Photooxidative ageing of 3D printed polymers PLA, ABS, PET, HIPS and PC induced by long-term UV radiation
Pith reviewed 2026-06-30 17:08 UTC · model grok-4.3
The pith
UV exposure over 10 months leaves PLA and PC 3D prints mechanically intact while embrittling ABS and HIPS, with PETG changes confined to the top 10 micrometers.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
After 7744 consecutive hours of UV radiation, PLA and PC exhibit the highest resistance with no significant shifts in mechanical properties; ABS and HIPS display clear changes even at greater depths that produce embrittlement in ABS; PETG shows mechanical alterations only to depths below 10 micrometers. Raman scattering and infrared absorption confirm the absence of structural change in PLA while revealing differences in characteristic and deformation vibrations for ABS and PETG.
What carries the argument
Nanoindentation to obtain hardness and modulus of elasticity depth profiles on FFF-printed samples, supplemented by Raman scattering and infrared absorption spectroscopy for structural insight.
If this is right
- PLA and PC retain hardness and elastic modulus after long UV exposure and can be selected for sun-exposed 3D-printed parts.
- ABS undergoes embrittlement from property changes that extend past the surface layer.
- HIPS shows mechanical degradation at greater depths under the same conditions.
- PETG mechanical changes remain limited to depths under 10 micrometers.
- Vibrational spectra detect the structural basis for the observed mechanical shifts in ABS and PETG.
Where Pith is reading between the lines
- Material selection for outdoor 3D prints could start with PLA or PC to reduce replacement frequency.
- The shallow depth of PETG damage suggests surface coatings might protect other polymers in similar settings.
- Tests that combine UV with mechanical stress during exposure could change the observed ranking of the five materials.
- Single-factor UV data like these can serve as a baseline before full outdoor weathering trials are run.
- keywords:[
Load-bearing premise
Nanoindentation measurements on the printed surfaces isolate UV-induced mechanical changes without interference from printing layers, surface roughness, or the controlled cell conditions.
What would settle it
No difference in hardness or modulus between exposed and unexposed PLA or PC samples after 7744 hours, or mechanical changes detected below 10 micrometers in PETG, would contradict the reported resistance ordering.
read the original abstract
This article focuses on the influence of long-term UV radiation exposure on mechanical and structural properties of selected polymeric materials (PLA, ABS, PC, PETG, HIPS) prepared using 3D-print based Fused Filament Fabrication (FFF) method. Existing research in the field of polymers weathering has been focused more on the combined effects so far, moreover on time scales not exceeding units of months. However, it is important to separate individual effects to understand the dynamics of material changes and design strategies to improve material resistance. Our research thus focuses on UV-affected ageing of the selected polymers for time duration exceeding 10 months (7744 consecutive hours, i.e. 322 days), performed in an environmental cell with controlled humidity and temperature. Mechanical properties were evaluated by a locally sensitive nanoindentation method. Surface properties, depth property profiles, and creep were studied as well. Hardness and modulus of elasticity data were obtained for a wide range of samples. Based on our analysis of mechanical properties, the highest UV resistances are characteristic for PLA and PC. On the contrary, noticeable changes of mechanical properties occur in the ABS and HIPS samples (even at greater depths), leading to an embrittlement of the former material. Changes in mechanical properties even in strongly affected samples (PETG) were only evident to depths <10 um. For the selected samples (PLA, ABS, PETG), vibrational spectroscopies (Raman scattering and infrared absorption) were exploited to gain a deeper insight into polymers structural changes. Vibrational spectra supported the results of mechanical properties tests: while PLA revealed no significant changes from the structural viewpoint; ABS and PETG showed differences in characteristic as well as deformation vibrations.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The manuscript examines the photooxidative ageing of FFF 3D-printed polymers (PLA, ABS, PETG, HIPS, PC) under long-term UV exposure (7744 hours / 322 days) in a controlled environmental cell. Nanoindentation is used to quantify changes in hardness, elastic modulus, surface properties, depth profiles, and creep; vibrational spectroscopy (Raman, IR) is applied to a subset (PLA, ABS, PETG) to assess structural changes. The central claim is that PLA and PC show the highest UV resistance, ABS and HIPS exhibit noticeable mechanical changes even at greater depths (with embrittlement in ABS), and PETG changes are confined to depths <10 μm, with spectroscopy supporting limited structural alteration in PLA versus changes in ABS and PETG.
Significance. If the nanoindentation data reliably isolate UV-induced effects, the work supplies valuable long-duration experimental data on UV resistance of additively manufactured polymers under controlled humidity and temperature. The extended timescale (exceeding typical studies) and dual mechanical-spectroscopic approach are strengths that could guide material selection for outdoor 3D-printed components. The paper also ships direct experimental reporting without fitted models or free parameters.
major comments (1)
- [Nanoindentation / mechanical properties results] Nanoindentation section / depth-profile results: The ranking of UV resistance (PLA/PC highest; ABS/HIPS embrittlement at depth; PETG <10 μm) rests on hardness and modulus measurements performed on as-printed surfaces. The manuscript does not report cross-section preparation, polishing, or statistical mapping to decouple UV photooxidation from FFF-induced spatial heterogeneity (layer interfaces, raster orientation, surface topography). Without such controls, the observed depth-limited changes and embrittlement conclusions risk confounding with pre-existing printing artifacts, undermining the attribution to UV alone.
minor comments (2)
- [Title] Title lists PET while abstract and text consistently refer to PETG; this nomenclature inconsistency should be corrected for clarity.
- [Abstract / Results] The abstract states that hardness and modulus data were obtained but does not mention reported sample sizes, number of indents per condition, or error bars; these details should be added to the results section for reproducibility.
Simulated Author's Rebuttal
We thank the referee for their constructive comments and the opportunity to clarify our methodology. We respond to the single major comment below.
read point-by-point responses
-
Referee: [Nanoindentation / mechanical properties results] Nanoindentation section / depth-profile results: The ranking of UV resistance (PLA/PC highest; ABS/HIPS embrittlement at depth; PETG <10 μm) rests on hardness and modulus measurements performed on as-printed surfaces. The manuscript does not report cross-section preparation, polishing, or statistical mapping to decouple UV photooxidation from FFF-induced spatial heterogeneity (layer interfaces, raster orientation, surface topography). Without such controls, the observed depth-limited changes and embrittlement conclusions risk confounding with pre-existing printing artifacts, undermining the attribution to UV alone.
Authors: We thank the referee for raising this methodological point. Nanoindentation was performed directly on the UV-exposed as-printed surfaces, with depth profiles generated by varying maximum load to probe different penetration depths from the surface. Multiple indents were acquired per sample at different surface locations to provide averaging over local topography and raster variations, although the manuscript text does not explicitly quantify the number of measurements or their spatial distribution. The reported depth dependence—changes confined to <10 μm in PETG while extending deeper in ABS and HIPS—matches the expected UV attenuation lengths in these polymers and is inconsistent with bulk printing artifacts, which would appear uniformly across the sample thickness. All specimens were printed under identical conditions from the same filament batches. We nevertheless agree that explicit cross-sectional polishing and mapping would strengthen the separation of surface-specific UV effects from printing heterogeneity. We will therefore revise the manuscript to (i) detail the indentation statistics and locations, (ii) add a dedicated paragraph discussing potential printing artifacts and why the observed depth profiles support UV attribution, and (iii) note the absence of cross-section data as a limitation while outlining how future work could address it. revision: partial
Circularity Check
No circularity: purely experimental reporting of measured properties
full rationale
The paper reports direct experimental measurements (nanoindentation hardness/modulus depth profiles, creep, Raman/IR spectra) on UV-exposed FFF samples over 7744 hours. No equations, models, fitted parameters, or derivations appear in the provided text. The central ranking of UV resistance (PLA/PC highest; ABS/HIPS embrittlement; PETG <10 µm) is an interpretation of raw data, not a reduction to any input by construction or self-citation. No load-bearing steps match any enumerated circularity pattern.
Axiom & Free-Parameter Ledger
Reference graph
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