra-High-Molecular-Weight PE): Mw typically >3×10⁶ g/mol; outstanding abrasion resistance, very low friction; used for liners, Kāhele, sliding applications and some medical implants.
- XLPE (Cross-linked PE): PE chemically or radiation crosslinked to improve temperature, creep and chemical resistance; used for high-temperature piping and cable insulation.
- Metallocene-catalysed PE (mPE / mLLDPE): tighter molecular weight distribution and improved mechanical property control — enables high clarity films and tailored mechanical behaviour.
Each grade is optimised for processability and application performance by adjusting Mw, comonomer content and catalysts.
4. Typical physical and mechanical properties
The table below gives representative, typical ranges for common PE grades. Use manufacturer datasheets for design-critical values.
| Waiwai | LDPE | LLDPE | MDPE | HDPE | Uhmwpe |
| Huakai (g · cad) | 0.910–0.925 | 0.915–0.930 | 0.926–0.940 | 0.940–0.970 | 0.930–0.940 |
| Ikaika ikaika (Mpa) | 8-15 | 12-20 | 14-25 | 20–37 | 30-45 |
| Elongation at break (%) | 200-800 | 200-600 | 200-400 | 100-600 | 100-400 |
| Modulus'ōpiopio (GPA) | 0.2-0.4 | 0.3-0.6 | 0.6-0.9 | 0.8-1.5 | 0.8-1.5 |
| Malting Point (° C) | 105–115 | 105-120 | 120–130 | 125–135 | 130–138 |
| Notched Izod (kJ·m⁻²) | 30-100 (paʻakikī) | 30-100 | 20-60 | 10-40 | 50-200 (very tough) |
| E kāʻei i ke kū'ē | Hoʻohaʻahaʻa | Loli | Loli | Maikaʻi loa | Kūpono |
| Continuous service temp (° C) | ~65–80 | ~65–80 | ~80–90 | ~80–110 | ~80–120 |
| Kūleʻa kimemika | Kūpono | Kūpono | Kūpono | Kūpono | Kūpono |
| Water absorption | Hōʻoleʻole | Hōʻoleʻole | Hōʻoleʻole | Hōʻoleʻole | Hōʻoleʻole |
5. Processing methods and manufacturing considerations
PE is processed by almost every thermoplastic technique:
- Hānehi — pipes, Nā'āpana, Pipai Pūnaewele, Nā Mānā. HDPE and UHMW in pipes and liners are extruded or ram-extruded.
- Blow-molding — bottles and containers (HDPE, LDPE).
- ʻO nā molding molding — fittings, housings and components (HDPE, LDPE variants).
- Rotational (rotomoulding) — large hollow parts (Nā'Ka, KAHOA).
- Film casting / blown film — packaging films (LDPE, LLDPE, mLLDPE).
- Compression sintering / ram extrusion / ke kāohiʻana — UHMWPE often processed this way because of extremely high Mw (no conventional melt flow).
- Crosslinking methods — chemical (peroxides), silane grafting or electron-beam / gamma radiation to produce XLPE for higher temperature or improved creep resistance.
6. Key applications by grade
- LDPE / LLDPE: flexible film, shopping bags, liners, film packaging, cable sheathing, agricultural films.
- HDPE: water and gas distribution piping, blow-moulded containers (milk bottles), geomembranes, rotomoulded tanks, Nā Kūlana Kūlana.
- MDPE: gas distribution pipe, geomembranes.
- Uhmwpe: wear strips, chutes and liners, sliding bearings, chain guides, orthopaedic implants (hip a me nā mea hoʻohālike o ke kuli), ballistic fibres (UHMWPE fibres like Dyneema® / Spectra®).
- XLPE: high-temperature pipe applications (hot water/industrial), cable insulation.
7. Performance challenges and failure modes
Although chemically robust, PE has several known failure mechanisms to design against:
Environmental stress cracking (ESC)
- ʻO wehewehe: crack formation and propagation under stress in the presence of specific chemicals or surfactants.
PE’s most critical failure mode — stress levels below yield can cause cracking over time in contact with detergents, glycol, or some hydrocarbons. - Miomi: choose ESC-resistant formulations, reduce residual/trapping stress (improve processing and anneal), avoid sharp notches and reduce sustained tensile stresses.
Creep and long-term deformation
- PE exhibits significant creep under sustained load, especially at elevated temperature.
Design for creep with safety factors; use HDPE, XLPE or select UHMW for reduced creep where needed.
Uv / oxidative degradation
- Unstabilised PE degrades under UV and oxygen: surface chalking, embrittlement and loss of mechanical properties.
Stabilisation with UV absorbers, carbon black pigmentation and antioxidants is routine for outdoor applications.
Low stiffness at high temperature and dimensional limits
- PE’s modulus falls with temperature; for structural applications approaching service temperature limits select materials with higher stiffness or crosslinking to raise heat deflection.
Fusion / welding considerations (for piping)
- HDPE piping is typically joined by butt fusion or electrofusion; poor welding leads to weak joints and premature failure — welding procedures and operator qualification are critical.
8. Kaiualoa, recycling and sustainability aspects
- Recyclabiality: PE is highly recyclable (mechanical recycling); HDPE and LDPE are commonly reprocessed into packaging and non-critical products. PE is assigned recycling codes: #2 (HDPE) and #4 (LDPE).
- PAHUI: paio, mixed polymers and additives complicate recycling streams. UHMWPE and filled grades are more difficult to reprocess into high-value products.
- Biobased options: ethylene can be produced from bioethanol (bio-PE) with identical properties to fossil-based PE.
- Pau-o-ola: incineration with energy recovery and chemical recycling (depolymerisation) are technical options; lifecycle analysis depends on application and recovery rates.
- Environmental concerns: microplastics generation from films and wear particles (E.g., from conveyor liners) requires consideration.
9. Comparative Analysis — PoneThayynene (PE) vsa. other common materials
ʻO ka papaʻaina ma lalo nei PE with several materials engineers commonly consider as alternatives for parts, nā kiʻiʻoniʻoni, pipes or wear components.
| Waiwai / Loko | PE (LDPE / HDPE) | PP (PolyProylene) | PVC (Rigid) | POM / Puana aloa | Nylon (Pa6 / PA66) |
| Huakai (g · cad) | 0.91–0.97 | 0.90–0.91 | 1.34–1.45 | ≈ 1.41 | 1.12-1.15 |
| Ikaika ikaika (Mpa) | 8–37 (LD→HD) | 30-40 | 35-60 | 50-75 | 50-90 |
| Modulus'ōpiopio (GPA) | 0.2-1.5 | 1.0-1.8 | 2.7-3.5 | 2.8-3.5 | 2.5-3.5 |
| Hoʻomālamalama / usable temp (° C) | Tm ~105–135 / use ≈ 65–110 | Tm ~160–170 / use ≈ 90–120 | Tg/softening ~75–80 / use ≈ 40–60 | Tm ~165–175 / use ≈ 80–100 | Tm ~215–265 / use ≈ 80–120 |
| Kūleʻa kimemika | Kūpono (Nā'āpana, Nā Hale Kiʻi, many solvents) | Maikaʻi loa (similar to PE) | Maikaʻi loa (Nā'āpana, aloha, many chemicals) | Maikaʻi loa (hūke, na ailai wai) | Maikaʻi loa (hydrocarbonord, na ailai wai) |
| Hoʻokomoʻia ka wai | Hōʻoleʻole | Hōʻoleʻole | Hōʻoleʻole | ~ 0.2-0.3% | 1-3% (hygroscopic) |
ʻAʻa / friction behavior |
Maikaʻi loa (HDPE better than LDPE) | Loli | Loli | Kūpono (haʻahaʻa haʻahaʻa haʻahaʻa, low wear) | Maikaʻi loa |
| Paʻa paʻa | Loli (creep under load) | Loli | Maikaʻi loa | Kūpono | Loli (affected by moisture) |
| Ke kū'ē kū'ē (unstabilized) | Ilihune (needs stabilizers) | Ilihune | ʻAi maikaʻiʻia (formulation dependent) | Ilihune | Ilihune |
| Processability | Kūpono (hānehi, blow, injection, rotomolding) | Kūpono | Maikaʻi loa (but narrow processing window) | Maikaʻi loa (injection, machining) | Maikaʻi loa (requires drying before molding) |
| Recyclabiality | Maikaʻi loa (HDPE/LDPE widely recycled) | Maikaʻi loa | Paʻa (chlorine content) | Paʻa | Loli |
| Nā noi maʻamau | Films, bottles, pipes, Nā'Ka, liners | Trim trim, hiuntes, nā popala | Pipes, window profiles, KahawaiOli | Nāʻuala maikaʻi, Bussings, Nā Vilves | Kauluhi, Kāhele, urowing, 'ahuʻu |
10. Nā hopena
Polyethylene is a versatile thermoplastic family whose different grades cover a very wide span of mechanical and processing behaviours.
PE’s strengths are chemical resistance, Kālā, low cost and a capability range from flexible films to ultra-tough sliding parts.
The most common engineering pitfalls are environmental stress cracking, creep and UV degradation — each addressable through grade selection, stabilisation and design.
For most industrial designers, PE remains an economical and robust choice when its limitations are understood and managed through specification and testing.
FaqS
What is the difference between LDPE and HDPE?
LDPE has more chain branching, lower crystallinity and lower density (≈0.91–0.925 g/cm³) → softer, more flexible films.
HDPE has little branching, higher crystallinity (≈0.94–0.97 g/cm³) → stiffer, stronger parts and pipe.
Why does PE crack under mild chemicals sometimes?
That is environmental stress cracking (ESC): certain surfactants and detergents promote slow crack growth under tensile stress. Selecting ESC-resistant grades and reducing stress concentrations mitigates the risk.
Can PE be used for pressure piping?
Yes — HDPE and MDPE are widely used for potable water and gas distribution. Proper fusion welding and qualified materials/processes are essential.
When should I choose UHMWPE?
Choose UHMWPE when very high abrasion resistance, low friction and impact toughness are required (conveyor liners, lole lole, sliding bearings, certain medical implants).
Is polyethylene recyclable?
ʻAe: HDPE and LDPE are among the most recycled plastics, but contamination and mixed polymers influence recycling quality.
Mechanical recycling and emerging chemical recycling routes are both used.
