15
Journal of Sustainable Architecture and Civil Engineering 2021/1/28

Political Economy of Straw 
Houses: Traditional and 
Contemporary Way of Enhancing 
Sustainability of the Buildings

Received  
2020/09/29

Accepted after  
revision 
2020/12/22

Journal of Sustainable 
Architecture and Civil Engineering
Vol. 1 / No. 28 / 2021
pp. 15-25
DOI 10.5755/j01.sace.28.1.27711

Political Economy 
of Straw Houses: 
Traditional and 
Contemporary 
Way of Enhancing 
Sustainability of the 
Buildings

JSACE 1/28

http://dx.doi.org/10.5755/j01.sace.28.1.27711

Introduction

Cities, as production and consumption hubs, cause significant amount of global CO2 emissions and energy 
consumption. Climate change challenges world’s welfare due to the global warming. Cities’ environmental 
footprint can be reduced with the help of energy efficient and sustainable built environment which can further 
contribute to the wellbeing and welfare of the urban population contributing to the solution of the fuel poverty. 
Straw is a traditional and contemporary material having outstanding technical characteristics (e.g. thermal 
insulation). Straw is a traditional material as it has been used in sheltering starting from the ancient times. 
Straw is a contemporary material as it is used even in small buildings with the help of innovations. Furthermore, 
it is a cost effective material from initial investment as well as maintenance and repair aspects. Straw houses 
can reduce energy consumption. This can reduce countries’ trade deficit due to the reduced demand for energy 
import, contributing to the solution of the fuel poverty. Straw is environmental friendly natural material. 
Constructing straw houses is important for sustainable living. Giving importance to the straw house construction 
can help reduction in the CO2 emission and in the energy consumption. Based on an in-depth literature review, 
this paper investigates political economy of straw houses and straw houses’ contribution to the sustainability 
performance of the built environment. This paper introduces to the literature political economy of the straw 
houses and provides recommendations on how to widespread the use of straw houses.

Keywords: energy, environment, housing, politics, political economy of straw houses.

*Corresponding author: egemens@alumni.bilkent.edu.tr

Egemen Sertyesilisik*
Gozuyilmaz Engineering and Marine Industries Ltd., Izmir, Turkey

Seyma Yilmaz
Cevher Cam, Sumer Mah. Denizli, Turkey

Begum Sertyesilisik
Izmir Democracy University, Faculty of Architecture, Department of Architecture, Izmir, Turkey

As none of the countries has unlimited financial power, efficient allocation of budget is important 
to generate welfare and to enable sustainable development. Climate change has started to chal-
lenge world’s welfare. Effective fight against the climate change requires interdisciplinary action 
due to its consequences. Consequences of the climate change have started to become a threat 
for rights (Levy and Patz, 2015). Wallimann-Helmer (2019) has emphasized the importance of the 
justice in managing climate change. Especially, thanks to the Kyoto Protocol and Paris agreement 
many countries come together to reduce their CO2 emissions, and to reduce their environmental 
footprint. At this stage finding solution to unsustainable urbanization can support fight against cli-
mate change. Even if cities cover approximately 2% of the land surface of the world, they consume 
majority of energy and emit 75% of CO2 (United Nations, 2014; Sertyesilisik & Sertyesilisik, 2015: 



Journal of Sustainable Architecture and Civil Engineering 2021/1/28
16

83). The building sector’s consumption of 40% of main energy usage is a sample for Levermore 
(2008)’s statement who indicates that the built environment consumes big amount of energy and 
material (Levermore, 2008). European Union’s targets for 2020, 2030 and 2050 regarding re-
duction in the greenhouse gas emissions and increase in the energy efficiency (European Union 
website, n.d.) emphasize need for and importance of improving sustainability performance of the 
built environment. Construction of environmental friendly houses like straw houses can reduce 
environmental harm caused by the construction industry (CI) and the built environment. Straw 
houses can contribute to the protection of the world’s resources and for enhancing sustainability 
performance of the built environment. Furthermore, straw houses can contribute to the circular 
economy as they enable waste material to be used as an input.

Political economy of straw/straw houses is related with the political economy of sustainability and 
sustainable development. The three pillars of sustainability and political economy are interrelated. 
Sustainability is an important topic of the global political economy (The World Bank, 1982; Loshaj, 
2016). Global environmental policies’ topic can be covered by the global political economy which “…
is the politics of international economic activities” (e.g. trade, international politics on economic inte-
grations, etc.) (Goldstein & Pevehouse, 2015: 371). Political economy is also concerned with the sus-
tainable development as it is related with “… determining what political and/or economic factors … 
are restricting the courses of action toward sustainable development” (Branco, 2008; Rogers & Boyd, 
2008; Loshaj, 2016: 5). Straw and straw houses can have potential to contribute to the establishment 
of the sustainable built environment and to the solution of the fuel poverty problem. Based on an 
in depth literature review, this paper investigates the political economy of straw houses and straw 
houses’ contribution to the sustainability performance of the built environment.

Traditional  
and 

Contemporary 
Usage of  
Straw in 
the Built 

Environment

Although straw has been used in construction since the Paleolithic Age (Langlois, 2017), straw 
gained its popularity in late 1800s with the invention of baling machines (Steen, Steen, & Bain-
bridge, 1994). Similarly, straw houses have been widespread in Nebreska due to the scarcity of 
other building materials (Amazon Nails, 2001) and they date back to 1800s as they are durable 
(Nunan, 2010). Contribution of the straw bale’s usage as a construction material to the reduction 
in the housing costs has further resulted in widespread use of the straw houses (King, 2006; 
Offin, 2010). Straw houses are cost effective as straw is easy to find and construct (Magwood, 
2014) Straw is a widely available material. For example, in North America, the amount of straw 
produced annually is enough for residential building construction (Garas, Allam, & El Dessuky, 
2009). Apart from residential architecture, many churches, schools, and community and youth 
centers have been constructed by people who will take advantage of the building to be built (Mag-
wood, et al., 2005). Thanks to the different-sized modular units, the usage of straw bales could 
reduce buildings’ construction time period, and the construction waste (Walker, Thomson & Mas-
kell, 2016). Furthermore, its construction technique is basic and it enables design flexibility (King, 
2006). Research in the field of different usage of straw further contributes to its widespread [e.g., 
the ‘ModCell®’ (Balehaus at bath n.d.; Guarneri, 2014: 732; ModCell, n.d.].

Nowadays, there are ongoing attempts to construct eco-friendly buildings with biodegradable and 
renewable building materials because of the depletion of the sources and deteriorated world habitat. 
Kołakowski (2005) stated that straw, which is a raw, traditional and grown naturally material, is one 
of these building materials (Jagielak, 2015: 1). Amazon Nails (2011) indicates that approximately 
1000 new structures per year are built in the world. Furthermore, Prof. Rueger prepared a map in 
2010 which shows that there are approximately 700 straw bale dwellings in France, 150 in Germany, 
and 104 in Austria (Atkinson, 2010). Straw is used both in traditional and contemporary ways.

Traditional Usage of Straw: Traditional construction with straw bales can be pointed off under 3 main 
types: load-bearing systems as in Nebraskan style, non-load-bearing systems, and hybrid systems 



17
Journal of Sustainable Architecture and Civil Engineering 2021/1/28

(Magwood, Mack, & Therrien, 2005). Load bearing system is the original one which was firstly used 
by the Nebraskan settlers in the USA (Jones & Breese, 2009). The bales are pinned to foundation and 
to each other to be able to carry the wooden roof structure (Magwood, 2014). Walker, et al., (2016) 
indicated that the original usage way of the straw bale is still an effective way for low-rise build-
ings. Moreover, if straws are baled, massed, elaborated, and plastered with any earthen renders, 
they could bear residential scaled loads (Bendapudi, Potnuru, Varanasi & Saha, 2012). One of the 
most important advantages is simplicity of its execution. This method is the easiest way for building 
load bearing structure as the non-professionals can build their small scale building with the help 
of basic guides (Myhrman & MacDonald, 1997). Another advantage of this method is less usage of 
wood or steel in the construction (Wilson, 1995). The second method is the non-loadbearing system 
where wood, steel or concrete frameworks carry the roof whereas the bales act as an infill material 
(Jagielak, 2015). In other words, load-bearing mission is transferred to column and beams, thereby, 
bales turn into just an infill material for the structure. In this method, it is possible to prevent the 
straw bales from being affected by adverse weather conditions by starting construction from the 
structural system and roof (Walker, et al., 2016). Even if the high insulation properties of straw are 
utilized in this method, this method is less sustainable compared to the first one due to the need for 
large amount of timber/steel (Amazon Nails, 2011). In the third method which is the hybrid method, 
the most suitable features of the previous two methods are used as straw bales act as a bearer with 
the main structure, and at the same time provide design flexibility (Magwood, et al., 2005). Apart 
from these methods, bales can be used as flooring and ceiling material with their high insulation 
properties (Atkinson, 2010).

Contemporary Usage of Straw: Nowadays, different methods are being researched to use the straw 
bale more efficiently and to spread the usage area. Prefabricated panel systems could be shown 
as an example of these researches. Researchers at the University of Bath’s Building Research Es-
tablishment (BRE) Centre for Innovative Construction Materials had developed new ways of using 
straw bales for construction which is ‘ModCell®’(Balehaus at Bath, n.d.). In this system, which is 
developed based on the prefabrication method, the straw in the timber frames makes use of the fast 
and flexible design of modularity (ModCell, n.d.). It is seen that straw has expanded its usage area in 
contemporary architecture with this prefabrication method, which can be used in the construction 
of many structures which all have different scales and flow schemes such as school buildings (e.g., 
Glenfrome Primary School, Waterfoot Primary School), student centers (e.g., Harlow Learning Cen-
ter), media centers (e.g., Knowle West Media Centre), residences (e.g., Shirehampton Eco-Homes 
Bristol), co-houses (e.g., LILAC Affordable Co-houses, BaleHaus at Bath), cafes (e.g., Holme Lacy 
Campus Cafe), and visitor centers (e.g., Hengistbury Head Visitor Centre) (ModCell, n.d.). Another 
example of the new way of the straw bale usage is the panel-cladding used in the Résidence Jules 
Ferry building with an eight-story in St-Dié-des-Vosges in France (Walker, et al., 2016). Considering 
that the traditional way of the straw bale is mostly used in small-scale buildings, it can be said that 
with the advancing technology in contemporary architecture, the range of building types and the 
building scale which are constructed by using straw have been expanded. Magwood et al. (2005) 
stated that commercial buildings could be more suitable for construction with straw bale than resi-
dential buildings because they are prefabricated and modular. Furthermore, straw houses and straw 
can support sustainable contemporary life. After excessive natural disasters, scarcities, and global 
warming issues, people are seeking a new way of life that is healthy, sustainable, and harmless to 
the nature. Straw Bale construction is one of the original techniques for creating that kind of living 
area (Guarneri, 2014). StrawBale Village proposal by One Community can be given as an example 
of this new way of sustainable contemporary life (One Community, 2020). One Community -which 
proposes mini-village models with different eco-building methods- benefits in their second pro-
posed village from the modular and expandable nature of the straw bales for creating a sustainable, 
accessible, and collective way of living (One Community, 2020).



Journal of Sustainable Architecture and Civil Engineering 2021/1/28
18

Straw and 
Sustainability

Straw houses have various benefits. They perform well especially with regard to: sustainability, 
energy efficiency, embodied energy, water efficiency, embodied water, and embodied carbon. CI is 
a carbon-emission intensive industry. Furthermore, many of the construction products have high 
amount of embodied carbon. Today, in many countries, there is an increasing tendency to reduce the 
negative impacts of the CI on the environment with the help of sustainable and green construction. 
Straw bale usage in the construction can reduce the greenhouse gas emissions significantly reduc-
ing carbon footprint and embodied carbon of the building (Jones & Breese, 2009). Straw is one of 
the natural building materials which has many different advantageous features in terms of sustain-
able construction. Contrary to the intensive energy consumption, carbon emission and water con-
sumption in the modern building material production process, straw is more environment-friendly 
(Walker, et al., 2016). Straw which is a waste material, is a natural and renewable material which 
reduces the environmental footprint of the building throughout its lifecycle (Bendapudi, et al., 2012). 
Furthermore, usage of straw as a building material, instead of burning it, can contribute to the waste 
recycling in a sustainable way (Nunan, 2010). The usage of locally available straw can further reduce 
embodied carbon, carbon emissions, energy and transportation cost, as well as support the local 
economy. Furthermore, considering the demolition processes of buildings, straw does not cause 
environmental pollution as it is dissolved in nature easier.

Energy Efficiency and Embodied Energy: CI is energy intensive. More than 30% of the worldwide 
energy consumption results from the CI (Andrić, et al., 2017). Straw has low embodied energy. The 
choice of straw bale wall with 6:1:1 section of plaster can be a better selection than traditional con-
struction style of wooden frame with brick siding thanks to its six times lower embodied energy 
(Offin, 2010). Embodied energy value of the straw bale has various values depending on analysis 
type with different parameter [e.g. 0,24 MJ/kg (North, n.d.; Offin, 2010: 35), 0,4 MJ/kg (Edminster & 
Alcorn, 1995; Offin, 2010: 35), 0,0014 MJ/kg (BRE, 2001; Offin, 2010: 35)]. As CI is carbon emission 
intensive, improvement of the energy efficiency is important and it can be supported by the usage 
of straw-bale due to its high thermal insulation value (Amazon Nails, 2001). This can enhance 
reduction in the heating and cooling loads. Reduction in the rural populations’ dependence on the 
coal can contribute to the sustainable development (Bendapudi, et al., 2012). This reduction can 
take place with the usage of straw as a main building material as it is a local and waste product 
of harvested grain. Houses constructed with straw generally do not require any additional wall in-
sulation as R-value for straw bale walls ranges between R-17 and R-65 (Stone, 2003; Offin, 2010). 
For this reason, considering increase in the world population and global warming, the straw bale 
structure can be adopted as a housing solution which can contribute to the reduction in the usage 
of fossil fuels (Kennedy, Smith & Wanek, 2015).

Embodied Water: Buildings consume important amount of energy and water (during construction, 
material manufacturing phase) in the production/manufacturing phase as well as in the occupa-
tion and maintenance phase. Water usage is a significant environmental problem especially in hot 
and dry climates. All products need water to be produced. As the total water used in whole stages 
of the production chain means virtual water, the more the material is processed, the more virtual 
water is consumed. As straw bales do not undergo industrial processing, the virtual water value 
is less than many other modern construction materials (e.g., steel, concrete). The considerable 
amount of water usage for straw bale occurs during the growing process of grains.

Initial investment, operation and maintenance costs: Straw houses have relatively low initial in-
vestment, operation and maintenance costs. This potential advantage of the straw houses can 
contribute to the environmental, social and economic sustainability as well as to the affordability 
of housing (Table 1). Straw houses can be considered as a solution to the affordable housing 
scarcity problem. Straw houses are cost effective enabling cost savings throughout the build-
ing life cycle periods especially in the construction and maintenance period as they can enable 
reduction in the labor cost due to the easy/simple construction process and as they can enable 



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Journal of Sustainable Architecture and Civil Engineering 2021/1/28

reduction in the heating and ventilation due to their high heat insulation (Garas et al., 2009). 
Simplistic building method of straw can enable unexperienced people to participate in the design 
and construction processes (Jones & Breese 2009). The cost of a straw bale building varies by: 
region, climate, codes and permit requirements; the method of construction as well as the size 
and design of the building (Woolley & Kimmins, 2000); the price paid per bale and distance of the 
place from where the straw is purchased (Steen et al., 1994). Furthermore, straw houses’ oper-
ation period is cost effective due to the energy efficiency and reduced energy cost. For example, 
in Mongolia, straw bale buildings have approximately 80% less energy consumption compared 
to the conventional buildings (Bainbridge, 2004; Garas et al., 2009). The heating costs of straw 
houses can be reduced by 75% annually compared to traditional residential buildings (Jones & 
Breese, 2009:14). Straw can balance the air conditions inside of the houses which can give an 
opportunity to reduce maintaining cost of the building (Steen et al., 1994). According to a study 
of the Canada Mortgage and Housing Corporation, the usage of heating energy for space in the 
straw bale houses is at least 20% lower than the modeled traditional houses (Technical Series 
02-115. 2002; Garas et al., 2009). Life of straw houses can last for hundred years with very low 
maintenance costs (Steen et al., 1994: 38-39).

Table 1 
Examples of main 
characteristics 
of straw houses 
which can 
contribute to the 
sustainability and 
affordability of 
houses

Its long life duration and low maintenance costs (Steen et al., 1994)

Its contribution to the reduction in the usage of fossil fuels (Kennedy, Smith & Wanek, 2015)

High thermal insulation value (Amazon Nails, 2001; Stone, 2003; Offin, 2010; Garas et al., 2009)

Low embodied energy (Offin, 2010)

Reduced energy demand (Bainbridge, 2004; Garas et al., 2009) and reduced heating costs (Jones & Breese, 
2009; Technical Series 02-115. 2002; Garas et al., 2009)

Low embodied carbon (Jones & Breese, 2009)

Its contribution to waste recycling (Nunan, 2010)

Easy and fast construction (Jones & Breese 2009; Nunan, 2010)

Moisture and fire related concerns are among the main concerns which need to be addressed 
throughout the entire lifecycle of the straw houses starting from the design phase so that sustain-
ability and affordability of houses can be achieved (Magwood, et al., 2005). As the moisture content 
over the acceptable ratios can cause serious health problems as it can cause moisture and repro-
duction of mold spores, straw bale designers and researchers need to give a special attention to 
this issue (King, 1998). The effective solutions to deal with problems related with water and vapor 
depend on the climate and region of the building (Carfrae, 2011). For example, Marc Rosenbaum 
suggests that in cold climates, vapor-retardant paint should be used on the interior wall, whereas in 
hot and humid climates, this paint should be used on the exterior (Wilson, 1995). Another precaution 
to prevent moisture is placement of the air barrier between the bottom of the bales and the footing 
as the bales can be recommended to be raised approximately 20 cm above ground level (Steen et 
al., 1994). Furthermore, detailing of windows is essential measure to prevent from moisture leakage 
(Kennedy et al., 2015). Despite of the concerns for the moisture, Steen et al. (1994) state that there 
are straw bale buildings which don’t have any problem of deterioration of the bales in Washington 
which receive 75 inches of rain per year from 1970s and 1980s (Steen et al., 1994). Fire resistance 
is another important aspect of straw houses. Plastered straw bale walls have lower fire risk than 
traditional timber frame walls (Steen et al., 1994). In accordance with the statements of the Canada 
Mortgage and Housing Corporation, it has been proved that straw bales have high fire resistance 
(Steen et al., 1994). Fire retardants (e.g. aluminum sulfate) can be applied to the bale to reduce fire 



Journal of Sustainable Architecture and Civil Engineering 2021/1/28
20

risk of the building (Myhrman & MacDonald, 1997). The greatest risk of fire, however, can emerge 
due to loose straw that can agglomerate on the worksite. As especially in windy conditions, the 
flames can easily spread through these straws, sweeping loose straw and storing away from build-
ing is an important issue (Myhrman & MacDonald, 1997).

Political 
Economy 
of Straw 
Houses

Political economy of straw houses is related with the straw’s performance and effects regarding 
to the three pillars of sustainability (Fig. 1). Straw houses can have impacts and contributions to 
these three pillars of sustainability which can act as drivers for increasing demand for them (Fig.1).

Straw and straw houses can have impact on the environmental sustainability with the help of their 
low environmental footprint due to their energy efficiency, water efficiency, low embodied ener-
gy, carbon and water as well as their contribution to the circular economy. Straw can substitute 
some of the materials having higher embodied energy, carbon, and water as well as reduce their 
market share. According to Peñaloza et al. (2018: 1025), there is a necessity to urgent mitigation 
measures for CI’s GHG emissions as it causes “19% of the global GHG emissions.” (Peñaloza et al., 
2018: 1025). As building straw houses can help to protect the environment, they can help govern-
ments and NGOs to reduce their spending to protect the environment. Protecting environment and 
reducing air pollution can make people healthier reducing their health care spending.

Straw and straw houses can contribute to the social sustainability due to relatively fast and easy 
construction process, relatively low construction/initial investment cost, operation and mainte-
nance costs heating and cooling costs (due to relatively low active heating and ventilation require-
ments). Easy construction process can enable creation of job opportunities for relevant workforce 
or they can enable the potential home owners to build their own houses. Fast construction pro-
cess can enable demand for housing to be fulfilled fast even in the post-emergency or post-disas-
ter phases. Using straw is relatively faster option for the construction in terms of both preparation 
and execution process (e.g. no curing or drying period for the straw; no fabrication process for 
the straw) (Nunan, 2010). Easy and fast construction process of straw houses as well as their 
relatively low initial investment, operation and maintenance cost can enable straw houses to act 
as affordable housing and post-disaster housing. These potential benefits of straw houses can 
support welfare and wellbeing of the occupants.

Straw and straw houses can have impact on the economic sustainability and welfare creation. 
Enhanced circular economy can reduce the demand for and consumption of the raw materials 
which can be used in other value added production processes and products. Furthermore, poten-
tial contributions of the straw houses in reducing environmental footprint of the CI can contribute 
to the wellbeing of the occupants and to reduce health care spending. Potential contribution of 
the straw and straw houses to the reduction in the energy demand (Bainbridge, 2004; Garas et 
al., 2009) for construction and operation of the built environment can strengthen countries’ econ-
omy through reduced energy deficiency. As CI is responsible for at least 30% of the global energy 
consumption (Andrić et al., 2017), energy efficiency is important to reduce energy trade gap and to 
enhance sustainable development (Berk & Cin, 2018). Even in developed countries energy trade 
deficiency plays an important role in the economy. For example, energy caused America’s trade 
gaps (Tsafos, 2018). Governments can invest more owing to this kind of energy saving which will 
enhance welfare of the people. They can allocate their budget more on investment to respond to 
their societies’ needs. Furthermore, people who have reduced their energy spending, can spend 
more on leisure and on other investments which can make economy vivid and lead to the eco-
nomic development. These examples reveal that straw houses are among the other factors which 
can influence the sustainable development.

Environmental, social, economic, political, legal, technical and innovation aspects can act as con-
structs of the political economy of straw houses (Fig.1). They can act as enablers for wide spread-



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Journal of Sustainable Architecture and Civil Engineering 2021/1/28

ing straw material usage and straw houses’ constructions. These constructs influence each other. 
Among these constructs, political and economic factors can act as key enablers and drivers for 
straw and straw houses (Fig. 1). For example, Townsend et al. (2018)’s research on the availability 
of wheat straw for bioenergy generation in England, revealed the importance of pricing policy and 
its impact on the motivation of farmers for exploring innovative ways for increasing straw supply. 
Furthermore, policies and economic decisions encouraging research and development activities 
on innovative ways of using straw can further contribute to the wide spreading of straw material 
and straw houses. There are various examples for research and developments which can con-
tribute to the innovations having potential to contribute to the widespread usage of straw [e.g. 
enhancing durability of straw focusing on straw types’ water sorption in wall construction (Yin, et 
al., 2018); usage of different straw types (lavender and barley) as bio aggregates in earth bricks 
(Giroudon et al., 2019); enhancing efficiency in the straw resources’ usage (straw return versus 
usage of straw briquette fuel as a substitute for rural heating coal) (Zhang et al., 2019); investiga-
tion of straw’s usage in methane production (Guo et al., 2019); optimum straw return-to-field ratio 
(Liu et al., 2019); hygrothermal and funistatic properties of two new straw blocks on the northern 
wall of a solar greenhouse (Ren et al., 2019), etc.].

Fig. 1
Political economy 
aspects of the straw 
houses

Effective policies, laws, and regulations need to be in integrity and in compliance with the global 
climate justice and urban climate justice. Bulkeley et al. (2013) have emphasized the relationship 
between climate change politics and justice. Furthermore, Michalec et al. (2019) introduced smart 
and just city concept (Michalec et al., 2019). Based on the UNDP (2016)’s definition of human devel-
opment, Alves & Mariano (2018) have emphasized relationship between climate justice and human 
development. Urban climate justice can influence emergence of new laws which can contribute 
to the sustainable development and encourage construction of environmental friendly buildings 
and cities. How to implement these new laws is also part of the political economy. “…the politi-
cal economy endeavors to connect political and economic procedures within a nation.” (The World 
Bank, 1982; Loshaj, 2016: 4). Examples for such procedures can include water reforms or ways for 
implementation of new laws (The World Bank, 1982; Loshaj, 2016). Effectiveness of policies, laws, 
and regulations is related with their economic impacts which can influence supply of and demand 
for straw based materials and straw houses. Governments can encourage businessmen to build 



Journal of Sustainable Architecture and Civil Engineering 2021/1/28
22

 

 

 

 

 

straw houses. Governments can reduce taxes or give subsidies to the businessmen who want to 
build straw houses or who want to invest in innovations related with straw materials. Furthermore, 
effectiveness of the policies, laws and regulations depends on the stakeholders’ contribution as 
well as on the systematic approach. Main stakeholders and their main roles in enhancing political 
economy of the straw and straw houses have been illustrated in the Fig. 2. Climate change policies 
(both mitigation and adaptation policies) can be managed in an integrated way with the help of 
effective urban governance and with the participation of local governments (Lee & Painter, 2015). 
Furthermore, political feasibility depends on societal transformation and social justice (Patterson 
et al., 2018). Effectiveness of the climate policies and their acceptance can be further enhanced in 
case policy makers consider long-term effects of climate policy (Bretschger, 2017). Furthermore, 
academics and researches can collaborate further to enhance effectiveness and widespread usage 
of straw in the CI through their research and development activities. Research funds can encourage 
their research activities in this field. These funds together with effectively allocated subsidies to the 
manufacturers can foster widespread usage of this traditional material as a contemporary material 
in contemporary built environments. Architecture and civil engineering undergraduate education 
curriculums can be effective tools to enhance future construction professionals’ knowledge on and 
preference of straw materials usage in an innovative and contemporary way.

Fig. 2
Main stakeholders 

and their main roles 
in enhancing political 

economy of the straw 
and straw houses

Political economy of straw houses needs to be considered as inputs to the housing policies. Sus-
tainability and affordability performance of straw houses highlight their important role in housing 
policies and sustainable development policies.

 

 

 

a – Main institutions and their main roles in enhancing political 
economy of the straw and straw houses;
b – Main individuals in enhancing political economy of the straw 
and straw houses.

a

b



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Journal of Sustainable Architecture and Civil Engineering 2021/1/28

Conclusions

References

Humanity’s environmental footprint has been asymptotically increased since the first industrial 
revolution. Humans should use the world’s natural resources more efficiently, as failure to do 
so can obstacle sustainable living on earth. Straw, as a traditional and contemporary material, 
can provide sustainable solutions. Straw and straw houses can contribute to dealing with this 
challenge as they can support and protect nature and natural resources with the help of their low 
embodied energy, carbon and water. Their potential contribution to the three pillars of sustain-
ability and to the sustainable development make them a subject of the political economy. This 
paper focused on the political economy of straw houses and straw houses’ contribution to the 
sustainability performance of the built environment. Political economy aspects of straw houses 
were explained under the environmental, social, economic, political, legal, technical and innova-
tion categories which are interrelated. These categories are the main pillars of the political econo-
my of straw houses and their effectiveness and success depends on the successful management 
of their relationship and their impact to each other as well as on the effective contributions of all 
stakeholders. Further studies can focus on how to widespread straw material usage in developing 
and underdeveloped countries to fulfill their sustainable development needs.

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EGEMEN
SERTYESILISIK

Position at the organization  
Freelance consultant  
in Gozuyilmaz Engineering  
and Marine Industries Ltd.

Main research area 
Sustainability, sustainability 
policies,  
political economy

Address 
Gozuyilmaz Engineering and 
Marine Industries Ltd., Izmir, 
Turkey
E-mail:  
egemens@alumni.bilkent.edu.tr

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/ ).

ŞEYMA 
YILMAZ

Position at the organization  
MSc Architect in Cevher Cam

Main research area 
Sustainability, construction  
project management

Address 
Cevher Cam, Sumer Mah. 
Denizli, Turkey
E-mail:  
seyma.ylmaz.93@gmail.com

BEGUM 
SERTYESILISIK

Position at the organization  
Professor, Izmir Democracy 
University, Faculty of Architecture, 
Department of Architecture 

Main research area 
Sustainability, construction  
project management

Address 
Izmir Democracy University,  
Faculty of Architecture,  
Department of Architecture, 
Izmir, Turkey 
E-mail:  
begum_sertyesilisik@hotmail.com