Towards More Sustainability: A Literature Review Where
Bioeconomy Meets Blockchain
Sven Willrich
1
, Felix Melcher
1
, Tim Straub
1
and Christof Weinhardt
2
1
FZI Forschungszentrum Informatik, Haid-und-Neu-Straße 10-14, 76131 Karlsruhe, Germany
2
Karlsruhe Institute of Technology, Karlsruhe, Germany
Keywords: Bioeconomy, Natural Resources, Sustainability, Blockchain, Literature Review.
Abstract: On the one hand, society has gradually grown awareness and importance of sustainability and natural
resources. On the other hand, blockchain technology gains increasingly interest and the impacts may have not
completely examined ecological, economical, and social. To present the state-of-the-art and hot topics within
bioeconomy and blockchain, we reviewed them equally and outlined future research threads. Based on a
systematic literature review combined with text mining and clustering, to enhance our data collection phase,
we describe a dedicated research thread and end up with real-word and possibly future-potential implications
driven by blockchain technology. Overall, this review gives important insights on how blockchain was and
could be engaged to add value towards sustainability at bioeconomy and natural resources.
1 INTRODUCTION
Bioeconomy brings natural resources and economy
together. It means being in exchange with natural
resources in a sustainable and responsible way while
using biological resources to undertake economic
activities (McCormick and Kautto, 2013). While
doing so, we consider scarce fossil natural resources
and general implications towards the climate change.
This kind of economy is trying to create a knowledge-
based production and usage of natural resources with
the goal of developing new products, procedures, and
services in all economic branches, with the focus of
providing a sustainable economy (Bioökonomierat,
2017). At the same time, with corporate social
responsibility (Orlitzky, Schmidt and Rynes, 2003)
and corporate sustainability (Gómez and Medel-
González, 2015) organizations are getting sensitized
and are taking such thoughts into the design and
distribution of products or services. Many researchers
agree upon the explicitly growing world population
cannot continue on the way they are currently in
exchange with natural resources and that new
sustainable ways to behave commercially are sought
after. It gradually becomes more and more important
to establish and to ensure a good governance to
natural resources (Devaney, Henchion and Regan,
2017). Hence, the topic around bioeconomy is also
touched politically, there are activities involved such
as participation and citizen science. As bioeconomy
normally includes a multitude of ecological,
economic and social parties with his own interests,
the cross-industries may consist of complex supply
chains. With blockchain has been arising, there is a
promising candidate to challenge uses cases where
trust between parties could be (is) an obstacle.
Theoretically, neither intermediaries are required nor
parties are enforced to trust somebody blindly in case
of an association (Nguyen, 2016) as they now are able
to get into business in a peer-to-peer topology.
In this contribution, we present a structured literature
review based on a text mining classification approach
(Yang, Zhang and Yan, 2017) (Yang and Hong,
2017). We use this procedure to cluster and classify
the literature results of the topic-related search
queries. Lastly, we discuss every auto-generated
cluster separately and go into depth, respectively.
2 LITERATURE REVIEW
In this paper, we want to analyze the state-of-the-art
in the field of bioeconomy and blockchain to suppose
possible future research threads. To do so in a clear
and structured way, we follow the guidelines from
Webster and Watson (Webster and Watson, 2002)
and in particular use a proven approach (vom Brocke
et al., 2009). This method is a framework organized
Willrich, S., Melcher, F., Straub, T. and Weinhardt, C.
Towards More Sustainability: A Literature Review Where Bioeconomy Meets Blockchain.
DOI: 10.5220/0007786301070114
In Proceedings of the 16th International Joint Conference on e-Business and Telecommunications (ICETE 2019), pages 107-114
ISBN: 978-989-758-378-0
Copyright
c
2019 by SCITEPRESS Science and Technology Publications, Lda. All rights reserved
107
in five phases. Each of the following sections
represent one of these five phases.
2.1 Definition of Research Scope
To define the scope of our research, we use the
taxonomy described by Cooper (Cooper, 1988).
The focus (1) of our literature review is to find
related practices and/or applications where
distributed ledger technologies (DLT) aka blockchain
are used in the field of bioeconomy. Because the
combination of bioeconomy / managing natural
resources with the technology of distributed ledgers
is not widely discussed, our goal (2) is to identify the
central issues within this field. The structure of this
review is organized (3) in a conceptual way. Written
with an espousal perspective (4), since we are
convinced the examination of distributed ledger
technologies is not sufficient. Especially with respect
to the context of bioeconomy and a ledger with a
distributed infrastructure, that could fit in the field of
communal used natural resources. We address a
specialized audience (5) with this review, because the
terms and concepts, especially in the scope of DLT,
need a deep understanding of cryptography,
distributed databases, and knowledge about the
patterns of communication within computer
networks. Lastly, since we ask several academic
databases with the same key words in a breadth-
oriented search, the review reaches a representative
coverage (6) of the topics.
2.2 Conceptualization of Topic
In the second phase (vom Brocke et al., 2009) we
describe the basic concepts and terms to put an
overview about the contextual definitions needed to
understand the basics of our research area helping us
to find new keywords for our literature search.
Bioeconomy is the knowledge-based production and
usage of natural resources, to create new products,
procedures, and services in all economic branches,
with the focus of providing a sustainable economy
(Bioökonomierat, 2017). Goals of bioeconomy are,
e.g., to change from fossil fuels as the economic
engine to an efficient economy based on sustainable
energy. In total, the topic spans from encouraging
consumer to be part in a bioeconomy value chain of
sustainable consumption until the protection of the
climate (McCormick and Kautto, 2013). It embraces
political and society topics alike, and range from
participation and citizenship to democratic and
1
A person or a group of people.
liberation approaches. It has the claim to include
everyone, because every individual has an effect on it
and the bioeconomy affects everyone.
The rise of Blockchain / Distributed Ledger
Technologies has most probably begun when Satoshi
Nakamoto
1
had published his understanding of the
blockchain technology in 2008 (Nakamoto, 2008). In
this connection, blockchain can be understood as one
potential implementation of a DLT (Cachin, 2016).
As conceptualized, the potentials come from its
distributed and decentralized structure resulting in
the missing necessity of any intermediary. Since
every central unit, e.g. technical, organizational, or
human agent can be supposed to be a black box.
Where the missing trust can become a problem,
blockchain provides an alternative way to interact
without it (Hawlitschek, Notheisen and Teubner,
2018). Hence, intermediaries might no longer be a
vital or indispensable part of transactions. Through its
public ledger and its consensus mechanism, the
transactions made on a blockchain are persistent in a
transparent, immutable, and traceable way
(Nakamoto, 2008) and consequently protected from
deletion, tampering, and revision (Iansiti and
Lakhani, 2017).
Furthermore, DLTs may have the ability to trigger
transactions automatically. With that feature, referred
to as Smart Contracts, DLTs are empowered to
execute programs at specific (time) events (Buterin
and others, 2014). The execution takes place as soon
as the event has occurred. These smart contracts also
enable a blockchain-based governance through the
concept of decentralized autonomous organizations
(DAO) (Reijers, O’Brolcháin and Haynes, 2016b).
The main purpose of a DAO is the decentralized
governance of “computerized rules and contracts”
(Chohan, 2017) in a transparent manner. We argue
that this kind of governance can be a promising
candidate for satisfying participatory requirements
needed for an effective bioeconomy.
2.3 Literature Search (Data Collection)
In this section, we have documented our literature
search. The research fields we target are relatively
new, that is why we do not set any boundaries such as
specific journals or conferences. At the end of this
section and with this information in mind, we want to
identify journals and conferences that cover our
research topics blockchain and bioeconomy most
suitable.
ICE-B 2019 - 16th International Conference on e-Business
108
For the field of bioeconomy, several synonyms
are existing while each meaning slightly differ.
Therefore, we have used the three most common
terms for this, i.e., bioeconomy, bioeconomics,
bioeconomic. In addition, DLT is not widely used in
publications, mostly the authors refer to blockchain
and use this term as the generalized name for the
technology. As a result, our first search query was
(blockchain AND (bioeconomy OR bioeconomics
OR bioeconomic))
2
.
In behalf of a comprehensive understanding of
our data collection phase, we explain the procedure in
more detail: We used a tool that calls the application
programming interfaces (APIs) of research databases.
These are IEEE, Springer Link, Elsevier, Crossref
and arXiv as they provide a convenient way to receive
machine-readable data for further analyses. The data
collection process consisted of three steps. In the first
step, we sent search query requests to the APIs. In the
second step, the query results got cleansing, which
consists of identifying and cleaning up duplicates,
removing papers not written in English (for better text
mining results), and information aggregation due to
different results emerged by different databases for
the same publication. In the final step, we saved the
results in a file-based database.
Our literature search took place in the period from
May to July of 2018. According to scope definitions
(Cooper, 1988), the final search (including the total
count) phrases to build our document corpus are the
following: Blockchain Democracy (5.879),
Blockchain Government (11.010), Blockchain
Sustainability (10.188), Blockchain (4.738),
Decentralized Autonomous Organization (19.549),
Distributed Ledger Technology (21.249), Natural
Resource Blockchain (13.109).
2.4 Literature Analysis and Synthesis
This section describes how we have analyzed the
(meta) data within the document corpus and shows up
some data insights. The next step in our analysis was
to cluster the publications with basic algorithms of
natural language processing (NLP) (Manning and
Schütze, 1999).
We have used the abstracts and titles to build a
bag of words corpus where we, have removed
2
An iterative process has led to an optimized query that
differs from our final search query yielding meaningful
results with respect to our research area, e.g., our first
query for bioeconomy had led to deep biology research
that are generally out of the scope of our review.
common and field-specific stop words, and stemmed
the sentences to tokens. After that, we have calculated
the Term Frequency Inversed Document Frequency
(TF-IDF) weight
3
. Next, to find overlapping research
fields and to identify often-covered fields within our
topics, we have clustered the TF-IDF of each
document. This procedure is partly based on an
existing contribution on how performing literature
review by text mining (Yang, Zhang and Yan, 2017)
(Yang and Hong, 2017). To conduct our clustering,
we have applied K-Mean
4
to identify groups in our
dataset. To determine the optimal number of clusters,
we have used the common method in unsupervised
learning, the elbow method. To find the best k, we
have calculated the distortion score (sum of squared
errors) for a different number of k, in our case 1-10,
as we have sought for the smallest k with a low score.
The basis for our clustering is the TF-IDF matrix
.
Figure 1: Publications per year.
containing all tri-gram tokens in our corpus. We
reduced the corpus size before the clustering by
filtering out all data records without an abstract and
with less than two citations.Finally, after we have
reached our clusters, we have classified them
manually based on the top terms.
One result of the metadata analysis is an overview
about the publication rate over time in research for
our topics (Figure 1). This chart gives insights that the
research field around blockchain technology and
bioeconomy is continuously rising in the past years.
Developed in 2009, Bitcoin (and therefore the
blockchain) is not widely mentioned in any
publications before 2014. While bioecnomy has been
3
The TF-IDF is a statistical method used to evaluate how
important a word is within a document compared to the
whole corpus.
4
The k-means algorithm groups data by separating the
samples in n clusters of equal variance, trying to
minimizing the sum-of-squares.
Towards More Sustainability: A Literature Review Where Bioeconomy Meets Blockchain
109
a research objective for over the last decades. The
publication date analysis makes visible that since
2007 the count of released publications is soaring.
This explains that this topic is also becoming more
relevant in research in the recent years. The container
type
5
shows us that there are already popular
conferences and workshops explicitly concerned to
DLTs and blockchains, although it is only one decade
old, there are already 200 papers each year since 2016
and over 1500 each year since 2017. The “Journal of
Bioeconomics” is the most popular under all
containers in the field of bioeconomy
The following sections are descriptions of the
most cited publications within each of the four
clusters the k-means algorithm has calculated. The
results of the cluster analysis are available in a
GitHub repository
6
.
Supply Chain Management (SCM) is one of the
possible use cases in DLT sector and one of our
clusters. The SCM is an often-discussed application
type in the field of Distributed Ledgers (Iansiti and
Lakhani, 2017). Is useful to identify actors who are
involved in (Toyoda et al., 2017) to optimize. The rise
of a connected industry i.e. through the Internet of the
Things (IoT) takes a supporting role in a digital SCM
(Haddud et al., 2017; Kshetri, 2018). We analyzed a
papers for real-time information sharing during the
distribution phase of a product (Nakasumi, 2017) to
optimize the workflows to increase the transparency
between parties. To secure the post supply chain,
some IEEE members (Toyoda et al., 2017) proposed
a Product Ownership Management System (POMS)
based on a distributed ledger. Martin Holland et al.
describe a blockchain based digital rights
management system to secure the copyrights of,
especially safety-critical, products (Holland,
Nigischer and Stjepandic, 2017).
Another example to avoid counterfeiting with a
blockchain to fight against an international fake
medicine market was examined (Mackey and Nayyar,
2017). A more complex analysis of the healthcare
market and the possible adoption is described in
(Clauson et al., 2018). Feng Tian (Tian, 2016)
addresses the agrifood supply chain in Chinas
constantly growing economy. They developed a
system, which covers the whole process of
information retrieval and management in a agrifood
supply chain, which includes the monitoring, tracing
and traceability management for the quality and
5
Generic field for journals, conferences, workshops etc.
6
Find repository https://github.com/melcherf/ .
literarure-review_bioeconomy-blockchain at the commit
id: 64bf59d9dccf980f6b873e96b04510e914e3f916
safety "from farm to fork" (Tian, 2016). They argue
that China loses every year 170 billion Renminbi
(RMB) in the agriculture industry because of quality
problems and losses in supply chains (Chen et al.,
2017). There problems are avoided that traditional
centralized trust mechanism cannot solve.
While looking at SCM, the blockchain was used
to the management of energy. With microgrid energy
markets (Mengelkamp, Notheisen, et al., 2018),
(Mengelkamp, Gärttner, et al., 2018), (Zhumabekuly
Aitzhan and Svetinovic, 2016), the trading between
self-producer and consumer (i.e., prosumers) in a
peer-to-peer network is understood.
To build the bridge between bioeconomy and
blockchain from the energy application’s point of
view, the blockchain is effectively applicable
whenever the existence for central actors should be
vanished. If we argue from the natural resource
management perspective of the forest, it is desirable
to merge small forests together (Bundesministerium
für Ernährung und Landwirtschaft (BMEL), 2008).
This way, decentralized coordination purposes with
partners on eye level can leverage the emergence of
such associations in a transparent and efficient way.
Blockchain Protocol is the biggest cluster, mainly
focused on the Bitcoin design, outlining the fields of
security, privacy, smart contracts, the decentralized
architecture and possible on-chain applications. In a
historical overview (Bonneau et al., 2015), they
describe the origin of the first cryptocurrencies. They
also give an exhaustive technical overview about the
Bitcoin design decisions including the Bitcoin
Improvement Proposals (BIPs), developer mailing
lists, trying to cover the current specifications, which
has continuously refined since the release of the
original Bitcoin white paper (Nakamoto, 2008). A
selection of the specifications they describe are the
transactions, consensus, block confirmation,
(incentivized) mining and the impact on the
consensus. Further, they discuss the client-side
security, anonymity, modification of the protocol and
alternative consensus algorithms. This work is highly
recommendable to get a widely overview about the
Bitcoin protocol. In a more on the peer-to-peer
network focused paper (Decker and Wattenhofer,
2013) the information propagation between the nodes
is researched. They investigated the methods used to
broadcast the transactions and blocks through the
network and verify the aspect that a delay in this
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broadcasting could result in a fork
7
of the blockchain.
They also address possible improvements and
emphasize several challenges towards architectural
limitations. Non-determinism might be a problem.
Also described in this cluster are the Smart contracts,
the decentralized applications running on a
blockchain. They are applicable in several domains,
e.g., crowdfunding, financial services, identity
management, and gambling. It touches topics like
cryptography, consensus algorithms, and
programming languages until governance, finance,
and law (Buterin and others, 2014). To use the
benefits of blockchain without cryptographic
knowledge, a cryptographic protocol allows
programmers to write private smart contracts in an
intuitive manner (Kosba et al., 2016). Further
research concentrates on how making smart contracts
to be smarter and more secure. During the
investigation of security aspects, they have revealed
problems that may be utilized by adversaries to gain
profit and have argued how such vulnerabilities could
be reduced and security be increased (Luu et al.,
2016a). One task they describe is to enhance the
security within contracts; another task is to make the
input more trustworthy. Concerning this matter,
thoughts have given to trustworthy data feeds acting
as a bridge between blockchain and non-blockchain
applications. Following this, a blockchain application
to ask HTTPS-enabled websites was developed and
serves as a source-authenticated data to relying smart
contracts (Zhang et al., 2016).
Not just offline existing parties are able to
collaboration, coordination or cooperation across
organizations over the bitcoin protocol, but also
digital ones, i.e., a decentralized autonomous
organization (Luu et al., 2016b). DAOs are
organizations based on smart contracts (Swan, 2015).
When such DAOs are organized in business
networks, cross organization collaboration gets
possible (Norta, 2016). To take decisions
democratically, mechanisms to organize and conduct
elections are required, thus another research team
tackles voting realized by dedicated blockchains or
smart contracts (Yavuz et al., 2018a). To handle a
digital organization adequately, every-day and
strategic decisions are required in a recurring manner.
On the question of how such voting systems are
possible, a simple implementation is made (Yavuz et
al., 2018b).
7
A fork is a split of the blockchain in two separated ledgers
with the same history but a different protocol for the future
and is mostly unintended.
These findings address the challenges of
Bioeconomy. As already introduced, bioeconomy
implies the involvement of various parties working
together in, i.e., supply chains or associations where
previously independent organizations are merged.
Smart Contracts may help to set up an (decentralized
autonomous) collaboration, to organize it and to make
processes / decisions more efficient and timesaving.
Governance, the process of governing (Bevir, 2012).
To manage (social) systems and/or organizations, we
undertake several tasks to hold it healthy and make it
work. In literature, the implications of blockchain
governance are discussed, i.e., how owners and
managers of public companies are affected during
tasks around corporate governance (Yermack, 2017).
In this way, blockchain implications range from
technical to economic and strategic areas and may
trigger a need for institutional changes where
operative and organizational processes is affected.
For example, the information stewardship changes
while data is stored in the blockchain (Ølnes, Ubacht
and Janssen, 2017), apart from that it faces corruption
and wrongdoing perpetrated by frauds (de Souza,
Luciano and Wiedenhöft, 2018) through the aid of
transparency, immutability, and traceability. To
understand blockchain not just as a technology
enabler, but also as a possible next step towards
institutional evolution, decentralized, democratic,
and self-organized ideas come in (Davidson, De
Filippi and Potts, 2018). Banking is one of the most
popular domains in that blockchain-driven
disruptions arise, including how banks work as
organizations too, i.e., such a conventional and
centralized hierarchical organization is discussed to
be shifted into those democratic, decentralized, and
self-organized ones (MacDonald, Allen and Potts,
2016). When considering social and society aspects,
various governance models can be taken into account,
hereof researchers have examined the interaction
between blockchain and social contract theories
(Reijers, O’Brolcháin and Haynes, 2016a). Another
example was given by a libertarian viewpoint with its
remarkable resemblance to blockchain properties as
both bypass central authority and provide anonymity
(Huckle and White, 2016), but coordination and
reaching consensus could become more complex
(Shermin, 2017).
Bioeconomy may benefit from those blockchain-
driven developments as it also affects participation,
citizen science, governance, cross-industrial areas,
Towards More Sustainability: A Literature Review Where Bioeconomy Meets Blockchain
111
and SCM. Especially natural resources touch every
individual alike and are hence worth considering in a
democratic and representative way.
Decentralized Networks depicted in this chapter are
dealing with the papers in the cluster about mulit-
agent systems (MAS), the self-organization of
vehicles and robotic automation and wireless sensor
networks. In a vision of an effective bioeconomy
future, intelligent agents will do the work. Often
referred to as self-organized systems, MAS has many
similarities with a blockchain. To mention one, they
both need a distributed consensus algorithm to ensure
the integrity of the data send between their nodes or
agents (Saber, Fax and Murray, 2007). One popular
paper we discovered is about a theoretical framework
to analyze consensus algorithms in MAS with fixed
or dynamic network topology (Saber, Fax and
Murray, 2007). The scope of the framework is about
the information flow, the robustness when network
nodes fail, delays in time and shows the possible
guarantee of performance with different consensus
algorithms. In another paper (Willke, Tientrakool and
Maxemchuk, 2009), they surveyed inter-vehicle
communication (IVC) protocols and applications of
the last decade to classify them, depending on their
information propagation and consensus into four
types: General, Safety, group planning and individual
planning & regulation. Consensus algorithms for a
decentralized control of communicating-agent
systems are also discussed and analyzed (Xie and
Wang, 2005). Also the connectivity and coverage in
wireless sensor networks, used in military, industry,
agriculture, urban management, and their impact on
the quality of service is discussed (Zhu et al., 2012).
They examine current research results, solutions and
problems with focus on energy efficiency. To ensure
the authenticity and integrity of the data gathered by
sensors a blockchain could be a possible solution. In
our research field, MAS as well as wireless sensor
networks and the automation of processes could have
a huge impact on the development of an autonomous
organized bioeconomy.
3 RESEARCH AGENDA
In our structured literature review, we have examined
the state-of-the-art and most cited literature towards
the concepts of bioeconomy and blockchain found
with our keyword-driven approach. All in one, we
have identified several dedicated research threads by
our clustering approach. We describe each separately
and conclude each with relevant implications
between bioeconomy challenges and blockchain
solutions. Since there was no cluster dedicated
explicitly to bioeconomy and blockchain, it seems
worth to higher research efforts in this domain.
Literature have focused on supply chain management,
government and application development with smart
contracts on public domains or where companies
come together to work in an association with no
longer need for an intermediate. Especially the topic
around supply chain management and government
arises as a promising candidate to enhance
bioeconomy-oriented activities since transparency,
immutability and in general the benefits of
digitalization are driver to revolutionize
collaboration. Looking at resource management,
many efforts have flowed into energy tasks such as
Energy Internet, but natural resources have not been
an objective of research so far.
As for all publications to blockchain, it is true that
they are not the solution for all problems we are
currently facing and a requirement-driven approach is
advisable. Despite the benefits of blockchain, the
underlying question is related to trust (Beck et al.,
2016), i.e., is there any trust problem justifying the
blockchain application or can we meet our
requirements with a central and trustable party too?
Based on the review’s findings and the contemporary
challenges in the field of bioeconomy, blockchain and
its beneficial features are worth considering.
Especially when taking into account that DLT is in an
early state and scientifically not examined
completely, the impact is not sufficiently clear.
Therefore, further research may address the whole
system bioeconomy is embraced by. In particular,
including the society and all relevant stakeholder to
socialize the process of natural resources decision-
making by an appropriate blockchain design. Care for
transparency on society-affecting decisions and
provide a basis for natural resource governance in a
democratic manner and for the benefit of climate and
according to the Sustainable Development Goals
(SDGs) (Group et al., 2015).
4 CONCLUSIONS
We have made a contribution embracing two high-
rated and important topics, i.e., to what extent have
researchers examined how blockchain can support
sustainability towards natural resources within the
bioeconomy. In order to approach the topic, we have
conducted a systematic review by hybridization of the
proposed literature review process (vom Brocke et
al., 2009) and state-of-the-art text mining procedures
to receive clusters to be examined. We argue for this
ICE-B 2019 - 16th International Conference on e-Business
112
methodology as it allows reaching the cluster
emergence automatically and enables us to divide the
whole topic into dedicated areas that we have called
research threads all of these in a deterministic,
replicable, and justified way. We have described each
cluster by reviewing the state-of-the-art (backwards)
and with discussion of possible implications,
potentials and challenges in the field of bioeconomy
and blockchain (forward).
Further, our literature review demonstrates that
both bioeconomy and blockchain in combination are
a promising candidate to become an emerging
interdisciplinary research field. Driven by this
anticipation, challenges the bioeconomy is
contemporary faced with and the solutions the
blockchain technology provides this review shows
a growing activity and attention in both of them
fields.
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