5
Journal of Sustainable Architecture and Civil Engineering 2022/2/31

*Corresponding author: heidi.turunen@aalto.fi

Research Dialogue 
between Materials and 
Products in Architecture

Received  
2022/02/31

Accepted after  
revision 
2022/06/01

Journal of Sustainable 
Architecture and Civil Engineering
Vol. 2 / No. 31 / 2022
pp. 5-20
DOI 10.5755/j01.sace.31.2.30963

Research 
Dialogue between 
Materials and 
Products in 
Architecture

JSACE 2/31

http://dx.doi.org/10.5755/j01.sace.31.2.30963

Heidi Turunen 
Aalto University, Department of Architecture, School of Arts Design and Architecture,  
Otaniementie 14, 02150 Espoo, Finland

Introduction

Abstract
The materials life cycle consists of several phases. If application areas are targeted for architecture, 
comprehending the demands of the end-use phase might not be clear at the research and development 
phase, leading to an entity appearing fragmented. The aim of this study is to help bring order to the 
material research or development phases. The objective is to generate a review tool, which helps to 
observe different areas where architecture operates, and contemplate simultaneously the aspects during 
the different phases of the material development. The review tool of the material life cycle consists 
of tracking the raw materials until the re-used raw material, resulting in eight different stages of the 
material life cycle. In addition, each of the eight stages of the material life cycle is possible to observe with 
the five different viewpoints, which are present in architecture. These eight material life cycle stages and 
five aspects have been formulated as a chart. The chart consists of 40 different approaches facilitating 
discussion between different operators during the different phases of the material development. The 
chart might help set goals, frame areas, and improve comprehension of the research and development 
processes of the materials, especially when interdisciplinarity is involved in the research process. 

Keywords: architecture, interdisciplinarity, materials development, materials life cycle, materials research. 

In architecture, construction materials have certain characteristics and aspects to fulfil depending 
on where and how they are applied. Traditionally, practitioners have obtained an intrinsic under-
standing of the materials by gathering knowledge when interacting with the materials on a prac-
tical level. Professionals, who are specialised in understanding the role of materials or methods 
in constructing, such as construction workers, craftspeople, builders, and architects, must un-
derstand the relatively simple processes involved therein. Due to this basic understanding, the 
communication between professionals is effortless because the targets are easy to discuss; the 
concepts are clear; and the materials or processes are well known. Though, when new technol-
ogies or materials are intended to be applied in the construction industry, special expertise is 
required (Giesekam et. al 2016). 

In architecture, materials are not just thought to constitute the protective shells, carry loads, or 
divide spaces. The material palette utilised in architecture is in general extremely versatile. Dif-
ferent materials must play well together leading to a meaningful and pleasant spatial experience, 
noting the function of the building, demands of the user, cultural aspects of the context, and overall 
cost of the constructing. Without a holistic perspective, the outcomes might be very practical or 
technically competent, but they may not necessarily be easy to implement in a living environment, 
where various aspects are meaningful. 



Journal of Sustainable Architecture and Civil Engineering 2022/2/31
6

Due to the new demands of sustainability, which can be an enabler of cross-disciplinary co-op-
eration, to improve the material palette for architecture, new methods for co-work may be a re-
quirement. Currently, the materials variety is much wider (Ballard Bell and Rand 2014), and there 
is the possibility to design materials with the help of technology (Ballard Bell and Rand 2006). As 
such, it may be wise to recognise those areas with the greatest potential for cross-disciplinary 
development. In architecture, the development of commercial products might involve many steps, 
and along the journey of the material, professionals involved in the design or construction phase 
might not have had a role in that process nor had an opportunity to influence the material charac-
teristics in relation to the intended end use. 

In architecture, traditional methods and best practices exist, which may be considered, when devel-
oping new products for the market. In general, the designed outcomes are customised, but there is 
demand, due to large production units, for including repetition in the designs (Gulling 2018). When 
processes become complicated, the knowledge and skills involved turn out to be fragmented due to 
specialisation (Hirshinger et. al 2006). This fragmentation may be an undesirable trait in cross-dis-
ciplinary material research and development. In fragmented specialisations, the processes are led 
by experts from different disciplines focused on specific phases, methods, or processes, and they 
are not necessarily concerned with the designed outcome or entity. Due to this, the fragmented 
knowledge at the level of materials is fused to one selected best outcome with a hierarchical eval-
uation by several experts during the process. As such, a wide comprehension of the entire material 
life cycle might be helpful to comprehend. In addition to this, it might be beneficial to understand the 
mindset of a person – an architect – who can influence the material selection in a building or living 
environment and can be educated to focus on the use-phase of the building. By combining these 
two aspects of the life cycle and where the architecture exists, the process and the outcome can be 
approached more holistically to facilitate materials research and development.

Consequently, the main objective of this study is to facilitate co-operation in architecturally related 
materials research and development. When objectives and research tasks were examined empir-
ically from an architectural point of view, a large gap was found between the preliminary research 
and the commercial products. This may be due to different emphases, objectives and practices of 
research and development activities as well as different stages of the process. After noticing the 
gap, the intention arose to approach the research and development tasks with valued aspects in 
the final products, and to reflect the knowledge to the different stages of the material research 
and development process. The results of research and development tasks, if they are intended to 
support product development, must take into account the stage of use and the user. The architect 
is an expert who is aware or the requirements of both of these. Materials research has several 
tools, but lacks a connection to architectural practices and values when the goal is to develop ma-
terials for architecture. In practice, valuable and meaningful information can be produced at the 
intersection of different stages in the research and development process and valued aspects in ar-
chitecture. The related task has been to develop a chart-based review method generating valuable 
information for facilitating materials research and development. Generally, material scientists or 
other material-related experts are exceedingly aware of the processing methods and technical 
aspects of materials during materials development. However, there remains some disconnect be-
tween this knowledge and its practical application in architecture. Given this, the aim of the study 
has been to generate knowledge of aspects valued in the combination of the life cycle of materials 
and architecture and provide the information to those involved in the material development work. 
The applications of the method presented in this paper are highly practical. The method generates 
knowledge of the user of the building at the level of experiencing the surroundings with their 
senses. In addition, with the assistance of the method, it is possible to discuss the profitability of 
the material from the point of view of material economy, social influence, or technology. These 
emphasised aspects might not be clear among individuals with specific tasks at the material 
research stage. 



7
Journal of Sustainable Architecture and Civil Engineering 2022/2/31

Fractured Material Development  
Materials research and development cover already in themselves various disciplines. The goals 
can vary from developing existing materials with enhanced properties to entirely new materials. 
On a practical level, the research and development may concentrate on developing natural mate-
rials or artificial materials. The result of both can be materials with more refined characteristics. 
At its simplest, materials research and development may concentrate on only improvements to 
one material whilst a more advanced study can concentrate on adjusting several parameters due 
to a combination of different materials. For instance, smart materials or semi-smart materials 
have a specific functionality, property, or change in appearance (Ritter 2007). Currently, the design 
of materials can be elevated to an even more advanced level with bio-design, where materials are 
or have been living during the life cycle of an organism (Antonelli 2014), or those materials can 
be adjusted by means of chemistry. Similarly, materials can reach a next level in design due to 
metamaterials, which are engineered to achieve outcomes, which may not exist in nature. Wide 
themes, in which a multidisciplinary approach is required, could be a replacement for plastics with 
bio-based alternatives, leading to sustainable construction materials, or production of super-ma-
terials with currently unidentified features. Moreover, material research may apply knowledge of 
various disciplines to obtain pre-set targets. Prior to that, the knowledge of experts, disciplines, or 
demands to facilitate research and development is valued and required. 

In the study of materials, the research phase differs substantially from the product development 
phase. Materials research is typically conducted prior to the product design phase, especially in 
the cases where the end uses are not strictly defined. In the product development phase, the out-
comes are defined more accurately. The frames for the development work have been document-
ed, for instance, at the design brief, where the objectives are presented and delivered for devel-
opers, participants, or stakeholders. In the research phase, experts from the various fields might 
be present, and knowledge sharing of different disciplines is exceedingly valuable. In scientific re-
search projects, the practical end-use application might not be specified precisely in the research 
phase. Due to this, even if the potentials and properties of the material has been established to 
a certain level, these do not necessarily guide or determine the development process towards a 
certain product. This may be due to the fact that in materials research and development, scientists 
may study materials from specific viewpoints, such as at the level of the chemical composition. 
In between chemically modified materials and the end-use application of a material, there is long 
journey to bridge. 

Role of Materials in Architecture
In architectural design, both technological aspects and artistic creativity are present. Architecture 
can be thought of as the practical fulfilment of different functions whilst, in contrast, architectural 
construction has a close relationship to the artistic approach (Mordaunt Crook 1987). In archi-
tecture, this differentiation has been considered to be significant, especially after the industrial 
revolution (Giedion 2008). The twofold approach of technology and art can be zoomed in and ob-
served in limited sections. The chosen materials, for instance, can be in their smaller constitutive 
parts observed from the standpoint of both domains. At this level, the aspects can be related, for 
instance, to technical features or artistic creativity in materials. 

Various Viewpoints of Architecture  
Architecture can be observed from various viewpoints. In addition to just evaluating different as-
pects of a material, such as material properties or artistic potentials, there are present aspects, 
which are meaningful in architecture on a wider perspective. The meaningful aspects can be ob-
served from the perspective of an architectural historian (Giedion 2008). The observation can fo-
cus on an architect as designer where different disciplines are present within which architecture 



Journal of Sustainable Architecture and Civil Engineering 2022/2/31
8

operates (Aalto 1978). The topic can be approached from the perspective of values, which affect 
the work of an architect (Ukabi 2015). In addition, the focus can be directed to the framework of 
architectural design (Eilouti 2018). Above mentioned wider perspectives have been compiled in 
Table 1. In that table, the content of each of the above mentioned perspectives have been grouped 
and colour coded to fit the technical, social, human, spatial experience, cultural, economic or mis-
cellaneous sub-frames. The purpose of this list is to facilitate the comparison of different contents 
from broader perspectives, but also to note similarities. 

The most common aspects in these four broader perspectives seem to be related to the social 
and techno-scientific sub-frames. These are present in all of the four above mentioned broader 
perspectives. In addition to these, human and cultural aspects were common as well as spatially 
bound experiences. The economic aspects are present in all perspectives, except in the final per-
spective. In that case, the frame is narrower than the other perspectives, due to a focus on the 
design process. The reason for this might be that economic aspects can be comprehended as 
enablers to the design task. Due to this role, these are clarified prior to the design task.

Table 1
Different aspects 

which are valuable 
or present in 

architecture or 
architects’ work

Sorting or Selecting Materials 

Numerous aspects influence how a material is selected to fit the design needs. These aspects 
have been mapped and studied recently from the standpoint of architecture (Wastiels et. al 2007), 
(Wastiels and Wouters 2008). The aspects are related, for instance, to the material experience. A 
researcher, who works with materials, may not concentrate on the aspects, which are related to 
aesthetic issues or how materials feel to the touch (Wilkes et. al. 2016). Experiencing a material 
is a multisensory experience, where space and time have a role embedded with significances 
(Fujisaki et. al 2015). At a practical level, sensory-related experiences might concern the visuality 
or acoustic aspects of materials. Both aspects can provide spatial feedback of the surroundings 
for the experiencer and are valuable to recognise when selecting the materials for a built environ-
ment. Aspects related to the use or maintenance of materials generate knowledge for the selec-
tion phase, when evaluating if the material is valuable to be selected. In addition, the quality of the 
materials in general and the profitability of the materials in terms of costs are taken into account 
in somehow when the architect selects the materials. The material selection and evaluation can 
focus on the surfaces or the other visible parts of a building. The selection process might focus on 
completing the specific use of a single room with suitable material choices or on a certain need for 
creating a specific atmosphere. In addition, the evaluation can focus on structures, which divide or 
create spaces. Due to these aspects, in the architectural design process, various aspects must to 
be considered at the material level. 



9
Journal of Sustainable Architecture and Civil Engineering 2022/2/31

During the design phase of the construction process, the architect makes decisions when select-
ing unprocessed materials or commercial products composed of certain materials. The materials 
selection of the design phase can be based on a certain frame or criteria. This frame can be facili-
tated to comprehend the entity and demands of the research or development processes. Recently, 
there has been studies on the selection method of an architect or designer (Karana et. al 2008), 
(Wastiels and Wouters 2012) and on the developing tools to aid materials selection (Karana et. al 
2010). The decisions of architects or designers may be based on tacit knowledge, which steers 
the design process forward unconsciously. This tacit knowledge is formed from past experienc-
es. When selecting materials, some decisions are based on reasoning, and those are the results 
of evaluation and comparison. An architect or designer can execute selections with the help of 
material samples provided by manufacturers. In addition to these, the selection can be based on 
previous well-chosen and successful selections. Moreover, materials libraries act as a bridge be-
tween designers and scientists (Wilkes et. al 2016). 

Knowledge Generation and Sharing 
In the design process and constructing phase, various experts from different disciplines are often 
involved. The information exchanged between participants can be shared in the form of various 
types of documents. In that process, the drawings represent one method to share information.  
For knowledge sharing during the construction period of a building, meaningful information can 
be collected in a “Building Description” (Rakennusselostusohje 2015) or “Construction Descrip-
tion” (Rakennustapaselostus 2016). These are both made by utilising text forms. In the field of de-
sign, a more-or-less similar approach is termed the “Product Design Specification” (Rodgers and 
Milton 2011). These documents encapsulate the project in a written format. With their help, the 
information of separate, but meaningful, aspects can be provided to people involved in the project, 
even in the early phases. These documents condense aspects, which are necessary to know even 
when the actual design work has not yet begun. Information collection is important to facilitate 
and frame the design phase. Materials are present in these specifications to some extent, though 
the focus is more on a designed object or building. 

At the material level, several methods to organise, comprehend, and share knowledge are common. 
In particular, these are valuable, when developing new products, evaluating material choices, or as-
sessing the impacts of life cycles. The assistance can be in several forms, such as checklists during 
the product design phase to facilitate the discussion between engineers and designers (Rousseaux 
et. al 2017). When evaluating the effects of materials, selections can be based on favouring green 
choices (Spiegel and Meadows 2010) or following the ISO 14040 standard at Life Cycle Assessments 
(LCA) (ISO 2006). In addition to LCA, which concentrates on minimising environmental impacts, other 
analysis tools can be employed, such as Life Cycle Costing (LCC), which concentrates on costs during 
the life cycle, and Sustainable Life Cycle Assessment (SLCA), which focusses on impacts related to 
socio-economic aspects (Halog et. al 2016). In recent years, the sustainability of materials and mate-
rial cycles have aroused interest among consumers (Peters 2011). The aim is that waste materials, 
agricultural materials, or single-use materials can be taken back into the material loop (Peters 2011). 
For industry, eco-tools are valuable to reduce environmental impacts, when developing process-
es and products. These can be designated into four categories: ‘inventory tools, improvement tools, 
prioritisation tools, and management tools’ (van Berkel et al. 1997). For example, the Materials, En-
ergy, and Toxicity (MET) Matrix is one inventory tool that has been developed to analyse materials, 
assessing their impacts on the environment (van Berkel et al. 1997). In addition, there are several 
eco-design tools which are purely aimed to facilitate choice evaluation within the construction indus-
try (Rousseaux et. al 2017). In addition to the abovementioned, the design phase or process can be 
directed to focus on a certain frame, such as ‘modular design, design for material substitution, design 
for disassembly (DFDA), design for recycling or design for life extension (Ljungberg 2007).



Journal of Sustainable Architecture and Civil Engineering 2022/2/31
10

This paper presents a method to facilitate multidisciplinary materials research and development 
from the viewpoint of architecture. The method is based on different aspects as to how architec-
ture related material research can be framed and later observed. The outcome of the research 
is a flexible chart. The chart can be employed as a tool to generate valuable knowledge for the 
materials research phase. In addition to facilitating materials research, the chart can be used 
creatively as a checklist or a reminder to map various aspects, which must be taken into account 
when materialised outcomes in the research are related in the buildings or living environments. 
The chart can also be utilised to determine the boundaries to the research work in a way that the 
people involved in the process are able to succinctly comprehend the idea of the material. The 
chart can be seen a notebook or classification platform with which to generate remarks on the 
desired material features. Another use of the chart could be to collect important information to 
be shared, such as the building specification utilised in architecture. In this paper, the chart has 
been presented with a case example. With the case example, the aim has been to disclose how 
the knowledge facilitating the research can be produced. 

As previously mentioned, the chart is generated to recognise different viewpoints, which can 
facilitate the mapping and collecting of valuable knowledge for research. The viewpoints are a 
combination of different steps of the material development phases and other diverse aspects, 
which are present in architecture or architectural design. Depending on the focus or demands 
of the materials research or development task, the viewpoints can be narrowed to focus on just 
the essential aspects, or the chart can be utilised as a whole to gain a comprehensive overview, 
especially when the research scope is not yet defined. 

In the chart, the considerations for what is needed to be taken into account, excludes detailed 
technical material properties or manufacturing details. These aspects are important and can be 
discussed in small groups of experts during the development work. In addition, the excluded re-
search areas, which might not get the full benefit of the chart, could include technical materials, 
such as the functional layers in the building envelope, or fittings, such as supplies for HVAC in-
stallations. These might not necessarily possess an important role in the spatial experience from 
the viewpoint of architecture. In generally, the functional material layers are defined by civil engi-
neering, and the materials are hidden inside of the wall structures. The fittings, such as supplies 
for HVAC installations, are usually produced from standard materials. In addition, the materials 
or products are not in general defined by an architect. However, the chart might be beneficial, es-
pecially when mapping knowledge in architecture, when new supplies for HVAC installations are 
developed, or there is a demand to understand detailed technical information of materials.

Structure of the Chart
The chart consists of horizontal and vertical aspects (Table 2). The eight steps in the chart (marked 
1 – 8) present the journey of a material from raw material to the re-use of the material. Horizon-
tally, on the top of the chart, there are placed five aspects, which are present in material develop-
ment (marked A – E). Those aspects are based on Alvar Aalto’s listing within which architecture 
operates (Aalto 1978). The reason for selecting Alvar Aalto’s listing was because the definitions 
were comprehensive enough, but not too complex. In addition, he participated in practical design 
work, and contemplated the relationships between the construction of materials and structures 
in his writings (Aalto 1978). The horizontal aspects indicate how architecture can be approached 
from the viewpoint, which is familiar in the culture of designing and constructing. The information 
discloses views on how an architect observes materials in the built environment. Overall, the 
eight steps in the life cycle of a material, and Aalto’s five-part classification generate 40 different 
valuable aspects as to how materials research in architecture can be observed. 

The objective of the chart is to facilitate research and development phase (A2, B2, C2, D2, E2), 
which is also present at the chart. The gathered information from other 35 viewpoints, excluding 

Results: 
Review 
Method 

Structuring 
Valuable 

Information 
for Research



11
Journal of Sustainable Architecture and Civil Engineering 2022/2/31

the mentioned five horizontal thematic areas of Research and Development phase, are fed into 
this phase. In addition, at the research and development phase it is possible to generate knowl-
edge various aspects related to materials. At this point, the chart can aid in identifying boundaries 
and limitative aspects. 

Vertical Thematic Areas

The vertical thematic areas include eight steps. Each of the steps presents a different phase in the 
life cycle of the materials. The aim of this has been to divide the life cycle of the materials into small-
er parts for more specific observations. Due to this, more detailed and focused knowledge can be 
generated to facilitate research. The vertical thematic areas during the material life cycle are: 

Table 2
The chart presents the 
vertical and horizontal 
aspects within which 
architecture operates 
during the life cycle of the 
material. The research 
and development phase 
is highlighted in the table 
(A2, B2, C2, D2, E2)

1. Raw Material,

2. Material Research and De-
velopment, 

3. Product,  

4. Commercialisation, 

5. Use,  

6. Maintenance, 

7. End use, 

8. Re-used Raw Material. 

The first phase, Raw Material, consists of simple processes prior to delivering the material for 
sale or further developed raw material. Material Research and Development is the phase to which 
the work of this paper is aimed—to facilitate research by collecting valuable information gener-
ated with the help of the chart. At this stage, the research work can be executed at universities, 
research institutes, or commercial companies. The research work can vary due to the objectives, 
research material, and research facilities of the interested parties. The knowledge generation in 
the Research and Development phase can be related to mapping research facilities, suitable tests, 
research methods, or the desired skills of the researchers. In the Produced phase, the knowledge 
generation can be related to the qualities and requirements of the end use of the material before 
the material is launched onto the markets. In the Commercialisation phase, the potential chal-
lenges and boundaries of the material are discussed when the material is developed for the mar-
ket, or the material is part of a commercial product. In the Use phase, the knowledge generation 
is related to daily life and use of the material, and in the Maintenance phase, an understanding can 
be generated as to the serviceability of the material. At the end of the material life cycle, there are 
possibilities to generate knowledge of the potential end uses of the material. If the material can be 
utilised as a raw material again, the aspects can be pondered in the Re-used Raw Material phase. 
At best, the material life cycle and knowledge generation may start again in the first phase, Raw 
Material, and the material loop is closed. 



Journal of Sustainable Architecture and Civil Engineering 2022/2/31
12

Horizontal Thematic Areas

In the horizontal thematic areas, the materials can be classified into five different aspects for 
observation. This division is based to Alvar Aalto’s notions of the aspects which are present in 
architecture. The division was selected because it is general enough to fit the scheme of multi-
disciplinary material research, and flexible enough to include different considerations, which the 
constantly evolving field of architecture faces intermittently. The horizontal thematic areas include 
the following:

A. Technical Aspects, 

B. Human Aspects, 

C. Psychological Aspects, 

D. Social Aspects,  

E. Economic Aspects. 

In this study, the technical aspects include the measured data of materials, and methods for how 
to process materials. In addition, these include interpretations and evaluations on a general level, 
such as how the material can tolerate water. This section can generate knowledge as to how the 
material can be modified, or what kind of technical knowledge is valuable. In addition, it is possible 
to consider manners, tasks, practicalities, methods, or machines. Moreover, any necessary or 
existing technical information can be discussed in this section. Valuable knowledge can be gen-
erated if the emphasis is on how the technical aspects fit the demands of research, development, 
or design. The desired information might be applied on a wider basis than in the regular technical 
data sheets or process overviews. In addition, the information may be tied to design practices. 
The information outside of the technical data sheets might deal with aspects, such as moisture 
sensitivity, weathering, wearing, and tearing of the material. Aspects included in the technical 
thematic areas are wide and extensively present in architecture. Human, psychological, social, 
and economic aspects are present in materials, but they might not have been studied that widely 
compared to the technical aspects of materials from the viewpoint of science. In Human Aspects, 
the safety of the material and its adaptation to human use can be considered. In Psychological 
Aspects, the materials can be observed from the viewpoint of material experiences. The focus 
here can be on how the material affects the experiencer or experienced space, noting that the 
experiences are personal. Sensing the material through touch or experiencing the space where 
the material is utilised might be worth considering in order to ascertain if the material is optimal 
for a given purpose. When thinking of the relationship between material and society, there might 
also be a demand to consider themes, such as how the material fits to the existing culture and tra-
ditions and how the material adapts to living environments in general. The wise use of resources 
could be included as the focus of the last section, Economic Aspects. 

Review Process 
Material development is a long-lasting process influenced by various aspects. Thus, the aim of the 
review method is not to create a permanent structure but an active review method, which varies 
depending on the different material research tasks, end-use visions, frames where the material 
would be used, and disciplines of the persons involved. Due to this lively nature, the focussed 
observation areas can be narrowed very tightly, if the observed areas are desired to be specific. 
The observation areas can be selected according to needs, such as product from the viewpoint of 
psychology, use of the material from the viewpoint of society, or maintenance of the material from 
the viewpoint of economy. In turn, the observation points can be selected for only a certain phase 
of the material life cycle, such as maintenance observed from all five horizontal thematic areas in 
which architecture operates. 

Consequently, the direction of the observation can generate different knowledge. The chart can 
be observed from raw material towards products, where the starting platform is wider, due to 
delimiting knowledge. From the opposite side, the chart can be observed according to the de-
mands of the use phase towards raw materials. In this case, the aim is to curate the right material 



13
Journal of Sustainable Architecture and Civil Engineering 2022/2/31

to be developed among the draft materials. The demands of use-phase visions limit and frame 
the material research. Due to these aspects, the observation direction from the material towards 
products, or in the reverse order, can generate different results. 

The process starts by defining the preliminary research approach. In the process, all 40 aspects or 
selected aspects according the defined research approach are present. In the selected scope, the 
framing can be limited, such as A. Technical aspects and 3. Product, which generates a narrower 
view to understand these valuable aspects. The knowledge here is generated with the help of 
questioning. The nature of the question – answer – question method is mostly achieved through 
debate, where the aim is to encourage knowledge to emerge. The reason for this method is that 
most of the information regarding the scientific research might be clear for the professionals in 
specific areas but opaque to all other participants. The knowledge might not be visible at all, or 
the knowledge exists as tacit knowledge. Due to nature of tacit knowledge, it can be difficult to 
share with others. With the help of the systematic method presented in the article, the knowledge 
has a better possibility of being revealed and shared. After answers have been generated, the final 
focus on the narrow topic may reveal a more accurate comprehension. After that, the generated 
information can be fed into the research and development process of the material. This final phase 
provides advice on how to proceed further. (See Table 3). 

Table 3
Process for 
utilising the 
chart



Journal of Sustainable Architecture and Civil Engineering 2022/2/31
14

Increasing Knowledge with Questions

In the review process, the research data is collected in the requisite frames, or all 40 aspects, with 
the help of question generation. The objective is to return the strictly limited and framed knowl-
edge back to the materials research to facilitate discussion. In addition, the aim is to generate 
research objectives more comprehensively. The first question round is generated to survey and 
study the material whilst further questions, if needed, can generate more specific knowledge. If 
the chosen method of observation in the first step (see Table 3) is chosen to be very narrow, as 
the material produced is observed at the intersection of psychology (C. Psychology - 3. Product, 
see Table 2), the questions can be related to the experiences, which the material awakens, when 
experiencing the material as a spatial experience in the proposed physical space. On a practical 
level, the outcomes of the questions can be notions that the material muffles or reflects sounds; 
both of these affect the acoustic experience. When developing answers for the questions gener-
ated for the second round, the outcomes may be that the acoustic properties might need some 
improvements during the research phase. As a result of the process, more specific knowledge 
can be generated to serve the material development. On a practical level, the observation could 
concentrate on how to adjust or improve the acoustic properties when additives are planned to be 
mixed into the material. 

Evaluation: 
Testing 
Review 
Method

The review method has been tested in practice by evaluating an early phase material research 
studies. In this practical test, the perspective where the questions have been approached involves 
the research material cellulose. The preliminary objective of the cellulose research includes knowl-
edge generation of the potentials of this abundant material for new research openings. Among 
several material cases, Foam Material was selected to reveal the method presented in this paper  
(Fig. 1). The sketch material reveals how the method can be utilised if evaluating the potentials of 
early stage materials research. The selected Foam Material has been developed during Design Driv-
en Value Chains in the World of Cellulose, DWoC 2.0 research project, 2015 –  2018. 

Cellulose is a material which appears as a structural material in plants or tree trunks. The cellu-
losic materials are derived from renewable resources and are inherently biodegradable. The raw 
material of this case study is wood-based cellulose. In architecture, cellulose as a material in 
products has been utilised in insulation materials or building papers. 

The review method has been preliminarily tested with one DWoC 2.0 material research case. The 
results of three other DWoC 2.0 cases were presented in a short conference paper at the Proceed-
ings of the Nordic Wood Biorefinery Conference (Turunen 2018). In the conference paper of the con-
ference proceedings, the cases have been observed in either a bottom-up approach from materials 
towards products or vice versa in a top-down approach. In this study, the life cycle of the material is 
widened to cover raw materials and re-used raw materials. The case study of Foam Material was 
observed from one vertical aspect A. Technical aspects, but in all the life cycle stages of the material 
from 1. Raw material to 8. Re-used raw material. The purpose of the evaluated case study presented 
in this article is to reveal general information to assist the architect in the early stages of the material 
development. Due to this, the views on how questions are created have been based on the approach 
and mind set of architects. If the observer would represent another field, the questions and infor-
mation collected would have a different emphasis. In both observation tasks, however, the results 
of the inquiry are tied to architecture and facilitate research and development of architecture-related 
materials, regardless of the evaluator’s background. The reason for this is that the framing directs 
the process to stay within the boundaries of the architecture.

Research Material Case   
In this article, the method is evaluated with a material sample, where cellulose was foamed and 
then compressed into stiff boards. The foamed material may be utilised as a structural material. In 



15
Journal of Sustainable Architecture and Civil Engineering 2022/2/31

this study, the material has been modified by patterning the material, printing on the material, and 
shaping the material with a commercial water jet cutter. The material samples were early phase 
sketch materials, anticipating future research in the field of architecture. With the assistance of the 
review method, the material cases were studied, which in turn generated a deeper knowledge. 

Fig. 1
Foamed Material on the 
right: patterned foam, 
printed foam, water 
jet-cut foam, and foam 
utilised as a structural 
material.  
Photos Eeva Suorlahti

 
 

phase is aimed at collecting information on how the research can proceed further. This means gathering information on what 
kinds of knowledge, tests, or processes might be beneficial to serve the research. In the fourth phase, more knowledge was 
generated utilising more specific questions, notions, and comments. The second round of questions is not necessary if the 
first phase managed to generate enough information regarding the material. In the case of foam material, the second 
question round can be related to map specific technical methods how to obtain information, such as defining next steps 
when measuring air permeability.  
 
 
 
 
 

 

Foamed Material, 2017-2018 

Team: Heidi Turunen Aalto, Jani Lehmonen VTT

Soft cellulose foam has been pressed to make stiff boards. The density of the boards is adjustable. The 
bending stiffness of the material has been tested to be 2.95 ± 0.43 MPa, which turned out to be better 
than commercial peeled plaster board. The bending stiffness of the plaster board was 1.13 ± 0.13 MPa. 
In addition, when comparing the maximum deflection of foamed material to peeled plaster board, 
the measure of the foamed material was 14.45 ± 0.38 mm, and plaster board just 0.5 ± 0.1 mm. The 
foamed material boards can be post-processed in various ways. In this research, patterns have been 
pressed on the foam. A commercial printer has been tested to print thin lines. The aim of the printing 
was generating knowledge how ink spreads on top of the board. The printing quality was superior. In 
addition, the material was tested on water jet cutter. The quality of the cutting edge was sharp, and 
material did not absorb water. A 1:1 scale sample was made to present an early phase sketch, if the 
foamed material could be considered to replace gypsum boards. Future application areas for foamed 
materials could be in indoors, where stiff boards are required in vertical or horizontal applications, and 
where it is desirable for the material to be recyclable, reusable and bio-based. 

Review Process
In the chart, all 40 aspects were tested to fit cellulosic research. In this preliminary study, the 
foamed material was observed from raw material towards products, meaning that the end use of 
the material was not defined. Due to this, the scope of the future application areas was wider than 
if reviewed the other way round. The results presented in this paper were limited to cover A. Tech-
nical aspects from the horizontal thematic area, and 1. Raw Material to 8. Re-used Raw Material.

Results of Testing
The knowledge is possible to assort with help of the assistance of 40 different viewpoints. The 
chart follows four phase paths (Table 3).  In the case of the foam material, only selected aspects 
are shown, the journey of the material from a technical point of view. In this article, the first round 
of questions is presented using simplified concepts marked in the table (Table 4). 

An example of a simplified concept is; available technical information (A3) and the question; what 
are the available technical information of the foamed material (see also Table 3). After that, in the 
third phase, the answers are created according to the questions. The answers were, for example, 
the high air permeability of the material. The fourth and final phase is aimed at collecting infor-
mation on how the research can proceed further. This means gathering information on what kinds 
of knowledge, tests, or processes might be beneficial to serve the research. In the fourth phase, 



Journal of Sustainable Architecture and Civil Engineering 2022/2/31
16

more knowledge was generated utilising more 
specific questions, notions, and comments. The 
second round of questions is not necessary if 
the first phase managed to generate enough 
information regarding the material. In the case 
of foam material, the second question round 
can be related to map specific technical meth-
ods how to obtain information, such as defining 
next steps when measuring air permeability. 

In the case of the foam material, the first round 
answers have been analysed, and the con-
densed information has been summarised be-
low briefly in written form to provide an impres-
sion of the type of gathered information.

Foamed material 

A. Technical Aspects: 1. Raw Material to 8. 
Re-used Raw Material

Technical aspects: When evaluating the foamed 
material with the help of the chart, it is worth 
noting that the production processes of the 
Raw Material (A1) can be relatively simple and 
well known, but the limitative aspects need to 
be mapped from the viewpoint of architecture. 
These can include aspects, such as the quality 
of the product as well as amounts of the po-
tential production volumes. These consider-
ations as to whether the material is wise to use 
from the standpoint of material properties are 
important to recognise at an early phase. For 
example, there is a notion in foam material that 
cellulose tends to get wet easily. On a practi-
cal level, the foamed material in this case has 
been analysed from the viewpoint of process-
ing possibilities. These processes were water 
jet cutting, printing, pressing patterns, and con-
structing three-dimensional structures. When 
analysing the cases with the help of the chart, it 
was clear that more testing of the processing of 
the material is required. In addition, identifying 
the limitations and studying, for instance, the 
customisation potentials of the material would 
be beneficial to comprehend the potential end 
uses. In the Product phase (A3), it is possible to 
identify the technical properties of the materi-
al. In the foam material case, these can include 
water tolerance, fire resistance, UV-resistance, 
surface sensitivity, chemical resistance, and the 
potential external dimensions of the material. 

Table 4
 In the chart, it is possible 

to select certain aspects 
or utilise the whole chart 

for knowledge generation 



17
Journal of Sustainable Architecture and Civil Engineering 2022/2/31

In this phase, it is possible to generate preliminary information of the tests, which are required 
to ascertain the potentials of the material on a technical level. In addition, it might be valuable at 
this phase to consider how the variations of the customisation possibilities might serve various 
end-products. When materials are aimed at commercialisation, various aspects must be clarified 
prior to that. Information for that phase can be generated with the help of the frame Commercial-
ization (A4). The mapped data can increase the reliability of the material, when evaluating suitable 
end uses. In the case of the foam materials, the potential information for the technical datasheets 
or design principles may help guide the research and development phase to comprehend the 
material potentials. In the Use phase (A5), information of a certain scenario can be generated 
as to how the material is expected to be utilised, allowing researchers to feed the resulting in-
formation into the research phase. The scenarios regarding how to use the foam material may 
lead researchers to consider aspects, such as the potential accumulation of dirt and dust on top 
of the relatively soft and fibrous material. In this phase, it might be wise to consider if unwanted 
additives or chemicals may be released during the use of the material. The gathered information 
can be fed into the research and development phase, where improvements and testing can be 
performed in anticipation of these concerns. Feedback from the Maintenance phase (A6) to the 
research and development phase would include knowledge generation of cleaning possibilities 
and the limitations, which the material sets for the maintenance customs. In the case of foamed 
material, cleaning with a wet cloth is not practical and requires consideration in the research and 
development phase if cleaning is desired in the maintenance phase. Similarly, replacing broken 
or worn material can be considered in this phase. The consideration here is related to the repair 
methods or the possibilities for affixing a replacement. In the End Use phase (A7), the consistency 
of the material can be considered from the viewpoint of potential re-use, and this information can 
be fed into the research and development phase. The aspects considered in the case of foamed 
material may be concentrated on noting the potential additives or chemicals planned for inclusion 
in the material. Additives or chemicals might prevent or complicate re-use or recycling of the 
material. This is due to the fact that separating the ingredients in the material may be difficult, if 
materials are merged together, for example chemically. In addition, additives or chemicals may 
disrupt the biodegradability. In the early phase of the material development, the notion that the 
foamed material may be recycled among newspaper waste was considered from the viewpoint of 
additives. The last observed phase, Re-used Raw Material (A8) generates knowledge as to where 
and how the material can be re-used, and what must be considered when returning the material 
back into the material loop. In the case of the foamed material, re-use among composites might 
be a valuable aspect to consider.

Discussion
Different material research and development cases can vary significantly due to the researched 
materials, processing methods, facilities, end applications, and customs in the materials research 
and development phase. However, tools have been developed to steer the process in the desired 
direction. The tools are often related to understanding and analysing material impacts from the 
viewpoint of environmental issues and sustainability. In architecture, the design processes tend to 
be complex due to unique outcome of the buildings in a living environment and the different de-
mands of the users. In addition, the aspects are bound to cultures and practices. The nature of the 
designed outcomes is often one-off or even experimental. In human-related aspects, the interpre-
tation is dependent on a designer, user, or experiencer. Contemplating the previously mentioned 
aspects, gathering precise information might not be a clear process to filter the information back 
to the phases of materials research and development. 

Thus, the objective of this paper is to generate a tool to facilitate materials research and develop-
ment. The tool is observed from the viewpoint of architecture, but it is not designed to make the 
role of an architect unnecessary. Understanding the aspects included in architectural design is a 



Journal of Sustainable Architecture and Civil Engineering 2022/2/31
18

long learning process, where architects reflect their personal history, experiences, and learnings 
from previous design tasks. Due to this, it cannot be assumed that all valuable information could 
be filtered to serve materials research and development solely with the help of this review meth-
od. Instead, the focus is to open the mindset of the participants to versatile approaches, where 
architecture and materials can merge, and to facilitate effortless interactions with the participants 
of the research. Otherwise, the use of the chart might be a superficial shortcut, lacking in depth. 

The primary assumption of the chart is that the materials would come back into use in a loop. This 
can be taken into account in the material design phase. While the materials involved in architec-
ture might not return to serve only architectural applications later on, they can be utilised in other 
product fields as a new raw materials. Due to this, it might be wise to survey other potential re-use 
possibilities at an early stage of the material research and development, not just those which are 
related to architecture or the construction industry.

In recent years, material selection has broadened in architecture, resulting in the inclusion of 
various disciplines in the research and development process. Given these developments, this 
paper focusses on a tool for recognising aspects, which might be beneficial when researching and 
developing materials for use in architecture. The focus of the study has been aimed especially at 
projects in which various disciplines are included. In terms of the role of the architect, the focus 
has been on which aspects an architect emphasis when performing a design task or when de-
fining materials or products for use. The result is a systematic tool for knowledge generation to 
facilitate discussion during materials research and development. The principles of the tool mirror 
the aspects, which architects focus on and favour when evaluating suitable choices during the 
construction process or prior to that, and it simultaneously identifies what kind of information is 
valuable to notice. The aim of the tool has been to return the information back into the materials 
research or development phase. With the help of the chart, it is possible for all to comprehend 
different viewpoints related to the materials life cycle.

The chart consists of 40 viewpoints related to how materials research or development can be 
approached. These viewpoints are generated from the horizontal aspects, which are considered 
vital in architecture. Based on Alvar Aalto’s notions, these horizontal aspects include the cate-
gories of technical, human, psychological, social, or economic aspects. In contrast, the vertical 
aspects focus on the life cycle of the materials. The vertical viewpoints are different stages of the 
life cycle: raw material, material research and development, product, commercialisation, use, 
maintenance, end use, and re-used raw material. The chart has been tested with an early stage 
material research project, where the case material is foamed and pressed cellulose.  

The practical application of the chart presented in this paper is to facilitate knowledge generation 
for material research and development when developing new or recycled materials for architec-
ture. In other words, the researched material might contain great potential, but the view is narrow, 
or the product exists, but a suitable material is not yet available. In both cases, knowledge gen-
eration allows for a more comprehensive comprehension of the demands before the start of the 
research and development phase. In addition, the chart can assist researchers in comprehending 
aspects-related materials research and development. This utilisation is similar to how a building 
specification document facilitates architectural design. As well, the chart can be utilised as a flexi-
ble tool to reveal the necessities of a certain material from different viewpoints. The chart can also 
be employed as a checklist to survey valuable aspects to facilitate research and development. 
Further studies related to the topic could concentrate on the 40 frames. These considerations 
may be related to how valuable and meaningful information can be revealed more accurately. In 
particular, when there is demand to adapt various end uses, properties, or qualities of materials 
for the practical work of research and development.

Conclusion



19
Journal of Sustainable Architecture and Civil Engineering 2022/2/31

Acknowledgements
This work was supported by Tekes, The Finnish Funding Agency for Technology and Innovation 
(currently Business Finland), and the Finnish Cultural Foundation: Kalle ja Dagmar Välimaan Ra-
hasto and Suomen Hypoteekkiyhdistyksen Rahasto.

Aalto A (Schildt G ed.), Sketches. Cambridge (Mass.): 
The MIT Press; 1978. p. 60-61, 97.

Antonelli P (foreword), Myers W. Bio Design: Nature, 
Science, Creativity. New York: Thames & Hudson; 
2014. p. 7.

Ballard Bell V, Rand P. Materials for Design. London: 
Princeton Architectural Press; 2006. p. 10.

Ballard Bell V, Rand P. Materials for Design 2. New 
York: Princeton Architectural Press; 2014. p. 8.

van Berkel R, Willems E, Lafleur M. Development of 
an industrial ecology toolbox for the introduction of 
industrial ecology in enterprises. Journal of Clean-
er Production, 1997; 5 (1-2): 12-13, 14. https://doi.
org/10.1016/S0959-6526(97)00004-8

Eilouti B. Concept evolution in architectural de-
sign: an octonary framework. Frontiers of Archi-
tectural Research, 2018; 7: 190-191. https://doi.
org/10.1016/j.foar.2018.01.003

Fujisaki W, Tokita M, Kariya K. Perception of the 
material properties of wood based on vision, au-
dition, and touch. Vision Research, 2015; 109: 185. 
https://doi.org/10.1016/j.visres.2014.11.020

Giedion S. Space, Time and Architecture, The 
Growth of a New Tradition. Cambridge, Massachu-
setts, London, England: Harvard University Press; 
2008. p. 19, 165.

Giesekam J, Barrett J R, Taylor P. Construction sec-
tor views on low carbon building materials. Building 
Research and Information. 2016; 44 (4): 425. Ac-
cessed 20.2.2011. https://doi.org/10.1080/096132
18.2016.1086872

Gulling D K. Manufacturing Architecture: An Archi-
tect’s Guide to Custom Processes, Materials, and 
Applications. London: Laurence King Publishing; 
2018. p.13.

Halog A, Manik Y, Atwood D (ed). Life Cycle Sustain-
ability Assessments. Sustainable Inorganic Chem-
istry. John Wiley & Sons Ldt.; 2016. p. 27. https://
doi.org/10.1002/9781119951438.eibc2372

Hirshinger Q, Ternaux E, Blokland T. (ed). Material 
World 2. Innovative Materials for Architecture and 
Design. Amsterdam: Frame Publishers, Basel: 
Birkhäuser; 2006. p 24.

ISO 14040:2006. Environmental management - Life 
cycle assessment - Principles and framework. ISO 
International Organization for Standardization.

References
Karana E, Hekkert P, Kandachar P. Material con-
siderations in product design: A survey on crucial 
material aspects used by product designers. Mate-
rials and Design 2008; 29: 1081-1089. https://doi.
org/10.1016/j.matdes.2007.06.002

Karana E, Hekkert P, Kandachar P. A tool for mean-
ing driven materials selection. Materials and Design 
2010; 31: 2932. https://doi.org/10.1016/j.mat-
des.2009.12.021

Ljungberg L Y. Materials selection and design for 
development of sustainable products. Materials and 
Design 2007; 28: 475. https://doi.org/10.1016/j.
matdes.2005.09.006

Mordaunt Crook J. The Dilemma of Style, Architec-
tural Ideas from the Picturesque to the Post-Mod-
ern. London: John Murray Ltd.; 1987. p. 11

Peters S. Material Revolution - Sustainable and 
Multi-Purpose Materials for Design and Architec-
ture. Base: Birkhäuser; 2011. p. 7, 9. https://doi.
org/10.1515/9783034610773 

Rakennusselostusohje, Talo 2000 (building descrip-
tion), RT 15-11176 (KH 96-00565). Helsinki: Raken-
nustieto; 2015. p. 1-24.

Rakennustapaselostus, Talo, 2000 (construction 
description), RT 15-10863. Helsinki: Rakennustieto; 
2016. p. 1-6.

Ritter A. Smart Materials in Architecture, Interior 
Architecture and Design. Basel: Birkhäuser; 2007. 
p. 8.

Rodgers P, Milton A. Product design. London: Lau-
rence King Publishing Ltd.; 2011. p. 85-91.

Rousseaux P, Gremy-Grosb C, Bonnin M, Henri-
el-Ricordelc C, Bernard P, Flourye L, Staigref G, Vin-
cent P. „Eco-tool seeker“: A new and unique busi-
ness guide for choosing ecodesign tools. Journal of 
Cleaner Production 2017: 151 (546-577): 551, 570. 
https://doi.org/10.1016/j.jclepro.2017.03.089

Spiegel R, Meadows D. Green Building Materials: 
A Guide to Product Selection and Specification. 3rd 
Edition. John Wiley & Sons, INC. 2010.

Turunen H. NWBC 2018: Proceedings of the 8th Nor-
dic Wood Biorefinery Conference. VTT Technology 
340. Espoo: VTT Technical Research Centre of Fin-
land; 2018. p. 75-78. Accessed 20.3.2022. Available 
from www.vtt.fi/inf/pdf/technology/2018/T340.pdf



Journal of Sustainable Architecture and Civil Engineering 2022/2/31
20

About the 
Author

This article is an Open Access article distributed under the terms and conditions of the Creative 
Commons Attribution 4.0 (CC BY 4.0) License (http://creativecommons.org/licenses/by/4.0/).

Ukabi E. Conserving the Architects’ Jewel in the 21st 
century. Frontiers of Architectural Research 2015; 5 
(1): 12.

Wastiels L, Wouters I. Architects‘ considerations 
while selecting materials. Materials and Design 
2012; 34: 584-593. https://doi.org/10.1016/j.mat-
des.2011.05.011

Wastiels L, Wouters I. Material Considerations in 
Architectural Design: A Study of the Aspects Iden-
tified by Architects for Selecting Materials. Undisci-
plined! Proceedings of the Design Research Society 
Conference 2008, Sheffield Hallam University, Shef-
field, UK, 16-19 July 2008; 2009; 379: 1-13. Accessed 

20.3.2022. Available from https://core.ac.uk/down-
load/pdf/100022.pdf

Wastiels L, Wouters I, Lindekens J. Material Knowl-
edge for Design - The Architect’s Vocabulary. Pro-
ceedings of IASDR 07, IASDR 2007 International As-
sociation of Societies of Design Research, Emerging 
Trends in Design Research, Hong Kong, November 
12-15, 2007: 2007:. 1-16.

Wilkes S, Wongsriruksab S, Howesc P, Gamestera R, 
Witcheld H, Conreene M, Laughlina Z, Miodownik M. 
Design tools for interdisciplinary translation of mate-
rial experiences. Materials and Design 2016; 90: 1228. 
https://doi.org/10.1016/j.matdes.2015.04.01 

HEIDI TURUNEN 

Aalto University, Department of Architecture,  
School of Arts Design and Architecture

Adress
Otaniementie 14, 02150 Espoo, Finland
Tel. +358 40 536 0880
E-mail: heidi.turunen@aalto.fi