Vol.:(0123456789)

Clean Technologies and Environmental Policy (2024) 26:3297–3312 
https://doi.org/10.1007/s10098-024-02884-1

ORIGINAL PAPER

A cradle‑to‑gate life cycle assessment of polyamide‑starch 
biocomposites: carbon footprint as an indicator of sustainability

Laura Äkräs1 · Frans Silvenius2 · Hossein Baniasadi1 · Marjatta Vahvaselkä3 · Hannu Ilvesniemi3 · Jukka Seppälä1

Received: 29 November 2023 / Accepted: 6 May 2024 / Published online: 29 May 2024 
© The Author(s) 2024

Abstract
Accelerating climate change poses an alarming global issue, demanding a range of prompt and effective solutions. In 
response, bio-based plastics and biocomposites have emerged as extensively researched alternatives to combat the environ-
mental threats posed by a warming climate. In this context, the present paper presents a cradle-to-gate life cycle assessment 
of a newly developed polyamide-starch biocomposite, with varying content of potato starch as the biofiller (ranging from 
0 to 70 wt%). The primary aim was to quantitatively measure the total carbon footprint of the selected biocomposite. The 
results indicated that the progressive addition of potato starch as the biofiller into the copolyamide matrix significantly 
reduced the total carbon footprint of the biocomposite, achieving a maximum reduction of 42–43% with the highest starch 
content of 70 wt%. Moreover, the newly developed polyamide-starch biocomposite demonstrated excellent performance 
compared to reference fossil-based polyamides of polyamide 6 (PA6), polyamide 12 (PA12), and polyamide 6.6 (PA6.6), as 
well as composites of PA610/80 wt% polylactic acid modified by reactive extrusion (REX-PLA) and PA40/30 wt% glass fib-
ers, with carbon footprint reductions of 29, 39, 42, 59, and 79%, respectively. Based on these findings, the polyamide-starch 
biocomposite, especially with the highest content of potato starch (70 wt%), exhibits significant potential as a new material 
solution to reduce the carbon footprint of several existing fossil- and bio-based polyamides together with polyamide-based 
composites. In doing so, it contributes to advancing the development of a more climate-friendly future for plastics through 
reductions in their carbon footprints.

Graphical abstract

A concise illustration, showcasing the main content of the present paper; a cradle-to-gate life cycle assessment of the newly developed polyam-
ide-starch biocomposites, which results indicated substantial reductions in the carbon footprint of these biocomposites

Keywords  Copolyamide · Starch · Biocomposite · Life cycle assessment (LCA) · Cradle-to-gate approach · Carbon 
footprint

Extended author information available on the last page of the article

http://crossmark.crossref.org/dialog/?doi=10.1007/s10098-024-02884-1&domain=pdf


3298	 L. Äkräs et al.

Introduction

The current world encounters several environmental 
threats, such as the depletion of fossil resources, typi-
cally used as an energy source for different purposes or 
as building blocks for various plastic products, a chal-
lenge of accumulated waste in nature due to inadequate 
disposal practices and non-biodegradable nature of some 
of the commercial plastic products, as well as, above all, 
accelerating climate change with multiple innocuous 
consequences on the ecosystems and human health. The 
ways to slow down the development of these challenges 
include the utilization of several different steps on a com-
plementary basis through, for instance, more excessive 
use of bio-based feedstocks both for energy generation 
and for manufacture of plastic products (Yang et al. 2021; 
Zheng and Suh 2019), along with the development of new, 
sustainable, bio-based plastic products with comparable 
techno-economic properties with their fossil-based coun-
terparts (Bishop et al. 2021; van den Oever and Molenveld 
2017). These are accompanied with the substitution of fos-
sil-based plastic products with their bio-based alternatives 
(Zheng and Suh 2019) and, when applicable, increased 
recycling rates of plastic products (Zheng and Suh 2019), 
together with appropriate and effective legislation to guide 
these suggested actions. In addition to the acts mentioned 
above, quantifying, evaluating, and understanding the 
environmental impacts and hotspots caused by the manu-
factured bio- and fossil-based plastic products is becom-
ing more and more widely recognized, appreciated, and 
required as an aid in sustainable decision-making in mul-
tiple different arenas. In this context, for the quantification 
and evaluation of the environmental impacts, LCA with 
carbon footprint as the most researched impact category 
is a well-established technique widely in use (Banerjee 
and Ray 2022).

Against this background, from the material perspec-
tive, blending biofillers with different plastic matrices has 
been realized to enable a high bio-based content (Mohanty 
et al. 2018), frequently improving some of the properties 
of the individual plastics, such as their tensile strength 
(Shanmugam et al. 2021; Sadasivuni et al. 2020), impact 
strength (Sadasivuni et al. 2020), tensile modulus (Shan-
mugam et al. 2021), and stiffness (Mohanty et al. 2018), 
with simultaneous enhancements in the overall biodeg-
radability of the resulted (bio)composites per se (Shan-
mugam et al. 2021). On the other hand, from the environ-
mental point of view, bio-based plastics have been reported 
to often possess a lower carbon footprint in comparison 
with their fossil-based alternatives (Yang et  al. 2021; 
Zheng and Suh 2019; Broeren et al. 2017); (bio)compos-
ites have similarly been found to have generally decreased 

environmental footprints than fossil-based plastics (Shan-
mugam et al. 2021); and the addition of functional (bio)
fillers in plastics have also been shown to reduce the car-
bon footprint of these plastics when compared to their 
plain counterparts (Civancik-Uslu et al. 2018). In addi-
tion to these findings, the inclusion of biofillers into the 
bio-based plastic matrices can decrease their production 
costs (Shanmugam et al. 2021), therefore making them 
more cost-efficient. Hence, (bio)composites undoubtedly 
possess some proven potential to improve the performance 
of individual plastics in multiple different ways.

Stemming from this, recently, fabrication methods for dif-
ferent types of (bio)composites have been researched and 
analyzed in the literature (Sadasivuni et al. 2020; Andrew 
and Dhakal 2022; Kostag and El Seoud 2021; Baniasadi 
et al. 2021), among which polyamide-based (bio)compos-
ites have shown promising results, mostly regarding their 
enhanced mechanical properties (Baniasadi et al. 2023a, 
b; Oliver-Ortega et al. 2016) but also improved viscoelas-
tic performances and water vapor transmission (Baniasadi 
et al. 2021), when compared to the plain polyamide matrices 
(Baniasadi et al. 2021; Baniasadi et al. 2023a, b; Oliver-
Ortega et al. 2016). Despite this, according to the literature 
survey conducted by the authors for the purposes of this 
paper, the number of LCA studies regarding (bio)composites 
with polyamides as one of the constituents seems scarce. In 
this respect, only a few studies regarding the matter were 
able to be found, namely the comparison of PA11/stone 
ground wood biocomposite with the composite of polypro-
pylene (PP)/carbon fibers with cradle-to-grave approach 
(Oliver-Ortega et al. 2019), analysis of the commercial 
composites of PA610/glass fibers and PA410/glass fibers (in 
more detail, RTP 2099 X 115387 B and DSM EcoPaXXTM 
Q-KGS6, respectively) from cradle to gate (Petersson et al. 
2013), together with the cradle-to-gate LCA of the com-
posites of REX-PLA/acrylonitrile butadiene styrene (ABS), 
REX-PLA/PA610, and REX-PLA/PA1010 (Torrell Gines 
2016).

In this discourse, up to date, no LCA studies specifi-
cally about polyamide-starch biocomposites were able to 
be detected by the authors, while studies focusing on other 
types of (bio)composites with starch as a matrix or biofiller 
were more readily available. As an example, a cradle-to-
factory gate LCA about six starch plastics was conducted, 
consisting of the selected bio- or fossil-based polymers of 
polybutyrate adipate-co-terephthalate (PBAT), PLA, post-
industrial recyclate PLA (re-PLA), polybutylene succinate 
(PBS), and polyhydroxybutyrate (PHB), virgin or reclaimed 
starch and/or natural fibers as the biofillers, combined with 
various additives (Broeren et al. 2017). On the other hand, 
two biocomposites from cradle to gate were also studied, 
and these biocomposites consisted of either PLA or PLA and 
thermoplastic starch (TPS) as the matrix and wood fibers 



3299A cradle‑to‑gate life cycle assessment of polyamide‑starch biocomposites: carbon footprint…

as the biofillers (Mahalle et al. 2014). Similarly, the envi-
ronmental impacts of boxes made of fossil-derived polysty-
rene (PS), corn-derived PLA, and PLA-cassava starch bio-
composite were researched from cradle to consumer gate 
(Suwanmanee et al. 2013), while elsewhere a cradle-to-grave 
LCA about wheat-polyvinyl alcohol (PVOH), potato starch-
PVOH, and maize starch-PVOH, also including minor addi-
tives, was performed (Guo and Murphy 2012). In general, 
many of these reviewed studies pointed out that the increase 
in the bio-based content of the (bio)composites, in the form 
of a matrix or biofiller, can reduce some of the environ-
mental impacts caused by these (bio)composites, such as 
carbon footprint, non-renewable energy use (NREU), and 
ozone depletion potential (ODP) (Broeren et al. 2017; Oli-
ver-Ortega et al. 2019; Torrell Gines 2016; Mahalle et al. 
2014; Guo and Murphy 2012), in comparison with a neat 
polymer or fossil-based alternatives. Despite this, the reduc-
tion in these specific categories tends to occur with a simul-
taneous increase in the agricultural-related impacts, such as 
eutrophication, land use, as well as freshwater and terrestrial 
ecotoxicity (Broeren et al. 2017; Mahalle et al. 2014; Guo 
and Murphy 2012). This reported reduction in the carbon 
footprint, nonetheless, may require more emission-intensive 
manufacture of the monomers for the polymerization of the 
selected plastics when compared to the cultivation and pro-
cessing of the most often locally produced biofillers (Oli-
ver-Ortega et al. 2019; Mahalle et al. 2014), such as starch. 
Additionally, in most of the reviewed studies, transportation 
contributed only minorly to the environmental impacts, for 
example, the carbon footprint (Oliver-Ortega et al. 2019; 
Suwanmanee et al. 2013; Guo and Murphy 2012).

Against this background, there evidently is a need for 
research considering the environmental impacts of poly-
amide-based biocomposites. Analysis of the environmental 
impacts would also be interesting due to the composition of 
these biocomposites; for example, due to  the spherical 
morphology of the starch particles and their plasticizing 
effect, the latter one being facilitated by the applied com-
patibilization chemistry that enabled the starch content of 
the biocomposite to be elevated to an impressive 70 wt%. 
This would not have been feasible with alternative biofill-
ers, e.g., cellulose or lignin-based materials, owing to the 
unique attributes of starch and the implementation of effec-
tive chemical compatibility measures. Furthermore, the 
newly developed polyamide-starch biocomposite has been 
reported to exhibit other promising characteristics, such as 
exceptionally low melting point, enhanced adhesion between 
the polymer and biofiller together with improved dispersion 
of the biofiller within the polymer matrix, combined with 
excellent rheological properties, and a commendable balance 

between stiffness and toughness (Baniasadi et al. 2023b). 
Yet its environmental impacts still await to be researched. 
Consequently, the goal of the present paper was to quantify 
the total carbon footprint and further identify the hotspots 
of the cradle-to-gate manufacture of the newly developed 
polyamide-starch biocomposite on the laboratory scale to 
investigate any latent potential and bottlenecks for its further 
development from an environmental point of view. The ulti-
mate goal was, therefore, to find out whether the sustainabil-
ity aspect of the polyamide-starch biocomposite in terms of 
its carbon footprint was in line with its previously presented 
promising properties.

As the reasoning, identification of the hotspots and bot-
tlenecks of a new material alternative already on the labora-
tory scale can be argued to enable a more straightforward 
and affordable adjustment of the processes in comparison 
with a more elevated process setup. Moreover, the selected 
approach can be justified by Pini et al. (2020), who empha-
sized that the use of LCA also for the laboratory-scale 
research of chemical compounds should be highly recom-
mended or, depending on the case, even mandatory. This 
statement is supported by the good availability of previously 
conducted laboratory-scale LCAs about the synthesis of 
bio-based plastics (Pini et al. 2020; Ang et al. 2021; Nit-
kiewicz et al. 2020). Intriguingly, a framework for scaling 
up the laboratory-scale chemical production processes for 
LCA was found by the authors (Piccinno et al. 2016), yet it 
was excluded from the study. This is because the framework 
was found not to be applicable to the laboratory-scale setup 
of the present paper, since it was limited to wet chemistry 
(Piccinno et al. 2016), excluding solid-state chemistry, con-
sequently not representing the laboratory processes of the 
present study.

Lastly, it is claimed that the carbon footprint of the newly 
developed polyamide-starch biocomposite will be reduced 
with the increased content of potato starch, outperforming 
the neat copolyamide and, partially, the fossil-based plas-
tics and composites used as the references. In this regard, 
LDPE and PP were selected for the reference fossil-based 
plastics due to their reported high comparability to starch-
based plastics (Broeren et al. 2017), whereas HDPE, PA6, 
and PA6.6 were added to the list due to the contemplated 
advantage to compare the performance of the polyamide-
starch biocomposite to other plain, fossil-based polyamides 
and plastics. In addition to this, a few polyamide-based com-
posites were used as the reference, namely PA610/80 wt% 
REX-PLA and PA40/30 wt% glass fibers, to compare the 
carbon footprint of the polyamide-starch biocomposite also 
to some utterly commercial composites or the ones including 
a commercial polyamide.



3300	 L. Äkräs et al.

Materials and methodology

Goal and scope definition

The aim of the present study was to quantify the carbon 
footprint and identify the hotspots of the laboratory-scale 
manufacture of the novel polyamide-starch biocomposite, 
with the potato starch contents of 0, 10, 30, 50, and 70 wt%, 
by utilizing the widely used technique of LCA according to 
the guidelines set by ISO 14040 and 14044 standards (Inter-
nal Organization for Standardization (ISO) 2006a; Interna-
tional Organization for Standardization (ISO) 2006b). For 
this purpose, the focus of the present study was set on a cra-
dle-to-gate approach, in which the first two life cycle stages 
of the polyamide-starch biocomposite were considered for 
the LCA. The system boundaries, therefore, consisted of 
the raw material extraction and acquisition (cultivation and/
or preparation of the substances for the manufacture of the 
biocomposite) and, further, manufacture of the polyamide-
starch biocomposite per se (see Fig. 1 for the details). The 
steps of use and grave (End-of-Life (EoL) of the biocompos-
ite) were, nonetheless, excluded from the present study. The 
regionalization of the study, in turn, was set to be Finland 
and either Finland, Germany, or France for the manufacture 
of the polyamide-starch biocomposite and the different sub-
stances, respectively, while the functional unit was selected 

to be 1 kg of biocomposite. The selected functional unit 
can be stated to be comparable to the mass-based functional 
units applied for the recent LCA studies, in which the (bio)
composites per study possessed differences in the matrix 
types (Broeren et al. 2017; Kane et al. 2022), filler contents 
(Broeren et al. 2017; Kane et al. 2022), technical properties 
of the resulted (bio)composites (Broeren et al. 2017; Kane 
et al. 2022), and/or different target applications (Broeren 
et al. 2017; Kane et al. 2022). Finally, the target audience 
for the present study consisted of, for instance, scholars and 
industry representatives with a keen interest in bio-based 
composites, particularly polyamide-based ones, and the 
quantified carbon footprint they possess.

Life cycle inventory (LCI)

Manufacture of substances and their LCI

Cultivation of potatoes and production of potato starch  The 
step-by-step progression of the cultivation of potatoes, in 
general, included the actions of liming and tillage to main-
tain the basic growth conditions, together with the plow-
ing of the field. These were followed by planting the potato 
seeds, shaping the potato bed, caring for the crops through 
sufficient fertilization, efficient use of fungicides, herbi-
cides, and insecticides, as well as adjusted sprinkler irriga-
tion (Aaltonen et  al. 2016). In the end, the potatoes were 

Fig. 1   A simplified scheme about the system boundaries of the man-
ufacture of polyamide-starch biocomposite from cradle to gate. The 
gray dashed line represents the overall system and, in more detail, the 
manufacture of the biocomposite, while the color-coded blocks stand 
for the different unit processes, respectively. Additionally, the dashed 
line, red in color, indicates substances that have been excluded from 

the study (clarified in more detail in subSect.  “Manufacture of sub-
stances and their LCI”). Noteworthy, pelletizing has been included in 
the processes of copolymerization and melt blending, even if it has 
been excluded from the scheme, whereas transportation has not been 
depicted in this scheme



3301A cradle‑to‑gate life cycle assessment of polyamide‑starch biocomposites: carbon footprint…

harvested, tentatively cleaned, and placed in the interme-
diate storage when required (Finnamyl and Lapuan Peruna 
2017).

After the successful cultivation, potato starch was 
extracted from the potatoes by utilizing either a filtration 
or a decanter process, which was largely based on the same 
steps, apart from the treatment of potato juice. Namely, in 
the decanter process, as much potato juice as possible was 
extracted after the crushing of potatoes, whereas in the fil-
tration process, only part of the potato juice was extracted, 
followed by utter removal later through fine sizing. In gen-
eral, the process steps for both the filtration and the decanter 
process (the exact order of the filtering of potato mush and 
extracting of potato juice depending on the type of process) 
included obtaining the potatoes, removing the dry soil, stor-
ing the potatoes, floating the potatoes to remove more soil, 
and extracting the stones and other light substances. This 
was followed by further washing the potatoes and crush-
ing them, filtering the resulting potato mush to remove the 
fibers, extracting the potato juice completely or partially, 
concentrating and washing the potato juice, as well as fine 
sizing the mush to remove the rest of the fibers and potato 
juice. The processes ended up with pre-drying, final drying, 
as well as temporary storage and packing of the resulting 
potato starch. (Pääkkönen et al. 2004; Ahokas et al. 2012).

Consequently, the potato starch processing resulted in 
the by-products of potato juice and pulp, further containing 
protein and fiber, whereas the waste streams consisted of 
dry soil, stones and other light substances, sludge, as well as 
wastewater (Pääkkönen et al. 2004; Ahokas et al. 2012). In 
more detail, wastewater included, for instance, potato juice 
and sludge as a result of the washing steps (Välimaa et al. 
2017). Potato juice was mainly utilized as a fertilizer, and 
potato pulp was used as a feed, whereas soil and sludge were 
further able to be used, for example, for landscaping, back-
filling, and as soil on the fields, excluding potato and beet 
fields. Recovery of protein from potato juice by coagulation 
was also possible; nonetheless, it is not yet applicable in 
Finland. Wastewater, in turn, was treated in the activated 
sludge plants within the potato starch processing factories 
(Pääkkönen et al. 2004).

Moreover, the data of Natural Resources Institute Fin-
land’s case study for the cultivation of potatoes was solely 
gathered from Finland, whereas the Ecoinvent data (obtained 
from Ecoinvent v3.8, available in the PRé Sustainability’s 
LCA software of SimaPro) for the processing and modifica-
tion of potato starch was collected from the US, Europe in 
general, Germany, and Finland. Nonetheless, for the pur-
poses of the present study, both processes (cultivation of 
potatoes and production of potato starch) were assumed to 
occur in Finland. Finnish Finnamyl Oy was further selected 
as the potato starch processing company for the present 
study due to its highest production quantities of potato starch 

(100 000–105 000 t/a) (Pääkkönen et al. 2004), combined 
with the shortest distance to the facilities of Aalto Univer-
sity, where the manufacture of polyamide-starch biocompos-
ite was set to be occurred.

For the potato starch processing, dry soil, stones, and 
other light substances were excluded from the LCI of the 
present study due to their assumed lower value as coproducts 
and, therefore, fewer requirements for further processing. 
Potato protein, in turn, was included as an output flow due 
to the utilization of German data. Additionally, as defined in 
ISO 14040 standard (International Organization for Stand-
ardization (ISO) 2006b), the allocation was not able to be 
avoided due to the difficulty of dividing the multi-output 
process of potato starch processing into subprocesses or 
conducting a system expansion due to lack of data. There-
fore, the allocation was based on the quantitative relation-
ship between the coproducts (International Organization for 
Standardization (ISO) 2006b); as the share of potato starch 
was over half of the coproducts, all the burdens were allo-
cated to potato starch. Lastly, wastewater was excluded from 
this allocation, while allocation was not considered for the 
process of cultivation of potatoes.

Regarding the sources of input flows for the process-
ing of potato starch, integrated steam and heat production 
(CHP) has been reported to be widely used in Finland with 
an efficiency of 85% or even 90% (Silvonen and Mäkelä 
1996). Based on this fact, in Sphera’s software of LCA for 
Experts (LCA FE), the process steam from natural gas for 
the processing of potato starch was selected to be the Finn-
ish one with an efficiency of 85%, while the EU-28 tap 
water from groundwater at the plant served as a source of 
tap water. The activated sludge plant for the treatment of 
wastewater of potato starch processing, in turn, was selected 
to be EU-28 municipal wastewater treatment (with agricul-
tural sludge application) due to the fact that, in Finland, the 
sludge resulted from the treatment of wastewater is used 
as organic fertilizers in the fields (Pääkkönen et al. 2004). 
The input flow for this process was further selected to be 
organic, contaminated, and untreated industrial wastewater, 
treated according to Directive 91/271/EEC concerning urban 
wastewater treatment.

Finally, the collected LCI from the Ecoinvent database 
and case study of Natural Resources Institute of Finland is 
not more detailly showcased in the present paper due to the 
commercial origin and general confidentiality of the data, 
respectively. However, the auxiliary processes used to model 
the production of potato starch in LCA FE are presented 
in Supplementary Information’s (SI) Table S1, excluding 
the cultivation of potatoes as no auxiliary processes were 
utilized for its modeling.

Manufacture of  monomers and  compatibilizer  Altogether, 
three monomers were considered for the present LCA study, 



3302	 L. Äkräs et al.

namely 11-aminoundecanoic acid, 1,18-octadecanedioic 
acid, and 1,12-diaminododecane. To start with, the manu-
facture of 11-aminoundecanoic acid was initiated by the 
cultivation of castor beans within the castor plant (Ricinus 
communis L.) in low humidity, adequately high tempera-
tures, and deep sandy loams with required fertility, acidity, 
and drainage, which was followed by the extraction of castor 
oil from the cultivated castor beans, for example, through 
mechanical pressing and/or solvent extraction (Mubofu 
2016). The cultivation of castor beans and extraction of 
castor oil occurred in India, which currently dominates 
both processes globally (Mubofu 2016). In the next step, 
at the manufacturing plant located in Germany to which 
the produced castor oil was transported, transesterifica-
tion of castor oil in the presence of methanol and a catalyst 
was applied to yield methyl ricinoleate and glycerol, after 
which pyrolysis in the presence of steam at the elevated tem-
peratures between 500–600 °C was further utilized to gain 
methyl 10-undecenate and heptanal as the by-product. This 
was followed by bromination, which converted the methyl 
10-undecenate into 11-bromoundecanoic acid, and amina-
tion, resulting in the final intermediate product, 11-ami-
noundecanoic acid (Dimian et al. 2019).

The second monomer, 1,18-octadecanedioic acid was 
manufactured by olefin metathesis (for example, alkenoly-
sis) of purified plant oil (such as rapeseed oil) with 1-butene, 
followed by separation of the resulting olefins and esters 
through distillation. Next, the subsequent transesterification 
of these esters into monoesters, typically fatty acid methyl 
esters (FAME), such as methyl oleate, occurred in the ester 
stream. Finally, the monoesters and the resulting glycerol 
were separated to obtain a range of products, including α,ω-
dicarboxylic acids, such as 1,18-octadecanedioic acid (Chik-
kali and Mecking 2012).

Lastly, the manufacture of the third monomer, 1,12-diami-
nododecane (DMDA), started with the trimerization of buta-
diene, having been derived from fossil-based sources (Yang 
et al. 2010), to 1,5,9-cyclododecatriene (CDT) (Gaide et al. 
2016), catalyzed by nickel (Yang et al. 2010), which was 
followed by either two- or three-step reaction route (Gaide 
et al. 2016). The former included the hydrogenation of CDT 
to cyclododecane and oxidation of cyclododecane with air 
or oxygen to obtain a mixture of cyclododecanol and cyclo-
dodecanone, followed by the oxidation step with nitric acid 
to eventually yield 1,12-dodecanedioic acid (Yang et al. 
2010; Gaide et al. 2016). On the other hand, the latter route 
consisted of the partial hydrogenation of CDT to cyclodo-
decene with the subsequent oxidative ozonolytic cleavage to 
obtain 1,12-dodecanedioic acid (Gaide et al. 2016). Finally, 
these reaction steps were followed by the hydrogenation 
of 1,12-dodecanedioic acid, together with the subsequent 
amination of 1,12-dodecanediol, in the presence of liquid 

ammonia and catalyst of Ru/triphos system to obtain the 
desired 1,12-diaminododecane (Shi et al. 2017).

In addition to these monomers, the compatibilizer of 
ODI was required for the manufacture of polyamide-starch 
biocomposite, which consequently was also considered for 
the present LCA. In this regard, the ODI was synthesized, 
as most of the isocyanates, through a reaction between an 
amine or its salt and phosgene (Ozaki 1972; Saunders and 
Slocombe 1948), which can either be conducted in a solid-, 
liquid-, or vapor-phase, the need of a catalyst depending 
on the selected synthesizing method, and the reaction also 
resulting in the formation of urea as the side-product (Saun-
ders and Slocombe 1948).

The required LCI data were purchased from the private 
company of Sphera Solutions GmbH (in the case of mono-
mers) or collected from the MLC database (in terms of the 
compatibilizer). Nonetheless, the stearic acid (octadecanoic 
acid) dataset, purchased from Sphera Solutions GmbH, and 
a readily available process in LCA FE about aliphatic isocy-
anates were used as a proxy for the monomer of 1,18-octa-
decanedioic acid and compatibilizer of ODI, respectively, 
due to the lack of precise data for the original compatibilizer 
and monomer. These actions were justified by the reported 
possibility of replacing the materials, which are absent in 
the LCA databases, with their closely related analogue (Pini 
et al. 2020). The exact quantities of the input and output 
flows as well as other assumptions of the monomers and 
compatibilizer have, nonetheless, not been reported in the 
present paper due to the commercial origin of the data as 
well as the guidelines set by Sphera Solutions GmbH for the 
datasets developed by them.

Manufacture of  polyamide‑starch biocomposite  The 
manufacture of the novel polyamide-starch biocomposite 
consisted of four basic steps, namely, synthesizing of the 
low-melting-point polyamide through copolymerization, 
surface modification of potato starch to ease its compati-
bilization with the copolyamide matrix, and melt blending 
of these two resulted constituents to obtain the polyamide-
starch biocomposite. In more detail, firstly, the monomers 
of 11-aminoundecanoic acid, 1,18-octadecanedioic acid, 
and 1,12-diaminododecane were copolymerized through a 
polycondensation reaction for 4 h at the temperature of 200–
240 C° with the aid of a catalyst of sodium hypophosphite 
monohydrate under nitrogen flow to obtain the copolymer of 
PA11 and PA1218 (in short, PA11coPA1218) and water as a 
by-product. In the end, the synthesized PA11coPA1218 was 
cooled and pelletized, resulting in plastic granules (Banias-
adi et al. 2023b).

This was followed by the surface modification of potato 
starch with the compatibilizer of ODI, consisting of thor-
ough drying of the starch at 70 °C for 48 h as well as heating 
of the mixture of starch and ODI at 100 °C for 24 h to obtain 



3303A cradle‑to‑gate life cycle assessment of polyamide‑starch biocomposites: carbon footprint…

the surface-modified starch (in short, ODI-g-starch). Finally, 
the resulting PA11coPA1218 and ODI-g-starch were melt 
blended at 200 °C for 1 h by using a twin-screw extruder, 
followed by cooling and pelletizing to obtain the biocompos-
ite granules. After the experiments, the cooling water was 
poured into the sewer (Baniasadi et al. 2023a, b).

The LCI data required for the manufacture of polyamide-
starch biocomposite was directly derived from these labora-
tory-scale experiments conducted at the facilities of Aalto 
University School of Chemical Engineering, except of the 
value for electricity, which was collected from the Ecoin-
vent database. All the input and output flows together with 

the quantities of these unit processes of copolymerization, 
surface modification, and melt blending are further listed 
in Tables 1, 2, and 3, respectively. Additionally, the com-
prehensive description of all the auxiliary processes, flows, 
and data required to model these unit processes in LCA FE 
is provided in SI’s Tables S2–S4. Noteworthy, the LCI data 
for electricity is not showcased in the present paper due to 
its confidentiality.

The manufacture of the catalyst of sodium hypophosphite 
monohydrate for the copolymerization of PA11coPA1218 
was, nonetheless, excluded from the present study since it 
was used in rather small quantities (less than 1% from the 
functional unit of 1 kg of biocomposite), and some polym-
erization reactions can run without a specific catalyst. On the 
other hand, the manufacture of polyamide-starch biocom-
posite on the laboratory scale was assumed not to produce 
considerable solid waste streams or losses of substances, 
which is why these streams and losses were excluded from 
the present study. The utilized cooling water served as an 
exception, resulting in the wastewater being assumed to be 
treated in the EU-28 municipal wastewater facilities.

Similarly, only the copolymerization of 11-aminoundeca-
noic acid, 1,18-octadecanedioic acid, and 1,12-diaminodo-
decane, resulting in PA11coPA1218, was estimated to yield 
a vanishingly small amount of water as a by-product with no 
explicit end-users due to its collection as part of the nitro-
gen flow, which is why also this water was excluded. Con-
sequently, due to the exclusion of solid waste streams and 
by-products, the allocation was not essential to use in this 
manufacturing step of polyamide-starch biocomposite. In 
addition to these, due to its assumably low impacts, pelletiz-
ing was included in the unit processes of copolymerization 
of PA11coPA1218 and its subsequent melt blending with 
surface-modified potato starch without separate modeling 
of this unit process in LCA FE. In other words, pelletizing 
was excluded from the present study.

Additionally, the European electricity grid mix with the 
distribution of energy sources in the European electricity 

Table 1   LCI for the 
copolymerization of monomers 
to obtain PA11coPA1218

Input or output flow Type of constituent Quantity of the constituent (per 
1 kg of biocomposite)

Input 11-aminoundecanoic acid 0.0705 kg
Input 1,18-octadecanedioic acid 0.11 kg
Input 1,12-diaminododecane 0.0701 kg
Input Sodium hypophosphite monohydrate 0.0002 kg
Input Electricity Confidential information (CI)
Input Nitrogen 0.0006 kg
Input Water 40 kg
Output PA11coPA1218 0.23 kg
Output Wastewater (untreated) 40 kg

Table 2   LCI for the surface modification of starch to obtain ODI-g-
starch

Input or 
output 
flow

Type of constituent Quantity of the constituent (per 
1 kg of biocomposite)

Input ODI 0.01 kg
Input Potato starch 0.1 kg
Input Electricity CI
Output ODI-g-starch 0.11 kg

Table 3   LCI for the melt blending of PA11coPA1218 and ODI-g-
starch to obtain polyamide-starch biocomposite

* Depending on the content of potato starch used as a biofiller in the 
copolyamide matrix, namely, 10, 30, 50, or 70 wt%, respectively

Input or 
output 
flow

Type of constituent Quantity of the constituent 
(per 1 kg of polyamide-starch 
biocomposite)

Input PA11coPA1218 granules 0.9, 0.7, 0.5, or 0.3 kg*
Input ODI-g-starch 0.1, 0.3, 0.5, or 0.7 kg*
Input Electricity CI
Input Water 50 kg
Output Polyamide-starch bio-

composite granules
1 kg



3304	 L. Äkräs et al.

grid was utilized as the energy source for all the unit pro-
cesses of this manufacturing stage. The source of nitrogen, 
in turn, for the unit process of copolymerization of mono-
mers was selected to be EU-28 nitrogen (gaseous), which 
can also be found in the Sphera Managed LCA Content 
(MLC) 2023.1 database, available in LCA FE. The value 
for nitrogen flow was estimated based on the experimental 
setup by calculating the amount of gaseous nitrogen being 
consumed during the four hours of copolymerization with 
the flow rate of 2 ml/min. The calculations for the exact 
amount of utilized nitrogen are thoroughly explained in SI’s 
Table S5.

Further, since the overall share of groundwater as a pro-
cess water to produce plastics in Finland can be assumed to 
be slightly greater than that of surface water (Salminen et al. 
2017), desalinated and deionized EU-28 process water from 
groundwater, being available in the MLC 2023.1 database, 
was exploited as a source of cooling water for the unit pro-
cesses of copolymerization of monomers and melt blending 
of constituents. As in the case of nitrogen flow, the value for 
cooling water was assessed based on the laboratory experi-
ments by estimating the amount of consumed water for four 
hours and one hour for the unit processes of copolymeriza-
tion and melt blending, respectively.

Transportation of  substances  The processed potato starch 
was assumed to be transported from its processor of Fin-
namyl Oy, located in Kokemäki in Finland, monomers from 
their selected manufacturing plant of abcr Gute Chemie, 
nestled in Bruchsal in Germany, and the compatibilizer of 
ODI from its manufacturer of Vencorex in France, respec-
tively. Germany was selected as the manufacturing country 
for the monomers due to its relative proximity to Finland 
in comparison with some other European countries and the 
fact that a multitude of fine chemical manufacturers and/or 
suppliers operate in Germany. Noteworthy, for the potato 
starch, monomers, and compatibilizer, the EU-28 diesel mix 
at the refinery, manufactured both from crude oil and from 
biocomponents, together with EU-28 heavy fuel oil at refin-
ery (1.0 wt% S) was selected as the energy sources for trans-
portation in LCA FE, while transportation was excluded 
from the laboratory-scale manufacturing processes of the 
polyamide-starch biocomposite due to the permanent loca-
tion of the experiments with no need for transportation. 
Lastly, the LCI data for the transport of substances was 
gathered from the MLC database, the places of departure 
and arrival, as well as the distances, having been estimated 
with a basis on the selected websites. An in-depth report 
about the transport of these substances can also be found in 
SI, with all the transportation details being concisely pre-
sented in SI’s Table S6.

Sequestered CO2 in  potato starch  The CO2 sequestration 
into the biomass was considered by calculating the CO2 
content of the processed and modified potato starch per 1 kg 
of biocomposite according to Eq. (1). For these calculations, 
potato starch was selected as the carbon sink instead of pota-
toes due to the better consideration of its main output flows 
in the LCA model, namely, all the burdens of this produc-
tion step were allocated to potato starch. Finally, these cal-
culations of sequestered CO2 in potato starch are explained 
in more detail in SI’s Table S7.

where CDR(CO2) stands for the amount of sequestered 
CO2 in potato starch, M(C)ST for the molecular weight of 
carbon in potato starch, M(ST) for the molecular weight 
of potato starch, m(ST)biocomposite for the amount of potato 
starch required for 1 kg of biocomposite, M(C)CO2 for the 
molecular weight of carbon in CO2, M(CO2) for the molec-
ular weight of CO2, and Cf(CO2) for the characterization 
factor of CO2.

Life cycle impact assessment (LCIA)

Software, databases, and impact category

Sphera’s LCA FE with MLC 2023.1 databases, including 
the impact assessment method EF 3.1, was used to execute 
the LCIA of the present paper. Further, climate impact 
(expressed as kg CO2 eq./kg of biocomposite) played the role 
of the principal impact category for the present LCA study 
to quantify the carbon footprint of the biocomposite under 
analysis. In more detail, climate impact was selected for the 
study since it is the most researched impact category, which 
has successfully been used to quantify the carbon footprint 
reductions of different types of (bio)composites (Broeren 
et al. 2017; Oliver-Ortega et al. 2019; Torrell Gines 2016; 
Mahalle et al. 2014; Guo and Murphy 2012; Kane et al. 
2022), therefore possessing potential in aiding the develop-
ment of more climate-friendly plastics.

Sensitivity analysis

Sensitivity analysis was applied in the present paper to see 
how the alteration of data and model details will affect the 
LCIA results, with an aim to both tentatively simulate indus-
trial-scale production and preliminary explore the influence 
of a decarbonized electricity grid mix in the future. This 
was done by adding internal circulation of cooling water 

(1)CDR(CO2) =

⎛
⎜⎜⎜⎝

�
M(C)ST

M(ST)

�
⋅ m(ST)biocomposite�
M(C)CO2

M(CO2)

�
⎞
⎟⎟⎟⎠
⋅ Cf(CO2)



3305A cradle‑to‑gate life cycle assessment of polyamide‑starch biocomposites: carbon footprint…

in the manufacture of biocomposite on the laboratory scale 
and switching the European electricity grid mix to the 
Finnish alternative to accomplish the first and second aim, 
respectively. Nonetheless, the electricity grid mix used for 
the datasets of monomers and compatibilizer was left intact 
due to their commercial origin and, thus, non-modifiable 
characteristics. Stemming from this overview, in the follow-
ing results and conclusion Sects. “Results and discussion” 
and “Conclusions,” respectively, the two types of sensitivity 
analyses are referred to as sensitivity analysis 1 and sensi-
tivity analysis 2 (in short, SA1 and SA2), respectively, the 
former representing the case with the Finnish electricity grid 
mix and internal circulation of cooling water and the latter 
one with Finnish electricity grid mix and without an internal 
circulation of cooling water.

Results and discussion

Carbon footprint and sensitivity analysis 
of polyamide‑starch biocomposite

The core aim of the conducted LCA of the present paper, as 
previously defined in the introduction and subSect. “Goal 
and scope definition,” was to quantify the total carbon 
footprint and identify the hotspots of the manufacture of 
polyamide-starch biocomposite, closely followed by explor-
ing the effect of applied sensitivity analyses of the selected 
processes on the final LCIA results. Ergo, in the present 
subsection, an in-depth analysis of the obtained LCIA results 
has been conducted with a joint and, when required, separate 
focus on each of the cases (baseline case and the two types 
of sensitivity analyses SA1 and SA2, respectively), consist-
ing of the analysis of the general phenomenon, caused by the 
addition of potato starch as the biofiller into the copolyam-
ide matrix, together with the identification and evaluation 
of the hotspots within the defined system boundaries. The 
core focus of the present paper was on a carbon footprint; 
however, a primary analysis about acidification, eutrophi-
cation (terrestrial, freshwater, and marine), as well as land 
use impacts of polyamide-starch biocomposite was also con-
ducted and is provided in SI’s Figures S1–S3.

Having said this, all the total carbon footprints and hot-
spots per baseline case as well as SA1 and SA2, respectively, 
are presented briefly in Fig. 2. Noteworthy, the amount of 
sequestered CO2 in potato starch was calculated to be as low 
as –0.16 kg CO2 eq./kg of biocomposite with a minor effect 
on the total LCIA results, which is why the sequestered CO2 
is excluded from the analysis of the present subsection and 
Fig. 2, subSect. “Comparison of the LCIA results to the 
literature and reference plastics” and Fig. 3 being an excep-
tion. Additionally, the production processes of monomers 
and compatibilizer were combined for the LCA calculations 

as well as presenting the LCIA results to meet the guide-
lines set by Sphera Solutions GmbH for the purchased 
datasets developed by them and the ones available in their 
LCA FE software. Lastly, to enhance the reportability and 
understandability of the LCIA results, the carbon footprints 
caused by the unit processes of copolymerization, surface 
modification, and melt blending—their values being van-
ishingly low on their own—were calculated, presented, and 
analyzed under the umbrella term of manufacture of poly-
amide-starch biocomposite.

To start with, the general phenomenon that resulted in 
the addition of potato starch into the copolyamide matrix 
was evident and visible in terms of all the studied cases; this 
addition progressively reduced the total carbon footprint of 
polyamide-starch biocomposite, even up to 42–43% with the 
highest potato starch content of 70 wt% in comparison with 
the plain copolyamide. This occurrence can be attributed 
to the production processes of potato starch per se, in more 
detail, the cultivation of potatoes, as well as the processing 
and modification of potato starch. Namely, as can also be 
seen from Fig. 2, the carbon footprint of these two processes, 
altogether, was constantly considerably lower than the one 
caused by the production of monomers and compatibilizer 
(the energy-intensive monomers being the major contributor 
to the total carbon footprint of polyamide-starch biocompos-
ite). The contribution of these monomers and compatibi-
lizer, both requiring long-distance transportation from their 
manufacturers, was replaced step by step to a greater extent 
upon the addition of locally produced potato starch (Oliver-
Ortega et al. 2019; Guo and Murphy 2012). In more detail, 
on one hand, the share of the production of monomers and 
compatibilizer from the total carbon footprint of polyamide-
starch biocomposite was decreased by 14, 12.7, and 12.4% 
for the baseline case, SA1, and SA2, respectively. On the 
other hand, the share of cultivation of potatoes from the total 
carbon footprint was increased by 7.4, 8, and 7.5% for the 
baseline case, SA1, and SA2, respectively, and simultane-
ously, the share of processing and modification of potato 
starch from the same total carbon footprint was increased 
by 5.1, 3.8, and 3.6% for the baseline case, SA1, and SA2, 
respectively.

Nonetheless, despite this unquestionable role of the culti-
vation of potatoes together with processing and modification 
of potato starch in reducing the total carbon footprint of 
polyamide-starch biocomposite, also other processes within 
the system boundaries, required to manufacture the biocom-
posite, participated in this job, although to a lesser extent. 
Ipso facto, upon the increased addition of potato starch into 
the copolyamide matrix, the carbon footprint caused by the 
transport of substances was increased by 0.32, 0.38, and 
0.35%, and the manufacture of polyamide-starch biocom-
posite by 1.2, 0.54, and 0.9% for the baseline case, SA1, 
and SA2, respectively. These can be stated to be caused by 



3306	 L. Äkräs et al.

the slightly increased amount of potato starch transported 
to Aalto University and further used to manufacture the 
polyamide-starch biocomposite at the facilities of Aalto 
University.

Additionally, when having a further look at the differ-
ences between the studied cases, the total carbon footprint 
with the progressively increased content of potato starch was 
found to be 5.4–7.7% and 0.1–2.1% lower in terms of SA1 
and SA2, respectively, when compared to the total carbon 
footprint of the baseline case. In more detail, considering 
the former case (SA1), this can mainly be attributed to the 
simulated internal circulation of cooling water with an utter 
removal of the impacts caused by the production, circulation, 

and wastewater treatment of this cooling water, which 
slightly decreased the total carbon footprint. This is a rea-
sonable outcome because the environmental impacts caused 
by the laboratory-scale processes are often higher than their 
industrial-scale counterparts (Piccinno et al. 2016).

On the other hand, in terms of the latter case (SA2), 
the occurrence can be reasoned by the different sources 
used for the European and Finnish electricity generation, 
the European one mainly relying on coal, gas, and other 
fossil fuels with a share of 39% of the total electricity 
generation, followed by nuclear as well as combined wind 
and solar (both having a share of 22%), while Finland 
primarily utilizes nuclear (close to 40%) with a higher 

Fig. 2   A set of graphs showcasing the total LCIA results of the pol-
yamide-starch biocomposite with varying content of potato starch, 
combined with the contribution of each production step, per base-
line case and applied sensitivity analyses SA1 and SA2, respectively. 
Further, the abbreviations BioCo1, BioCo2, BioCo3, BioCo4, and 
BioCo5 stand for the polyamide-starch biocomposite with the starch 

contents of 0, 10, 30, 50, and 70 wt%, respectively. A. The baseline 
case (without an internal circulation of cooling water). B. SA1 (with 
Finnish electricity grid mix and an internal circulation of cooling 
water). C SA2 (with Finnish electricity grid mix and without an inter-
nal circulation of cooling water). Noteworthy, the sequestered CO2 in 
potato starch has not been considered in the present figure



3307A cradle‑to‑gate life cycle assessment of polyamide‑starch biocomposites: carbon footprint…

share of hydro- and bioenergy (both close to 20%) (Jones 
et al. 2023). As the reasoning, the burning of fossil fuels 
has been reported to emit higher CO2 emissions than, for 
example, the use of nuclear and hydro as the sources for 
electricity generation (Yadav et al. 2021), which conse-
quently decreases the impact caused by the processing and 
modification of potato starch together with the manufac-
ture of polyamide-starch biocomposite of the present study 
upon the application of Finnish electricity.

After evaluating the bigger picture, it is time to cap off 
this subsection by having a detailed look at the hotspots. 
Regarding the matter, Fig. 2 clearly showcases that the pro-
duction step of monomers and compatibilizer (and primar-
ily the monomers) evidently was the major hotspot for all 
the cases, and its share ranged between 79–93, 86–99, and 
81–93% of the total carbon footprint for the baseline case, 
SA1, and SA2, respectively. Apart from this, the otherwise 
slight variation in the order of hotspots was found to be 
dependent both on the content of potato starch and on dif-
ferent cases, namely, in terms of the baseline case and SA2, 
excluding the highest content of potato starch, while the sec-
ond most contributing production step was the manufacture 
of polyamide-starch biocomposite with the share of total 
carbon footprint ranging between 5.6–6.8% and 5.5–6.4% 
for the baseline case and SA2, respectively. Yet, SA1 served 

as the exception in this observation, with the biocompos-
ite’s manufacturing step having been the minor contributor 
throughout the varying content of potato starch with a share 
of 0.2–0.7% of the total carbon footprint.

In the case of the rest of the production steps, transpor-
tation contributed, most of the time, the least to the total 
carbon footprint in the baseline case as well as SA2 and the 
second/third least in SA1 with the share of 1.24–1.69% of 
the total carbon footprint. Finally, the contribution of the 
production steps of potatoes and potato starch progressively 
increased upon the increased addition of potato starch, with 
these two steps ultimately having been the fourth and sec-
ond/third most contributing steps with the share of 7.4–8 and 
3.6–5.1%, respectively, in the case of the highest content of 
potato starch in all the cases under analysis.

Comparison of the LCIA results to the literature 
and reference plastics

As previously stated, the available LCA studies about the 
polyamide-based or starch-including (bio)composites indi-
cated that the increase in the bio-based content of the (bio)
composites could reduce their environmental impacts in 
certain impact categories (such as in terms of their carbon 
footprint) (Oliver-Ortega et al. 2019; Torrell Gines 2016; 

Fig. 3   A set of graphs comparing the performance of polyamide-
starch biocomposite of the baseline case with the lowest and highest 
content of potato starch (namely, 0 and 70 wt%, respectively) to the 
selected fossil-based plastics and polyamide-based composites. Fur-
ther, the abbreviations of BioCo1, BioCo5, Co1, and Co2 stand for 
the plain copolyamide, polyamide-starch biocomposite with a starch 
content of 70 wt%, PA610/80 wt% REX-PLA, and PA40/30 wt% 

glass fibers, respectively. A, Polyamide-starch biocomposite vs. the 
selected fossil-based plastics. B, Polyamide-starch biocomposite vs. 
the selected polyamide-based composites. Noteworthy, in the figure, 
the sequestered CO2 is included in the carbon footprint of polyam-
ide-starch biocomposite and the plain copolyamide. Additionally, the 
sequestered CO2 has been assumed to be considered in the carbon 
footprint of all the reference polyamide-based composites



3308	 L. Äkräs et al.

Mahalle et al. 2014), making them outperform some of 
the fossil-based plastics in these categories (Broeren et al. 
2017; Mahalle et al. 2014; Guo and Murphy 2012). Despite 
the reductions in the carbon footprint, upon the increased 
bio-based content, the agricultural-related impacts of these 
(bio)composites are simultaneously worsened (Broeren et al. 
2017; Mahalle et al. 2014; Guo and Murphy 2012).

Regarding the hotspots, the process with the highest car-
bon footprint, irrespective of the polymer matrix or biofiller, 
seems to be, in some cases, the manufacture of monomers 
for the plastic matrix, whereas transportation is the least 
polluting one (Oliver-Ortega et al. 2019; Suwanmanee et al. 
2013; Guo and Murphy 2012), followed by the manufacture 
of biofiller and (bio)composite (Correa et al. 2019; Oliver-
Ortega et al. 2019). Stemming from this, the cultivation and 
processing of the biofiller can be stated to act as a minor 
contributor to the total carbon footprint, for example, in the 
case of virgin potato starch (Broeren et al. 2017), for which 
the carbon footprint per se is rather low (e.g., 0.88 CO2 eq./
kg of dry native starch produced from wheat, maize, or pota-
toes (An et al. 2012)). Despite these outcomes, it is good to 
bear in mind that the results in the form of their absolute val-
ues cannot directly be compared with each other due to the 
methodological differences of various LCA studies (Walker 
and Rothman 2020); ergo, the direct comparison of these 
literature findings with the LCIA results acquired from the 
present study was excluded from the discussion. However, it 
can be concluded that the general phenomenon in the outline 
is similar between the LCA studies of the analyzed literature 
and the present paper.

Additionally, Fig. 3 showcases the performance of the 
polyamide-starch biocomposite vs. the selected reference 
fossil-based plastics and composites, from which the data 
for PP, HDPE, LDPE, and PA6.6 were collected from the 
reports of PlasticsEurope (PlasticsEurope 2014a, 2014b, 
2014c), while the data for PA12, PA6, PA40/30 wt% glass 
fibers, and PA610/80 wt% REX-PLA were found from the 
literature (Petersson et al. 2013; Torrell Gines 2016; Lon-
don 2020; Brehmer 2014). Noteworthy, the carbon footprints 
of these reference plastics and composites have not been 
quantified along with the ones of polyamide-starch biocom-
posite but extracted from the reports or literature, which is 
a viable approach previously used by Broeren et al. (2017). 
Regarding the matter, the total carbon footprint caused by 
the baseline case’s polyamide-starch biocomposite with 
the highest content of potato starch (70 wt%) was 64, 49, 
and 43% higher in comparison with the fossil-based plas-
tics of PP, HDPE, and LDPE, respectively, and this specific 
biocomposite simultaneously had 29, 39, and 42% lower 
carbon footprint than the ones of fossil-based polyamides, 
PA6, PA12, and PA6.6, respectively. In a similar manner, 
the carbon footprint of the baseline case’s polyamide-starch 
biocomposite was decreased by 59 and 79% in comparison 

with the ones of the composites, PA610/80 wt% REX-PLA 
and PA40/30 wt% glass fibers, respectively.

Noteworthy, despite the fact that the functional units and 
system boundaries of these reference plastics and compos-
ites are in outline comparable to the one of the present paper, 
their LCIA results can be slightly affected by the applied 
LCIA impact assessment methods other than EF 3.1 (differ-
ence 1) (Torrell Gines 2016; PlasticsEurope 2014a, 2014b, 
2014c), the separate inclusion of the electricity-requiring 
pelletizer in the LCA (difference 2) (Torrell Gines 2016; 
PlasticsEurope 2014a, 2014b, 2014c), together with the 
addition of product manufacturing step (difference 3), for 
example, through injection molding (Petersson et al. 2013). 
These differences might either slightly underestimate or 
overestimate the final LCIA results in the case of difference 
1 and 2/3, respectively, in comparison with the present study 
with, although assumably, no remarkable effect on the final 
conclusions presented in this subsection.

Based on this analysis, the specific polyamide-starch 
biocomposite of the present study with previously reported 
excellent properties can be envisaged to possess a bet-
ter environmental performance from the global warming 
potential point of view in comparison with the commercial, 
energy-intensive fossil-based polyamides and, partially, 
some of the polyamide-based composites, consequently 
advancing the more climate-friendly manufacture of plas-
tics through blatant reductions in their total carbon footprint. 
Despite this outcome, advancements in the manufacture of 
monomers, combined with the minimization of the amount 
of compatibilizer (Broeren et  al. 2017), are required to 
ensure the polyamide-starch biocomposite’s ability to bet-
ter compete with the fossil-based plastics of PP, HDPE, and 
LDPE with a relatively low climate impact, for instance 
through decarbonization of energy by increasing the share 
of utterly biosourced electricity (Zheng and Suh 2019). 
Alternatively, evaluation of other possible bio-based plastic 
matrices for biocomposites with initially lower carbon foot-
print or application of agricultural wastes as biofillers are 
also options worth considering in reducing the total carbon 
footprint of biocomposites more remarkably. One promising 
option would also be to blend biofillers with fossil-based 
polyolefins to increase their bio-based content and, poten-
tially, lower their carbon footprint to some extent.

Limitations of the study

Despite the great efforts, every LCA study possesses its 
own limitations as well as requirements for enhancement 
and future research, and the study in question is no excep-
tion. Consequently, calculations of the amount of nitrogen 
and water for the unit processes of copolymerization and 
melt blending contain some uncertainties due to the diffi-
culty of estimating the exact quantity for both the initial 



3309A cradle‑to‑gate life cycle assessment of polyamide‑starch biocomposites: carbon footprint…

nitrogen and the water flows as well as the timescale for the 
exact utilization of these resources during the experimental 
work. Therefore, it would have been ideal to utilize more 
accurate data for these purposes, which had required, instead 
of assessing the matter through calculations and/or assump-
tions afterward, the direct and precise measurement of water 
and nitrogen flows already during the experimental work. In 
terms of other estimations, the places of arrival and depar-
ture, as well as approximated distances of land and ocean 
routes for the transportation of substances, primarily had 
grounded on assumptions, which, however, can be argued 
to have only a marginal effect on the acquired LCIA results.

In addition to the previous aspects, the use of stearic acid 
and a mix of aliphatic isocyanates as a proxy for 1,18-octa-
decanedioic acid (the monomer) and ODI (the compatibi-
lizer), respectively, as the input flows for the unit processes 
of copolymerization or melt blending has, to some extent, 
influenced the LCIA results. In more detail, the application 
of stearic acid has most probably underestimated the real 
carbon footprint of 1,18-octadecanedioic acid since some of 
its process steps are missing in the proxy, while the utiliza-
tion of aliphatic isocyanates has, most likely, overestimated 
the actual carbon footprint of ODI due to the higher number 
of isocyanates included in this proxy dataset. In this con-
text, the exclusion of pelletizing step may also have slightly 
underestimated the carbon footprint caused by the manufac-
ture of biocomposite. Finally, the comparison of the LCIA 
results of different technological scales (laboratory scale vs. 
the industrial one) can also be considered as one of the limi-
tations of the present study.

Development points and suggestions for further 
research

A full scaling up of the present laboratory-scale experiments 
could have been worth considering because, on the indus-
trial scale, the equipment of chemical processes is more 
complex with linked process steps (Piccinno et al. 2016), 
which affects the final LCIA results by usually lowering the 
total impacts in comparison with the ones derived from the 
laboratory conditions (Piccinno et al. 2016). This scaling 
up would also have improved the comparison of polyamide-
starch biocomposite, manufactured in the laboratory, with 
the commercial alternatives (Piccinno et al. 2016). Despite 
this, the acquired LCIA results of the present paper, as they 
are, already possess societal relevance. Lastly, the inclusion 
of a wider set of impact categories could have derived a 
broader picture of the environmental impacts caused by the 
manufacture of polyamide-starch biocomposite of the pre-
sent paper.

Overall, in the future, a discreet enhancement of the LCI 
data and the related assumptions, a full scaling up of the 
laboratory-scale experiments of the present study into an 

industrial scale, together with an inclusion of a broader 
set of impact categories, would be beneficial in obtaining 
a more relevant and comprehensive understanding of the 
environmental impacts caused by the manufacture of pol-
yamide-starch biocomposite of the present paper. The pro-
posed approach could also better facilitate the development 
and promotion of the newly developed polyamide-starch 
biocomposite (Piccinno et al. 2016), potentially also on the 
industrial scale.

Conclusions

In the present paper, a comprehensive cradle-to-gate LCA 
of a newly developed polyamide-starch biocomposite was 
conducted, varying the content of potato starch from 0 to 
70 wt%, with a specific focus on its carbon footprint. The 
results of the LCA are promising and provide valuable 
insights about the early-stage environmental burdens of the 
biocomposite with a possibility to forecast the impacts of its 
industrial-scale production; nonetheless, there is still poten-
tial for further carbon footprint reductions. One approach 
would, therefore, be to enhance the production of energy-
intensive monomers, while also reducing the required 
amount of compatibilizer. These improvements would ena-
ble the developed biocomposite to better compete with the 
commercial, fossil-based polyolefins that currently have a 
relatively low carbon footprint. For future LCA studies, in 
turn, it is recommended to scale up the laboratory setup to 
facilitate meaningful comparisons with various commercial 
plastics and (bio)composites. It would also be beneficial to 
explore a broader set of applied impact categories to gain a 
comprehensive understanding of the overall environmental 
impacts caused by the polyamide-starch biocomposite. To 
end up with, the polyamide-starch biocomposite presented 
in this paper, especially with the highest content of potato 
starch (70 wt%), has demonstrated considerable potential for 
reducing the carbon footprint of plain polyamides.

Supplementary Information  The online version contains supplemen-
tary material available at https://​doi.​org/​10.​1007/​s10098-​024-​02884-1.

Acknowledgments  The authors would like to profusely thank for the 
received funding No. 327248 (ValueBioMat), having been provided by 
the Strategic Research Council (SRC), established within the Academy 
of Finland. Additionally, the authors are very grateful for the excellent 
service provided by the staff of Sphera Solutions GmbH. Lastly, the 
authors would like to cordially thank Johan Äkräs for skillfully helping 
to make the graphical abstract as wonderful as it is today.

Author contributions  Laura Äkräs contributed to conceptualization, 
methodology, software, investigation, data curation, formal analysis, 
visualization, writing—original draft, and project administration. 
Frans Silvenius contributed to conceptualization, investigation, data 
curation, formal analysis, and writing—review and editing. Hossein 

https://doi.org/10.1007/s10098-024-02884-1


3310	 L. Äkräs et al.

Baniasadi contributed to conceptualization, investigation, data cura-
tion, and writing—review and editing. Marjatta Vahvaselkä contrib-
uted to writing—review and editing. Hannu Ilvesniemi contributed to 
writing—review and editing and funding acquisition. Jukka Seppälä 
contributed to conceptualization, writing—review and editing, funding 
acquisition, and supervision.

Funding  Open Access funding provided by Aalto University. The 
research leading to these above-described results received funding from 
the Strategic Research Council (SRC), established within the Academy 
of Finland, under Grant Agreement No. 327248 (ValueBioMat).

Data availability  The exact LCI and LCIA data not reported in the 
present paper are either of commercial or of confidential origin and, 
consequently, cannot be publicly shared. However, the modeling details 
for the production of potato starch and laboratory-scale experiments, 
detailed calculations for gaseous nitrogen and sequestered CO2 in 
potato starch, transportation details, as well as LCIA results of acidi-
fication, eutrophication (terrestrial, freshwater, and marine), and land 
use are available as Supplementary Information.

Declarations 

Conflict of interest  The authors have no conflict of interests to declare.

Open Access  This article is licensed under a Creative Commons Attri-
bution 4.0 International License, which permits use, sharing, adapta-
tion, distribution and reproduction in any medium or format, as long 
as you give appropriate credit to the original author(s) and the source, 
provide a link to the Creative Commons licence, and indicate if changes 
were made. The images or other third party material in this article are 
included in the article’s Creative Commons licence, unless indicated 
otherwise in a credit line to the material. If material is not included in 
the article’s Creative Commons licence and your intended use is not 
permitted by statutory regulation or exceeds the permitted use, you will 
need to obtain permission directly from the copyright holder. To view a 
copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.

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3312	 L. Äkräs et al.

Authors and Affiliations

Laura Äkräs1 · Frans Silvenius2 · Hossein Baniasadi1 · Marjatta Vahvaselkä3 · Hannu Ilvesniemi3 · Jukka Seppälä1

 *	 Jukka Seppälä 
	 jukka.seppala@aalto.fi

1	 Polymer Technology, School of Chemical Engineering, 
Aalto University, Kemistintie 1, 02150 Espoo, Finland

2	 Bioeconomy and Environment, Natural Resources Institute 
Finland, Latokartanonkaari 9, 00790 Helsinki, Finland

3	 Production systems, Natural Resources Institute Finland, 
Latokartanonkaari 9, 00790 Helsinki, Finland


	A cradle-to-gate life cycle assessment of polyamide-starch biocomposites: carbon footprint as an indicator of sustainability
	Abstract
	Graphical abstract

	Introduction
	Materials and methodology
	Goal and scope definition
	Life cycle inventory (LCI)
	Manufacture of substances and their LCI
	Cultivation of potatoes and production of potato starch 
	Manufacture of monomers and compatibilizer 
	Manufacture of polyamide-starch biocomposite 
	Transportation of substances 
	Sequestered CO2 in potato starch 


	Life cycle impact assessment (LCIA)
	Software, databases, and impact category
	Sensitivity analysis


	Results and discussion
	Carbon footprint and sensitivity analysis of polyamide-starch biocomposite
	Comparison of the LCIA results to the literature and reference plastics
	Limitations of the study
	Development points and suggestions for further research

	Conclusions
	Acknowledgments 
	References