Knowledge Transfer in Regulatory Analytical Sciences through the
Implementation of Communities of Practice
Joanna Jesionkowska
1
, Brigitte Denis
2
and Philip Taylor
1
1
The Institute for Reference Materials and Measurements, Joint Research Centre, European Commission
2
Department of Education and Training, University of Liège, Liège, Belgium
1 STAGE OF THE RESEARCH
This doctoral project started at the beginning of the
academic year 2013-2014 at the Department of
Education and Training, University of Liege under
the supervision of B. Denis and P. Taylor. The first
step of the work, the need analysis (see section 5.2.)
is almost finished. The literature review on the two
main aspects of the thesis (communities of practice
supported by technologies, knowledge transfer) is
ongoing. The research question and hypotheses are
defined as the general methodology linked to them.
The thesis is planned for three years.
2 OUTLINE OF OBJECTIVES
This project purpose is studying how the
development of a Community of Practice supported
by Information and Communication Technologies
enhances the transfer, capitalisation and production
of knowledge between scientists (experts and
novices) in the context of the European Commission
- Joint Research Centre - Institute for Reference
Materials and Measurements (EC-JRC-IRMM)
measurement and standards activities.
The aim is create the space where scientists
(analytical chemists) would have the opportunity to
interact, share the experience, search specific
information in the area of their interest, map the
knowledge and identify the gaps, solve the problems
together, seek for experience and coordinate shared
projects. The scientists who are geographically
dispersed could work together using appropriate
technology to access each other: remote tools,
databases, and instruments (National Research
Council, 1993). Community of practice could
provide such space for discussion and professional
development of its members.
3 RESEARCH PROBLEM
Today, organisations, workgroups, teams, and
individuals work together in new ways. Inter-
organisational collaboration is increasingly
important. Communities of practice provide a new
model for connecting people in the spirit of learning,
knowledge sharing, and collaboration as well as
individual, group, and organizational development.
This gives new possibilities which could be used in
scientific environment.
Most scientists are involved in international and
interinstitutional projects. They share information,
work together in teams and manage tasks throughout
different organizations and diverse geographic
locations. Very often the work and documentary
output mainly rely on traditional communication
tools, mainly cumbersome email, which does not
give the visibility on the conversations and
document postings. There is also no benefit from a
community which grows around given
network/activity.
Promoting affiliation between scientists is
relatively easy, but creating larger organizational
structures is much more difficult, due to traditions of
scientific independence, difficulties of sharing
implicit knowledge, and formal organizational
barriers. (Bos, Zimmerman, Olson, Yew, Yerkie,
Dahl & Olson 2007). There is a long tradition of
informal, one-to-one collaborations between
scientists, but the scientific environment lack the
model of more tightly coordinated, large-scale
organizational structures.
There is a need to search for a new way of
working together that would solve the problems: a
network-based space that spans distance, supports
rich and recurring human interaction oriented to a
common research area, fosters contact between
researchers who are both known and unknown to
each other, and provides access to data sources,
artifacts and tools required to accomplish research
tasks (Wulf, 1989)
18
Jesionkowska J., Denis B. and Taylor P..
Knowledge Transfer in Regulatory Analytical Sciences through the Implementation of Communities of Practice.
Copyright
c
2014 SCITEPRESS (Science and Technology Publications, Lda.)
Hence there is a need to research possibilities given
by CoPs in the area of sciences and develop and
optimize the solutions to supports its activities.
4 STATE OF THE ART
4.1 Knowledge Transfer in an
Organisation
Knowledge is socially embedded and highly
context-specific, and these characteristics make it
difficult to transfer knowledge (Brown & Dugid,
1998). The process of knowledge transfer requires
commitments of resources, managerial time,
attention, and effort (Chen, 2004; Easterby-Smith,
Lyles, & Tsang, 2008). Knowledge transfer is a
socially collaborative construct, management
scholars have long recognized its contextual nature
(Björkman, Barner-Rasmussen, & Li, 2004; Foss &
Pedersen, 2002; Lyles & Salk, 1996). Knowledge-
sharing behaviours, in terms of knowledge giving
and knowing receiving, are significantly predicted
by prosocial commitment and performance
expectation (Tseng & Kuo, 2014).
Knowledge transfer (KT) seeks to organise,
create, capture or distribute knowledge and ensure
its availability for future users. KT is complex
because knowledge resides in organisational
members, tools, tasks, and their subnetworks
(Argote & Ingram, 2000) and much knowledge in
organisations is tacit or hard to articulate (Nonaka &
Takeuchi, 1995). The knowledge gained by research
is often isolated from the practitioners in the field.
Likewise, tacit knowledge from the field rarely
reaches the researchers or those making decisions.
More effective bridges between knowledge, policy
and practice are needed, with communities of
practice (CoPs) well positioned to do that (Hearn &
White, 2009).
Knowledge in the organisation can refer to the
theoretical or practical understanding of a subject. It
can be implicit (as with practical skill or expertise)
or explicit (as with the theoretical understanding of a
subject); it can be more or less formal or systematic.
There are three kinds of knowledge: "knowledge as
object", "knowledge embedded within individuals",
and "knowledge embedded in a community" (Wasko
& Faraj, 2000). Communities of Practice have
become associated with finding, sharing,
transferring, and archiving knowledge, as well as
creating explicit "expertise", or tacit knowledge.
Tacit knowledge is considered to be those valuable
context-based experiences that cannot easily be
captured, codified and stored (Davenport & Prusak,
2000; Hildreth & Kimble, 2002).
Because knowledge management is seen
"primarily as a problem of capturing, organising,
and retrieving information, evoking notions of
databases, documents, query languages, and data
mining" (Thomas, 2001), the community of practice,
collectively and individually, is considered as a rich
potential source of helpful information in the form
of actual experiences. Thus, for knowledge
management, a community of practice is one source
of content and context that if codified, documented
and archived can be accessed for later use.
4.2 Communities of Practice and
Information and Communication
Technologies
A community of practice is a group of people who
share a common concern, a set of problems, or
interest in a topic and who come together to fulfil
both individual and group goals (Wenger, 1998;
Wenger, 2002). CoPs often focus on sharing best
practices and creating new knowledge to advance a
domain of professional practice. According to
Wenger (1998), people who want to participate in
CoPs get ready to share their knowledge, sharpen
their expertise, build up interpersonal networks and
pursue their interest. Different roles appear among
the CoP members and, in certain contexts, the
presence of an animator is necessary to facilitate
their activities (Snoeck, 2010). A CoP emerges
spontaneously or/and through a participatory design
process (Ashwin, 2009). Communities have
lifecycles—they emerge, they grow, and they have
life spans (Kaplan & Suter, 2005). Wegner (2004)
described that CoPs continually evolve through five
stages: potential, coalescing, maturing, stewardship
and transformation.
Face-to-face or virtual interactions on an on-
going basis are an important part of this. An
important feature of virtual communities is to bring
knowledge seekers and providers into one virtual
space that is equipped with knowledge databases
over networks (Shin & Kook 2014). Virtual CoPs
help knowledge management by capturing and
sharing of the expertise of members, spreading
know-how, ideas, problems, innovations, talents,
and experiences. Nowadays, much knowledge
sharing and knowledge construction takes place in
online environments (Kimmerle et al., 2013). These
communities use a variety of communication tools
(e.g., via discussion board, article commenting,
rating, poll, wiki, webinar) to foster discussion and
KnowledgeTransferinRegulatoryAnalyticalSciencesthroughtheImplementationofCommunitiesofPractice
19
the exchange of ideas (Wenger et al, 2010).
Since the widespread adoption of the Internet,
management scholars in general, and information
systems researchers in particular, have emphasized
how knowledge-work depends not only on new
communication affordances but also on the
behaviors and motivations of those who undertake
and manage it (Newell et al., 2009). Learning in
online environments is supported by three presences
– social presence, teaching presence, and cognitive
presence – that work together to support deep and
meaningful inquiry and learning online (Swan et al.,
2014). Prominent works focus on co-located or
distributed work groups (Dourish & Bly, 1992;
Gupta et al., 2009), project teams (Kietzmann, et al.,
2013; Evaristo et al., 2004; Oshri et al., 2008),
consortia, alliances, and joint ventures (Ibrahim &
Ribbers, 2009; Miles & Snow, 1995).
The community knowledge is a social concept of
knowledge as conceptual artifacts that have a public
life (Bereiter, 2002; Hyman, 1999; Popper, 1972). It
is public knowledge ideas made accessible to all
community members through contributions to
collective knowledge spaces. Community
knowledge involves a dynamic process interactions
between ideas and people knowledge (i.e., knowing
people’s expertise) with participants monitoring who
is working on what ideas or problems and advancing
knowledge in the community (Hong & Lin-Siegler,
2012). The community knowledge is the cultural or
intellectual capital of the community (Scardamalia
& Bereiter 2003, Hong & Scardamalia 2014).
4.3 Domain: Regulatory Analytical
Sciences
Modern societies are highly dependent on analytical
measurements. They play an important role not only
in science, but also in daily life. Based on the results
of such measurements decisions are taken regarding
health, food safety, manufacturing of goods, the
development of innovative products, the quality of
our environment, trade of goods and commodities;
Analytical chemistry is the study of the
separation, identification, and quantification of the
chemical components of natural and artificial
materials (Holler, Skoog, & West, 1996). Qualitative
analysis gives an indication of the identity of the
chemical species in the sample and quantitative
analysis determines the amount of one or more of
these components.
The Regulatory Analytical Sciences (RAS) objective
is to apply analytical science in the public interest,
acting as the referee analyst in cases of dispute and
providing advice to policy makers and industry. The
principal roles of RAS are:
• To act as an independent and impartial
referee analyst, authorised analyst and analyst by
reference to or pursuant to certain legislation,
• To be a source of advice for policy makers
and the wider analytical community on the analytical
chemistry implications on matters of policy and of
standards and of regulations.
Performing reliable measurements is not trivial and
requires knowledge and skills. Therefore training
and education in this area is important. The Joint
Research Centre (JRC) runs a life long learning
activity (www.trainmic.org) and fosters educational
activities in this area.
4.3.1 Context of the EC-JRC-IRMM's
Measurement and Standards Activities
The Joint Research Centre (JRC) is a European
Commission's in-house science service and a
reference centre interacting closely with Member
State institutions. As a service of the European
Commission, the JRC functions as a reference centre
of science and technology to provide customer-
driven scientific and technical support for the
conception, development, implementation and
monitoring of EU policies and legislation. JRC is
constituted of seven institutes. One of them, the
Institute for Reference Materials and Measurements
(IRMM) supports industrial competitiveness, quality
of life, safety and security in the EU by developing
advanced measurement standards and providing
state-of-the-art scientific advice concerning
measurements and standards for EU policies. One of
IRMM's objectives is to act as a learning and
knowledge hub on standardisation and measurement
in Europe, particularly in analytical sciences. A unit
of IRMM, the Knowledge Transfer & Standards for
Security (KNOTSS) is in charge of training
laboratory staff, researchers, educators, decision-
makers and accreditation assessors in metrology in
chemistry, in order to strengthen the measurement
infrastructure.
Thirteen years ago, KNOTSS has developed the
TrainMiC® programme. It is based on organisation
of one day workshops (theory and exercises) and
providing learning materials to the participants. The
training methodology does not provide a large space
to share knowledge between scientists. The
opportunity to interact and share experiences and
knowledge is not enhanced outside this meeting.
Professionals stay isolated in their laboratories. Then
the objective of exploiting the potential of the actors
IC3K2014-DoctoralConsortium
20
(especially the experts), of transfer, capitalisation
and knowledge production is difficult to reach. A
solution could be found in developing a Community
of Practice between these professionals.
5 METHODOLOGY
This study resorts to qualitative and quantitative
methods, such as interviews, focus groups,
questionnaires, observation grids. It is based on
participatory design. Actors are involved at the
different steps of the work. Details are provided in
section 5.3, after the presentation of the project’s
steps and tasks below.
The data collected will help us to test the
following hypotheses.
5.1 Hypotheses
H1. The creation of a CoP supported by ICT
matches learning needs of Actors of Regulatory
Analytical Sciences.
H2. The CoP’s life is conditioned by a participatory
design process.
H3. The presence of an external facilitator is
considered as necessary by the CoP’s members to
start the CoP’s activities.
H4. Core CoP’s members take autonomously in
charge the CoP’s animation.
H5. Both CoP’s experts and novices members share
their own knowledge on M&S.
H6. Novices are more motivated to participate to the
CoP than experts in the field of M&S
H7. CoP’s members capitalise knowledge on M&S.
H8. CoP’s members generate new knowledge on
M&S.
5.2 Steps and Tasks of the Research
Four main phases are identified to conduct this
project.
Step 1: Need analysis
- Make actors’ cartography at different
systemic levels and roles description.
- Identify key stakeholders and final users
(among TrainMic® actors) to constitute the group of
people to carry on the participatory design process
(from needs analysis to implementation) of a new
learning environment.
- Among TrainMiC® actors, identify why
changing is necessary, specific needs, key issues and
the nature of the learning, major topics, knowledge
and tasks that the community would steward,
primary purpose, potential benefits, goals and vision
for relevant community.
- Analyse the context to ensure the feasibility
of the creation of a CoP supported by ICT (e.g.
actors’ level of ICT uses, available technologies,
technical team, budget…).
- Feed the needs analysis with existing
experiences inside and outside the IRMM unit.
Step 2: Design of the CoP
- Determine CoP’s actors’ roles.
- Identify degrees of expertise (expert,
novice…) in the field of M&S of potential CoP’s
members.
- Choose (or/and develop) a technological
solution to communicate, share and collaborate that
will generate interactions, energy and engagement,
learning goals…
- Start the recruitment of a core team of
individuals who represent the community audience.
- Create a mission and vision: alignment of
interests.
- Choose together the major topic areas for
community content and exploration, potential
categories of activities that community members are
likely to want to carry out in the community,
communication paths…
- Familiarise the members to the use of the
ICT tools (e.g. create a directory or folder structure
for organizing resources, interact in forums, edit
shared documents…)
- Lay out a tentative schedule for the
community (weekly, monthly, quarterly, and/or
annually), create a timeline for the community’s
development.
Step 3: Piloting the activity
Engaging members in collaborative learning and
knowledge sharing activities, group projects and
networking events that meet individual, group and
organisational goals, while creating and increasing
cycle of participation and contribution.
- Test community-oriented technology
features to support the goals of the pilot, test the
functionalities through case scenarios.
- Implement the community prototype and
give access to the core team and pilot audience.
- Seed the community with content.
- Facilitate events and activities to exercise
the prototype, focusing on achieving short-term
value-added goals.
Step 4: Evaluation and regulation
Observe the CoP development process (actors’
enrolment, community identity, types of activities,
KnowledgeTransferinRegulatoryAnalyticalSciencesthroughtheImplementationofCommunitiesofPractice
21
online environment uses, community culture, etc.).
Refine the strategy. Establish a success story.
5.2 Methods and Instruments
In step 1: Need analysis
- Interviews of IRMM coordinators, TrainMic®
team members (stakeholders, trainers, trainees).
- Institutional documents analysis.
- Interviews and/or focus groups, TrainMic®
documents.
- Questionnaires
- Interviews
- Analysis and literature review about CoPs
In step 2: designing of the CoP
Participatory design methodology (Charlier, Henry
et al. 2009)
- communication and collaboration through face-to-
face and virtual meetings
- use of learning design models
- interviews
- questionnaires
In step 3: Piloting the activity
- Opinion questionnaires and interviews.
- Focus groups.
- Traces analysis of members’s activity:
* connections, use of the technological tools, types
of interactions…
* counting and categorisation of shared resources.
* organisation of shared resources.
- Direct observation.
In step 4: Evaluation and regulation
Permanent regulation through observations and
CoP’s members constraints and needs.
Measure success and report on the results of the
prototype to stakeholders.
6 EXPECTED OUTCOME
The Community of Practice supported by
Information and Communication Technologies
should enhance the transfer, capitalisation and
production of knowledge between scientists.
Planned activities of JRC stewarded knowledge
community would be:
sharing and exchanging information on existing
and new technical/scientific and legislative
developments in this field
building a consensus opinion on sensitive policy
issues starting from scientific-technical
interaction
organising scientific events and seminars and
particularly science-policy interfacing events
providing training and set up sustainable Life
Long Learning activities
influencing educators and fostering education ,
e.g. via summer schools
promoting the harmonisation of measurements
and co-ordinate QA/QC activities
performing method development and validation,
harmonising practice, participating to
standardisation activities
developing common research projects and pilot
studies
A model of a CoP created for the context of the EC-
JRC-IRMM's measurement and standards activities
could be used in a future to create CoPs in other
areas of interests of Regulatory Analytical Sciences.
REFERENCES
Argote, L., & Ingram, P. (2000). Knowledge transfer: A
Basis for Competitive Advantage in Firms.
Organizational Behavior and Human Decision
Processes 82 (1), 150–169.
Ashwin, P., Daele, A., Barlatier, P., Charlier, B., Denis,
B., Henri, F., Jacquemart, S., Künzel, M., Rieppi, S.,
Rossier, A., Van de Wiele, N. (2009). PALETTE:
Learning and Organisational Resources: Conceptual
Instruments for Self- Analysis, Learning and
Developments of CoPs, External report ERCIM,
Report number: D.PAR.06.
Bereiter, C. (2002). Education and mind in the knowledge
age. Mahwah, NJ: Lawrence Erlbaum Associates.
Björkman I., Barner-Rasmussen W., Li L. (2004):
Managing knowledge transfer in MNCs. A
comprehensive test of headquarters control
mechanisms. Journal of International Business Studies,
35 (5): 443-454.
Brown J.S., Duguid P., (1998) Organizing knowledge,
California Management Review 40 (3) 90–111.
Chen C. (2004) The effects of knowledge attribute,
alliance characteristics, and absorptive capacity on
knowledge transfer performance R&D Management
Volume 34, Issue 3, pages 311–321.
Davenport, T. H., & Prusak, L. (2000). Working
knowledge. How organizations manage what they
know, 2nd Edition. Cambridge, MA: Harvard Business
School Press.
Easterby-Smith, M., Lyles, M., Tsang, E. (2008) Inter-
Organizational Knowledge Transfer: Current Themes
and Future Prospects Journal of Management Studies,
Volume 45, Issue 4, pages 677–690.
Evaristo, R.J., Scudder, R., Desouza, K.C. (2004). A
dimensional analysis of geographically distributed
project teams: A case study. Journal of Engineering
Technology Management, 21(3), 175-189.
IC3K2014-DoctoralConsortium
22
Foss N, Pedersen T. (2002) Transferring Knowledge in
MNCs: The Roles of Sources of Subsidiary Knowledge
and Organizational Context. Journal of International
Management 8: 1-19.
Gupta, J. et. al. (2009). Evidence-Based Practice
Academic Partnerships. Presented at the 2009 AOTA
Annual Conference and Expo, Houston, TX April 23-
26.
Hearn, S., White, N. (2009) Communities of practice:
linking knowledge, policy and practice Overseas
Development Institute 2009. ISSN 1756-7610.
Hildreth, P., & Kimble, C. (2002). The duality of
knowledge . Information Research 8.
Holler, F. J., Skoog, D. A., West, D. M. (1996).
Fundamentals of analytical chemistry. Philadelphia:
Saunders College Pub.
Hong H., Scardamalia M. (2014) Community knowledge
assessment in a knowledge building environment
Computers & Education, Volume 71, February 2014,
Pages 279-288.
Hong, H., Lin-Siegler, X. (2012) How learning about
scientists' struggles influences students' interest and
learning in physics. Journal of Educational
Psychology, Vol 104(2).
Hyman, J. (1999) How Knowledge Works. The
Philosophical Quarterly 49: 433 – 51.
Ibrahim, M.K.M., Ribbers, P.M.A. (2009). The impacts of
competence-trust and openness-trust on
interorganizational systems. European Journal of
Information Systems, 18(3), 223-234.
Kaplan S., Suter. V. (2005). Community of Practice
Design Giude, A Step-by-Step Guide for Designing &
Cultivating Communities of Practice in Higher
Education. Darren Cambridge.
Kietzmann J., Plangger K., Eaton B., Heilgenberg K., Pitt
L., Berthon P. (2013) Mobility at work: A typology of
mobile communities of practice and contextual
ambidexterity The Journal of Strategic Information
Systems, Volume 22, Issue 4, Pages 282-297.
Kimmerle J., Thiel A., Gerbing K., Bientzle M.,
Halatchliyski M., Cress U. (2013) Knowledge
construction in an outsider community: Extending the
communities of practice concept Computers in Human
Behavior, Volume 29, Pages 1078-1090.
Lyles, M., Salk, J. (1996) Knowledge acquisition from
foreign parents in international joint ventures: an
empirical examination in the Hungarian context,
Journal of International Business Studies 29(2): 154–
174.
Miles, C. C., Snow, R. E. (1995) The new network firm: A
spherical structure built on a human investment
philosophy. Organizational Dynamics 23(4):5–20.
Popper, K. R. (1972) Objective Knowledge, Clarendon
Press, Oxford. 2nd edition.
National Research Council. National Collaboratories:
Applying Information Technology for Scientific
Research. Washington, DC: The National Academies
Press, 1993.
Newell, S., Robertson, M., Scarbrough, H., & Swan, J.
(2009). Managing Knowledge Work. 2nd edition.
Basingstoke: Palgrave.
Nieman, T. A., Skoog, D. A., & Holler, F. J. (1998).
Principles of instrumental analysis. Pacific Grove,
CA: Brooks/Cole.
Nonaka, I., & Takeuchi, H. (1995). The Knowledge-
Creating Company. New York, NY: Oxford
University Press.
Oshri, I., van Fenema P. C., Kotlarsky J. (2008).
Knowledge Transfer in Globally Distributed Teams:
The Role of Transactive Memory. Information Systems
Journal 18(6): 593-616.
Scardamalia, M., Bereiter, C., (2003). Learning to work
creatively with knowledge. In E. De Corte, L.
Verschaffel, N. Entwistle, & J. van Merriënboer
(Eds.), Powerful learning environments: Unraveling
basic components and dimensions (pp. 55-68).
(Advances in Learning and Instruction Series).
Oxford, UK: Elsevier Science.
Snoeck (2010). Guide d'utilisation de la plateforme
eGroupWare. Liège: Centre de Recherche sur
l'Instrumentation, la Formation et l'Apprentissage de
l'Université de Liège.
Shin, S., Kook W. (2014) Can knowledge be more
accessible in a virtual network?: Collective dynamics
of knowledge transfer in a virtual knowledge
organization network Decision Support Systems,
Volume 59, Pages 180-189.
Swan, K., Day, S., Bogle, L., Matthews, D. (2014) A
collaborative, design-based approach to improving an
online program The Internet and Higher Education,
Volume 21, Pages 74-81.
Thomas J. C., K. W. (2001). The knowledge management
puzzle: Human and social factors in knowledge
management. IBM SYSTEMS JOURNAL, VOL 40, NO
4, .
Tseng, F., Kuo F. (2014) A study of social participation
and knowledge sharing in the teachers' online
professional community of practice Computers &
Education, Volume 72, March 2014, Pages 37-47.
Wasko, M., & Faraj, S. (2000). It is what one does": why
people participate and help others in electronic
communities of practice. Journal of Strategic
Information Systems 9 (2-3), 155–173.
Wenger, E. (1998). Communities of Practice. Learning,
Meaning, and Identity. United States of America:
Cambridge University Press.
Wenger E., McDermott R. & Snyder W.M. (2002).
Cultivating Communities of Practice. Harvard
Business School Press, Boston.
Wenger, E. (2010) Communities of practice and social
learning systems: the career of a concept. In
Blackmore, C. (Editor) Social Learning Systems and
communities of practice. Springer Verlag and the
Open University.
Wulf, W. (1989, March). The national collaboratory. In
Towards a national collaboratory. Unpublished report
of a National Science Foundation invitational
workshop, Rockefeller University, New York.
KnowledgeTransferinRegulatoryAnalyticalSciencesthroughtheImplementationofCommunitiesofPractice
23
