The built environment is a long-standing hotspot of resource use and environmental impacts. The construction industry is one of the largest sectors in terms of contributions to greenhouse gas emissions in the United States (Truitt, 2009) and one of the heaviest consumers of natural resources (USGBC, 2012). Thus, the building and construction sector has a large potential to contribute to the achievement of future sustainable development (UN, 2015). As environmental topics related to resource efficiency and low energy become increasingly pertinent, current construction methods and products must adapt (Kibert, 2016). Unlike other industrial sectors, construction has historically failed to generate and sustain economic growth through innovation (Murphy, Perera, & Heaney, 2015). This is mainly due to high cost pressures (Loforte Ribeiro, 2009) and the long-term characteristic of projects, including high uncertainties (Ilg, Scope, Muench, & Guenther, 2017).

Literature overviews discussing the benefits and barriers of a green construction industry currently exist (Häkkinen & Belloni, 2011; Zuo & Zhao, 2014). However, they fail to draw conclusions on the business actors and companies that plan and build such projects. Additionally, little is known about the role of new materials and products on the greening process. Finally, no connection has been made between the greening process and corporate financial performance (CFP). However, all these aspects are vital for the transition to a green construction industry.

The aim of the article is threefold. First, it investigates how a sustainable virtuous circle (Glass, 1996) capable of turning the construction industry into a leading green sector could be created. Second, the importance of product innovation is analyzed (Cheng, Chang, & Li, 2013). Finally, the article aims to investigate barriers and other factors that impede, delay, or completely block the greening process (Mirow, Hoelzle, & Gemuenden, 2008). Moreover, practical implications and best practices are presented on how to overcome these barriers. The research bases on a literature review, 25 expert interviews with planners and developers, and three in-depth case studies with green business leaders. The research questions created to identify the transition mechanisms to a green development and its impacts are as follows:

• 1.

  What does a virtuous circle for a green construction industry look like?

• 2.

  How does green product innovation (GPI) influence the virtuous circle?

• 3.

  Which barriers hinder the greening process in an inert environment and how might these barriers be overcome?

The findings will guide construction companies in the greening process and demonstrate how to optimize their innovation processes to generate positive, long-term corporate environmental and financial performance (Menguc & Ozanne, 2005). Apart from the value added for corporate management, these findings help governments to approve regulations and certification schemes that encourage green development in the construction industry. Business science is provided with an in-depth understanding of the relationship between business (construction industry), GPI, and CFP.

The paper is structured as follows. First, an overview of the applied theories is provided in “Theoretical Background”. Afterwards, the used methods are explained. The following section presents the results, including the virtuous circle. The identified barriers are analyzed in “Barriers connected to a green construction industry”, followed by practical implications to overcome them. The next section entails the three case studies. The final section concludes the findings and provides an overview of future research.

In this article, the relation between GPI and a greening process of an inert industry is analyzed with the concept of a virtuous circle. The greening process is quantified by the number and quality of green real estate projects. Similar to UNEP (2012) or USGBC (2015a), green real estate projects are understood as projects that are more durable, more energy efficient, nontoxic, easier to deconstruct and recycle, and have a much smaller environmental footprint than conventional homes, while remaining economically profitable.

The resource dependency theory (RDT) is used as a theoretical background in this article as it analyzes the organization within its environment, focusing on the organization's uncertainty reduction and its interfirm relationships. The two main pillars of the theory state that 1) organizations are open systems that continuously exchange material and information with their environment, and 2) their survival depends on the resource exchange with the environment (Pfeffer & Salancik, 1978). Tashman (2011) extended that theory and added the biophysical sphere to the external environment, allowing RDT to investigate the direct relationship between organizations and the natural environment (Bergmann, Stechemesser, & Guenther, 2016).

As the influence of the environment on corporations is complex, a virtuous circle is appropriate to analyze that topic and its connection to GPI (Glass, 1996). Similarly, the concept of virtuous circles was applied by Orlitzky (2005), who detects a positive correlation between social performance and financial performance, suggesting the relation forms a virtuous circle. Additionally, innovation and the influence of regions on greening the economy can lead to a virtuous circle (Antonioli, Borghesi, & Mazzanti, 2014), as well as competition within a sector (Castaño, Méndez, & Galindo, 2016), or innovation, economic growth, and entrepreneurship (Galindo & Méndez, 2014). Finally, a virtuous circle in the construction industry is discussed by Brady, Davies and Gann (2005), who conducted research on private finance initiatives. However, these articles do not combine product innovation and greening within an industry to create a virtuous circle, nor are barriers and conditions discussed that are essential to starting that circle.

A strategically managed GPI starts and steers the virtuous circle (Lai, Lin, & Wang, 2015). GPIs are goods or services which are new or significantly improved (OECD, 2005) and have a lower environmental impact than their predecessors. The importance of market orientation and firm innovativeness, and the moderating effect of managerial attitudes of top managers toward the natural environmental, has been shown by Dibrell (2011).

As some authors argue that learning from mistakes motivates learning more than success (Eisenhardt & Martin, 2000), barriers in this non-linear system are identified in order to provide recommendations on how to initiate the virtuous circle and foster organizational learning. Therefore, the EOI model (external environment, organization, and individual barriers) by Hueske, Endrikat, and Guenther (2015) is applied to identify potential barriers.

The article is based on a literature review, focusing on the creation of a virtuous circle and GPI in the construction industry. The review considers existing virtuous circles from innovation and greening (e.g. Guenther & Hoppe, 2014). Subsequently, a more sophisticated circle is developed.

Secondly, the designed circle was assessed by practitioners and scientists. The experts were selected from the construction and real estate industry by theoretical sampling (Eisenhardt, 1989; Sandelowski, 1995). Interview requests were sent to the ten largest real estate developers, the largest consulting companies, and real estate academics in Germany. Germany was chosen as it serves as a forerunner in certifying green building. Theoretical saturation (Sandelowski, 1995) was reached after 20 interviews. The sample was supplemented by a representative of an investor-driven organization (interviewee #26) and an architect committed to green building (interviewee #27). An overview of the interviewees is provided in Table 1. Interviews were conducted from October 2016 to February 2017 via telephone or in person.

All interviews had an average length of 30–40min. The interviews were conducted on the basis of a semi-structured interview guide (see Appendices 1 and 2). The definition of green construction, as mentioned in “Theoretical Background”, was provided in order to start on a common basis. After transcribing the audio-recorded interviews, MaxQDA, a software for computer-aided qualitative data analysis, was used to code and analyze the interviews (Mayring, 2014).

Thirdly, the study follows the methodological approach of Olsen, Prenkert, Hoholm, and Harrison (2014) and compiles three case studies to understand the strategic decisions that are necessary to foster GPI. The case study approach offers the possibility to address the dynamic interactions between innovation, greening, and strategy over time (Herrera, 2016). Moreover, the interrelations between innovation, greening, and strategy are rather complex and thus a case study is preferable to quantitative analysis or experiments (Gerring, 2004). The case studies comprise in-depth interviews with senior managers and detailed study of documents and further information provided by the company. The questions asked in the interviews were arranged according to the steps of the virtuous circle and were backed up by theoretical approaches in business economics provided by Lewin (2004).

Green and sustainable products have long enjoyed high consumer demand and have become more and more required by governmental regulation. Since 2007, this trend for green projects has been visible in the construction and real estate industry as well (#22; #23). Annual spending on green construction in the US is projected to increase from $150.6 billion in 2015 to $224.4 billion in 2018 (USGBC, 2015b).

Regardless of recent developments, the real estate industry lags behind the sustainability movements of other business sectors (RREEF, 2010). The construction industry is still known to be among the least innovative industries and most conservative in terms of adaptation of innovation (Xue, Zhang, Yang, & Dai, 2014). Fig. 1 illustrates the designed virtuous circle that accelerates green project development and includes a self-enforcing greening process.

Fig. 1.

A virtuous circle of green product development in the construction industry.

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After a short overview of the entire circle, each step is described more in detail and backed up by literature and expert interviews.

Green becomes a business model

As a next step in the virtuous circle, green becomes a business model. US residential green construction spending is expected to grow by 24.5% from 2015 to 2018, while commercial green construction spending is estimated to grow by 9.76% at the same time (USGBC, 2015a). Asked about the willingness to participate in this booming market, 37% of executives are expecting more than 60% of their upcoming projects to be green (see Fig. 2). Additionally, most governmental projects in the western hemisphere ask for a certain type of green labeling of the companies and the projects as a prerequisite to participating in the bidding process (#22; #23; #24; #25).

Fig. 2.

Expected growth in levels of green building activity (DODG, 2016).

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One example of a company already using the business model is Turner Construction. They have generated more than half of their revenue (USD 5 billion in 2014) from green infrastructure projects each year since 2009. Another sign that green construction is turning into a business model are the offered products from the finance and insurance sector (BD&C, 2006), including funds being established with the single goal to invest in green buildings.

After all steps of the virtuous circle are discussed in more detail, this section concentrates on the barriers that might occur while fostering GPI. Using the model of Hueske et al. (2015), barriers are categorized to external, organizational, and individual factors.

External barriers are mainly determined by third parties and secondary stakeholders. For the greening of the construction industry, three major barriers are identified.

First, the construction industry is project based: Loosely coupled firms, mostly small and medium enterprises, delivering “projects” through partial engagement. The co-development of construction innovation at the project level includes “the government, suppliers of building materials, private capital providers, vendors and distributors, educational institutions, [and] professional and certification bodies” (Davis, Gajendran, Vaughan, & Owi, 2016: 105). Often these various partners do not cooperate enough (Xue et al., 2014). Using RDT, an exchange of information and material takes place; however, the exchange is uncoordinated and important parts are held back to gain competitive advantages. Additionally, innovation has the largest impact if positioned at an early stage. However, for real estate projects, planning and design is often decoupled from the construction phase (Murphy et al., 2015) and the use of green material depends on these actors (#23; #24). Inexperienced owners and buyers find it hard to navigate an opaque marketplace, what results in poor project management, inadequate design processes, and underinvestment in skills development, R&D, and innovation (McKinsey Global Institute, 2017). Moreover, the fragmented characteristic of construction and its high degrees of specialization makes innovation and its controlling more difficult. Product and process innovations have to be managed across organizational boundaries and within networks of interdependent suppliers, customers, and regulatory bodies (#22; #24). These effects are reinforced by changing political structures and regulations or missing support (#1; #5; #10; #17; #19).

Second, the lack of public awareness and information is a further barrier for green real estate projects (#2; #4). A lot of clients are still concerned about the higher risk of green projects (Larsson & Clark, 2000; #22; #23; #24) based on new assembling techniques, higher costs for additional testing (#25), shortage of support during the use phase (#4; #11; #12), and missing performance information (Häkkinen & Belloni, 2011). As a result, misperceptions of higher capital costs and inadequate market values circulate in the media and general public (Bon & Hutchinson, 2000). Deficient knowledge among investors reinforces that effect (RREEF, 2010).

Finally, a major external barrier is the well-known agency problem. Investment costs are defrayed by investors and developers, whereas utility costs are paid by the owners and tenants. Landlords pay for the capital costs of efficiency improvements, while many of the benefits of green buildings accrue to the user of the property (RREEF, 2010). Thus, where property owners pass utility costs on to tenants, they have no incentive to integrate utility cost-saving technologies (Morgan Stanley, 2016; #2; #15).

Organizational barriers are mainly related to strategy, structure, resources, and organizational culture within the firm. First, culture in the construction industry is rather conservative (Xue et al., 2014; #21). Companies and managers are rather risk averse and are usually skeptical about new products and processes (Morgan Stanley, 2016; #15). A major reason for that risk aversion is the large investment sums and low profit margins (#26). Regarding RDT, financial resources are lacking. Mistakes and delays due to missing certification or low technological performance can derail entire projects, and create negative effects for future orders (Häkkinen & Belloni, 2011; #21; #28).

Second, current accounting methods within construction companies result in fewer green real estate projects. As annual budgets do not take account of savings over several years, efficient use and maintenance measures do not pay off. Half of the executives rated the accounting methods as an extremely or very significant obstacle (Turner Co, 2014).

Individual barriers are connected to attitudes of individuals, personal characteristics, and the lack of management support for innovation. Two main barriers were revealed on the individual level.

First, and similar to external barriers, higher perceived construction and first costs are a main hurdle for managers and developers (#21). Second, most managers (56%) argue that payback periods are too long (Turner Co, 2014; #2), although most executives are willing to accept an extended payback period if projects incorporate green features (Turner Co, 2014).

The mentioned barriers on the external, organizational, and internal levels are not written in stone, and adequate solutions do exist for most of them. These are presented in the next section.

Similar to other industries, barriers of co-development can be solved by stakeholder collaboration and integration, a core concept of RDT. The construction industry has to increase both its collaboration with stakeholders and its absorptive capability. The former allows for the exchange of knowledge about new materials and technologies, while the latter refers to the incorporation of external knowledge for internal use in the organization. This can be achieved by effective information gathering (Veshosky, 1998), knowledge exchange (Xue et al., 2014), better communication and collaborative relationships (Davis et al., 2016), as well as cooperation between corporations and academia. Both aspects are in line with RDT and aim to reduce uncertainty by exchanging materials and information (Pfeffer & Salancik, 1978).

In order to make green real estate projects even more interesting, external effects during the construction and use phases should be internalized by governmental regulation (#26). By that, the biophysical sphere becomes incorporated in the valuation as requested in the NRDT (Tashman, 2011). Moreover, the shifting of certification schemes to more quantitative and intuitive control mechanisms would strengthen public awareness and empower consumers.

Connected to the first aspect, on an organizational level, the integration of planning and design at an early stage is important (BD&C, 2003; #1; #13; #16; #20). In these two stages, most of the economic and environmental impacts are determined. Moreover, the decision to build green has to be made as early as possible (#19; #23). The earlier green aspects are incorporated in the planning, the lower the cost difference between conventional and green building (#19; #20).

As mentioned above, some administrative procedures within companies block the development of green real estate projects. Innovative fiscal arrangements increase the acceptance of green real estate projects and reduce that barrier, e.g. longer pay back periods and the evaluation of individual targets on a project level rather than on an annual basis. Externally, financing arrangements could be recovered through increased rents (Häkkinen & Belloni, 2011) and an agreement between landlord and tenant on how the positive externality of lower operational costs can be internalized by the landlord (RREEF, 2010).

Finally, a comprehensive innovation management system is necessary (#24; #25). That includes feedback loops to control and steer the innovation process within the company, but also innovation management in singular construction projects (Murphy et al., 2015).

On the individual level, managers should encourage team members to visit trainings (BD&C, 2006). Motivated staff might start pilot projects and create spin offs for new divisions (#21). Following that, the power of these “leaders” can be used to shape an innovation culture (Xue et al., 2014) and to document and monitor the implementation of new technology (BD&C, 2003; Murphy et al., 2015).

Finally, and most importantly, strengthening the push and pull factors would provide the most impact. Using real cost data for a broad range of sustainability technologies and design solutions contradicts the assumption of high costs of green real estate projects and demonstrates the significant improvements in technological and environmental performance (#8; #11; #14). Moreover, it is necessary to communicate the life cycle cost (#13), provide live data, e.g. by smart metering (#27), and inform about technological benefits (#9). If large construction companies recognize these benefits, they will use certification schemes. As a result, other companies – competitors and suppliers – will follow as they are pulled by their market power (#26; #27). A reverse effect is also possible. Innovations can be pushed by suppliers. In the Netherlands, one of the most innovative construction sectors, suppliers accounted for about two-thirds of technological innovations (Pries & Doree, 2005). Both effects are in line with RDT as they prove the dependence of companies with their environment (Pfeffer & Salancik, 1978).

If institutional investors are convinced by the financial benefits and the quality improvement, they will accelerate the trend (#13; #27) by demanding certificates for their investments and thus use their financial power to green the real estate sector from a portfolio level (#6; #27).

Finally, push factors can be strengthened by stricter regulations and the comprehensive application of green building standards for public projects (#1). As a result, the majority of real estate companies and their projects (peak of the curve in Fig. 3) are pushed by regulation and pulled by the market to the right.

Fig. 3.

Stimulation of push and pull factors to increase green real estate projects.

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Adapted from GRESB (2016).

Skanska AB, an international development and construction company from Sweden, has been proactive in environmental management since the mid-1990s. The decision of “going green” was made by the former CEO after an environmental incident in 1996. Skanska produced its first environmental report in 1997 and one year later published its environmental policy. By 2000, all its business units were ISO 14001 certified. For its business plan 2011–2015, a set of seven Green Strategic Indicators (GSIs) was agreed upon by the Senior Executive Team. These are translated to regional goals and the progress is presented quarterly by the Business Unit President to the Senior Executive Team. In comparison to other construction companies, responsibilities related to green performance are located on a high management level.

Today there are two reasons why Skanska is increasing its share in green projects: First, the brand is valuable and highly connected to sustainable construction. Skanska is seen as a green leader with an excellent reputation in that market. Second, most of the investors ask for it. The business model concentrates on institutional investors (pension funds) that are interested in long-term benefits. These investors are not only interested in how Skanska creates profit, but also with which projects.

Skanska implements the green strategy through the “Journey to Deep Green”™ and the “Skanska Color Palette”™. Particularly, the second tool indicates Skanska's awareness of visualizing environmental performance and is used in every project as targets are set on the project level and aggregated later. Skanska obliges the internal construction and development units to design and build projects that beat local energy codes by a minimum of 25%. A good example of process innovation at Skanska is its frequent use of building information modeling software tools and radio frequency identification tag technology to eliminate waste and optimize logistics. Moreover, Skanska uses the tools to organize just-in-time delivery, e.g. from specially built off-site construction centers outside of cities. The transformation of innovation from project to corporate level is demonstrated by the use of carbon footprints. Apart from its objective to measure embedded carbon and carbon generated during construction for progressive customers, Skanska uses the information to modify the project and related construction processes in other projects.

Similar to other companies, Skanska recognizes the importance of early green design. They use this opportunity in projects that they develop themselves. Here, Skanska is its own client and can demonstrate what is possible. With that, clients can be convinced more easily for future projects with green benefits. As the cash flow originating from construction is reinvested in Skanska development and construction units, the learning curve is pushed even further. As a side effect, the gained expertise is used to advise local construction companies that have no experience with green construction. A positive side effect which was not planned by Skanska.

High cooperation within and between units and business streams facilitates innovation and knowledge transfer. Moreover, Skanska works together intensively with customers and other value chain partners (around 100,000) in all Skanska markets (Carlén-Johansson, 2016). This action is in line with RDT as it reduces uncertainty and strengthens interfirm relationships. Additionally, each business unit has an environmental team that provides advice and professional support. Finally, Skanska is engaged in several international and national organizations to exchange knowledge and collaborate on future technologies, e.g. European Network of Construction Companies for Research and Development.

According to Elizabeth Heider, Chief Sustainability Officer for Skanska USA Inc., education of staff is one of the most successful drivers to becoming a green leader. On one side, it is important to develop awareness of practical opportunities to improve energy efficiency in the workplace, at home, and while commuting. On the other side, the workforce gets training in areas such as eco-design, LEED certification, energy modeling, and life cycle costing. This effect is fostered by a management that is highly committed to green and sustainable development.

Clark Construction is a building and civil construction firm in the United States with a strong emphasis on community values. Apart from high safety standards, they have been at the forefront of new technologies and evolving building trends. They started to deal with green buildings around 10–12 years ago, when LEED and other certification schemes started to become more prominent. While a sustainability strategy is still not included in the corporate strategy, a process manual provides guidance for all employees. In intensive communication with architects and clients, they always pursue the surpassing of legal requirements and being prepared for the future, while reducing environmental impacts. A sustainability department was created that supports the day to day work of other departments regarding certification, green building trends, and resource use. Moreover, they collect and cultivate best practices and include these ideas in new projects. To be up to date and collaborate with suppliers, Clark Construction is a member of several national and regional networks. Thereby, they are in line with the RDT, as they are very active regarding resource use and the exchange of material and information with the environment. Finally, they developed a handbook on sustainable issues that should be considered in every project. Apart from the external sustainability issues, internal processes are also reviewed regarding ecological and social impacts. According to Chip Hastie, Senior Vice President – Operations, passionate employees are the most important assets in the transformation of a conservative company into a green and innovative company. Once this internal transformation has taken place, green products and external sustainability are just a matter of time.

Southern Development Homes is a regional construction company offering EcoSmart homes with high comfort, energy efficiency, healthy air, and superior durability. Moreover, they are recycling the construction waste at a local facility that they helped to create. The decision to offer green products and housing was made around 12 years ago when consumer demand on these issues rose and green construction became more important.

To ensure knowledge transfer within the company, an IT database was installed in which every building was entered, including individual customer requests. Four times a year, these entries are evaluated to analyze customers’ preferences and new innovative concepts established in the community. Additionally, the staff is present in regional networks, e.g. the Blue Ridge Home Builders Association, and national exhibitions where they get in contact with competitors and suppliers and discuss current trends and barriers in the construction industry.

All examples demonstrate solutions and tools presented in the previous section and thus support the concept of the virtuous circle developed in this article. Moreover, the best practices show what first steps in the direction of a green leader on the international, national, and regional level look like.

The article presents solutions for the theoretical transformation of an inert sector, in this case the construction industry, into a green and innovative sector. First, a virtuous circle which greens the industry is designed. Second, a detailed discussion of each step is presented. Afterwards, barriers and practical implications for a green construction industry are analyzed. Finally, three case studies present best cases for determining what innovative companies are.

Results, based on surveys and expert interviews, have shown that higher first costs, outdated accounting methods, and complex projects are perceived as the largest barriers. Noteworthy solutions to these barriers are, first, raising awareness, as real cost data contradicts the assumption of high costs of green real estate projects. Second, large construction companies have to appreciate the financial and environmental benefits of green real estate projects and the market advantages of being a green leader. Finally, investors should acknowledge that rents and occupancy rates of green projects are higher than those of comparable properties. This supports the creation of a business model based on green technologies that shapes the real estate market in the coming years. The designed virtuous circle accelerates this process and prepares the sector for a sustainable and innovative friendly future.

The practical implications and the investigation of the green leaders studied in the case studies support RDT. The results show the relevance of RDT in explaining current trends in the construction industry and the importance of the external environment on companies.

Although the findings are supported by literature and expert interviews, they are based on a qualitative study. The topic could be elaborated by further case studies and by additional quantitative research that backs the presented findings, thereby enhancing the internal validity, generalizability, and theoretical level of the results. Most implications and examples in the case studies are related to RDT. However, effects of the external environment, e.g. extreme weather events, might have an influence on the use of innovative material as well. Future research should investigate that relationship and its impact on the financial performance. Moreover, water efficiency emerged as an increasingly important topic (Turner Co, 2014). Future research should concentrate on the importance of water efficiency for green buildings and its impact on the triple bottom line.

By identifying crucial barriers for a green transition and pointing out further research, the article adds value to the scientific discussion regarding the relationship between business (in this case the construction industry), GPI, and CFP. Moreover, it connects findings from expert interviews and case studies and thus provides a base for future quantitative research.

Practical implications include examples on how construction companies can expand their green product line and thereby improve financial performance. Additionally, the article identifies barriers and practical implications for the greening process and thus facilitates the entrance to green construction and internal decision-making. The findings will guide construction companies on their way to becoming green and demonstrate how to optimize their innovation process. Finally, the barriers provide starting points for governments to adjust legislation and regulation if more green construction is desired. If all the barriers and their solutions are heeded, the construction industry has the potential to become a leading green sector and will have a larger impact on the ability of future generations to meet their own needs.