Exnovation

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Exnovation means the process of terminating a practice, or the use of a technology or product, within an organization, community, or society. Put simply, it can be described as the opposite of innovation. Exnovation has also been described as the "flipside of innovation", [1] or the "lesser-known sibling of innovation". [2]

In commerce and management, exnovation can occur when products and processes that have been tested and confirmed to be best-in-class are standardized to ensure that they are not innovated further. [3] [4] [5] [6] Companies that have followed exnovation as a strategy to improve organizational performance include General Electric, Ford Motor Company and American Airlines. [7]

One of the earliest usages of the term came in 1981, when John Kimberly referred to "removal of innovation from an organisation". [8] In 1996 A. Sandeep provided a modern definition of exnovation as the philosophy of not innovating – in other words, ensuring that best-in-class entities are not innovated further. Since then "exnovation" has become a notable parlance in various practices, from management to medicine. [9] [10] [11] [12] [13] [14]

In recent years, the concept has been increasingly taken up in sustainability and transition research to designate and investigate the deliberate phase-out of unsustainable technologies, products, and practices, particularly in relation to energy transitions and a coal phase-out. [15] [16] [17]

Exnovation and innovation are interrelated: "On the one hand, exnovating products and practices creates spaces for new products and practices. On the other hand, the promise of a new product or practice helps eliminating old products and practices." [2]

See also

Related Research Articles

<span class="mw-page-title-main">Disruptive innovation</span> Technological change

In business theory, disruptive innovation is innovation that creates a new market and value network or enters at the bottom of an existing market and eventually displaces established market-leading firms, products, and alliances. The term, "disruptive innovation" was popularized by the American academic Clayton Christensen and his collaborators beginning in 1995, but the concept had been previously described in Richard N. Foster's book "Innovation: The Attacker's Advantage" and in the paper Strategic Responses to Technological Threats.

<span class="mw-page-title-main">Innovation</span> Practical implementation of improvements

Innovation is the practical implementation of ideas that result in the introduction of new goods or services or improvement in offering goods or services. ISO TC 279 in the standard ISO 56000:2020 defines innovation as "a new or changed entity, realizing or redistributing value". Others have different definitions; a common element in the definitions is a focus on newness, improvement, and spread of ideas or technologies.

In business and engineering, product development or new product development covers the complete process of bringing a new product to market, renewing an existing product and introducing a product in a new market. A central aspect of NPD is product design, along with various business considerations. New product development is described broadly as the transformation of a market opportunity into a product available for sale. The products developed by an organisation provide the means for it to generate income. For many technology-intensive firms their approach is based on exploiting technological innovation in a rapidly changing market.

<span class="mw-page-title-main">Food engineering</span> Field of applied physical sciences

Food engineering is a scientific, academic, and professional field that interprets and applies principles of engineering, science, and mathematics to food manufacturing and operations, including the processing, production, handling, storage, conservation, control, packaging and distribution of food products. Given its reliance on food science and broader engineering disciplines such as electrical, mechanical, civil, chemical, industrial and agricultural engineering, food engineering is considered a multidisciplinary and narrow field.

A sustainable business, or a green business, is an enterprise that has a minimal negative impact or potentially a positive effect on the global or local environment, community, society, or economy—a business that strives to meet the triple bottom line. They cluster under different groupings and the whole is sometimes referred to as "green capitalism." Often, sustainable businesses have progressive environmental and human rights policies. In general, a business is described as green if it matches the following four criteria:

  1. It incorporates principles of sustainability into each of its business decisions.
  2. It supplies environmentally friendly products or services that replace demand for nongreen products and/or services.
  3. It is greener than traditional competition.
  4. It has made an enduring commitment to environmental principles in its business operations.

User innovation refers to innovation by intermediate users or consumer users, rather than by suppliers. This is a concept closely aligned to co-design and co-creation, and has been proven to result in more innovative solutions than traditional consultation methodologies.

Social innovations are new social practices that aim to meet social needs in a better way than the existing solutions, resulting from - for example - working conditions, education, community development or health. These ideas are created with the goal of extending and strengthening civil society. Social innovation includes the social processes of innovation, such as open source methods and techniques and also the innovations which have a social purpose—like activism, crowdfunding, time-based currency, telehealth, cohousing, virtual volunteering, microcredit, or distance learning. There are many definitions of social innovation, however, they usually include the broad criteria about social objectives, social interaction between actors or actor diversity, social outputs, and innovativeness. Different definitions include different combinations and different number of these criteria. Transformative social innovation not only introduces new approaches to seemingly intractable problems, but is successful in changing the social institutions that created the problem in the first place.

Eco-innovation is the development of products and processes that contribute to sustainable development, applying the commercial application of knowledge to elicit direct or indirect ecological improvements. This includes a range of related ideas, from environmentally friendly technological advances to socially acceptable innovative paths towards sustainability. The field of research that seeks to explain how, why, and at what rate new "ecological" ideas and technology spread is called eco-innovation diffusion.

<span class="mw-page-title-main">Ecological design</span> Design approach sensitive to environmental impacts

Ecological design or ecodesign is an approach to designing products and services that gives special consideration to the environmental impacts of a product over its entire lifecycle. Sim Van der Ryn and Stuart Cowan define it as "any form of design that minimizes environmentally destructive impacts by integrating itself with living processes." Ecological design can also be defined as the process of integrating environmental considerations into design and development with the aim of reducing environmental impacts of products through their life cycle.

Innovation management is a combination of the management of innovation processes, and change management. It refers to product, business process, marketing and organizational innovation. Innovation management is the subject of ISO 56000 series standards being developed by ISO TC 279.

<span class="mw-page-title-main">Micro-sustainability</span> Individual or small scale sustainability efforts

Micro-sustainability is the portion of sustainability centered around small scale environmental measures that ultimately affect the environment through a larger cumulative impact. Micro-sustainability centers on individual efforts, behavior modification, education and creating attitudinal changes, which result in an environmentally conscious individual. Micro-sustainability encourages sustainable changes through "change agents"—individuals who foster positive environmental action locally and inside their sphere of influence. Examples of micro-sustainability include recycling, power saving by turning off unused lights, programming thermostats for efficient use of energy, reducing water usage, changing commuting habits to use less fossil fuels or modifying buying habits to reduce consumption and waste. The emphasis of micro-sustainability is on an individual's actions, rather than organizational or institutional practices at the systemic level. These small local level actions have immediate community benefits if undertaken on a widespread scale and if imitated, they can have a cumulative broad impact.

Environmentally sustainable design is the philosophy of designing physical objects, the built environment, and services to comply with the principles of ecological sustainability and also aimed at improving the health and comfort of occupants in a building. Sustainable design seeks to reduce negative impacts on the environment, the health and well-being of building occupants, thereby improving building performance. The basic objectives of sustainability are to reduce the consumption of non-renewable resources, minimize waste, and create healthy, productive environments.

Communities that support innovation have been referred to as communities of innovation (CoI), communities for innovation, innovation communities, open innovation communities, and communities of creation.

<span class="mw-page-title-main">Technology and society</span> Overview of the relationship between technology and society

Technology, society and life or technology and culture refers to the inter-dependency, co-dependence, co-influence, and co-production of technology and society upon one another. Evidence for this synergy has been found since humanity first started using simple tools. The inter-relationship has continued as modern technologies such as the printing press and computers have helped shape society. The first scientific approach to this relationship occurred with the development of tektology, the "science of organization", in early twentieth century Imperial Russia. In modern academia, the interdisciplinary study of the mutual impacts of science, technology, and society, is called science and technology studies.

<span class="mw-page-title-main">Circular economy</span> Production model to minimise wastage and emissions

A circular economy is a model of resource production and consumption in any economy that involves sharing, leasing, reusing, repairing, refurbishing, and recycling existing materials and products for as long as possible. The concept aims to tackle global challenges such as climate change, biodiversity loss, waste, and pollution by emphasizing the design-based implementation of the three base principles of the model. The three principles required for the transformation to a circular economy are: designing out waste and pollution; keeping products and materials in use, and regenerating natural systems." CE is defined in contradistinction to the traditional linear economy. The idea and concepts of a circular economy have been studied extensively in academia, business, and government over the past ten years. It has been gaining popularity because it can help to minimize carbon emissions and the consumption of raw materials, open up new market prospects, and, principally, increase the sustainability of consumption.

Transition management is a governance approach that aims to facilitate and accelerate sustainability transitions through a participatory process of visioning, learning and experimenting. In its application, transition management seeks to bring together multiple viewpoints and multiple approaches in a 'transition arena'. Participants are invited to structure their shared problems with the current system and develop shared visions and goals which are then tested for practicality through the use of experimentation, learning and reflexivity. The model is often discussed in reference to sustainable development and the possible use of the model as a method for change.

Transition engineering is the professional-engineering discipline that deals with the application of the principles of science to the design, innovation and adaptation of engineered systems that meet the needs of today without compromising the ecological, societal and economic systems on which future generations will depend to meet their own needs. Today safety is an expected consideration in design, operation and end use. Transition Engineering aims for a similar consideration of sustainability. Transition engineering is a trans-disciplinary field that addresses wicked problems while creating opportunities to increase resilience and adaptation through change projects.

Johannes Willem "Johan" Schot is a Dutch historian working in the field of science and technology policy. A historian of technology and an expert in sustainability transitions, Johan Schot is Professor of Global Comparative History at the Centre for Global Challenges, Utrecht University. He is the Academic Director of the Transformative Innovation Policy Consortium (TIPC) and former Director of the Science Policy Research Unit (SPRU) at the University of Sussex. He was elected to the Royal Netherlands Academy of Arts and Sciences (KNAW) in 2009. He is the Principal Investigator of the Deep Transitions Lab.

Innovation management measurement helps companies in understanding the current status of their innovation capabilities and practices. Throughout this control areas of strength and weakness are identified and the organizations get a clue where they have to concentrate on to maximize the future success of their innovation procedures. Furthermore, the measurement of innovation assists firms in fostering an innovation culture within the organization and in spreading the awareness of the importance of innovation. It also discloses the restrictions for creativity and opportunity for innovation. Because of all these arguments it is very important to measure the degree of innovation in the company, also in comparison with other companies. On the other hand, firms have to be careful not to misapply the wrong metrics, because they could threaten innovation and influence thinking in the wrong way.

<span class="mw-page-title-main">Green industrial policy</span> Strategic government policy

Green industrial policy (GIP) is strategic government policy that attempts to accelerate the development and growth of green industries to transition towards a low-carbon economy. Green industrial policy is necessary because green industries such as renewable energy and low-carbon public transportation infrastructure face high costs and many risks in terms of the market economy. Therefore, they need support from the public sector in the form of industrial policy until they become commercially viable. Natural scientists warn that immediate action must occur to lower greenhouse gas emissions and mitigate the effects of climate change. Social scientists argue that the mitigation of climate change requires state intervention and governance reform. Thus, governments use GIP to address the economic, political, and environmental issues of climate change. GIP is conducive to sustainable economic, institutional, and technological transformation. It goes beyond the free market economic structure to address market failures and commitment problems that hinder sustainable investment. Effective GIP builds political support for carbon regulation, which is necessary to transition towards a low-carbon economy. Several governments use different types of GIP that lead to various outcomes. The Green Industry plays a pivotal role in creating a sustainable and environmentally responsible future; By prioritizing resource efficiency, renewable energy, and eco-friendly practices, this industry significantly benefits society and the planet at large.

References

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  2. 1 2 Ziegler, Rafael (2023). "Exnovation". Encyclopedia of Social Innovation. ISBN   978-1-80037-334-1.
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  17. Heyen, Dirk Arne; Hermwille, Lukas; Wehnert, Timon (2017). "Out of the Comfort Zone! Governing the Exnovation of Unsustainable Technologies and Practices". GAIA - Ecological Perspectives for Science and Society. 26 (4): 326–331. doi:10.14512/gaia.26.4.9.


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