academic knowledge externalities: spatial proximity and networks
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Academic knowledge externalities:
spatial proximity and networks
Roderik Ponds, Frank van Oort & Koen Frenken
• University: a regional booster?
Background and motivation
• University: a regional booster?
• Many studies suggest existence of localised knowledge externalities (or spillovers) from academic research
• Importance of scientific research for innovation differs between industries impact academic knowledge externalities as well
Background and motivation
Pieken organiseren zich (in RIS)
Scientific and technological
knowledge
Innovation and
valorisation
Economic growth
Academic institutions
FirmsNon-profit &
Governmental agencies
Regional Innovation Systems
Knowledge externalities are as localized as their mechanism are:
1.Spin-off & start-up dynamics
2.Labour mobility
3.Networks of knowledge exchange
Mechanism of knowledge externalities
• Informal knowledge exchange through social networks, which are mostly localized (Breschi & Lissoni 2003, 2006)
• Besides this, formal knowledge exchange through research collaboration:
• Strong growth of collaboration in processes of knowledge creation (see for example Wagner-Doebler 2001)
• University-industry collaboration key feature of science-based industries (eg. Pavitt 1984, Cockburn & Hendersson 1998)
Networks of knowledge exchange
• University-industry research collaboration not limited to regional scale (see eg. McKelvey et al. 2003)
• Given the importance of this mechanism in science-based technologies: network (of research collaboration) and spatial dimension necessary to analyze relation between academic knowledge externalities and regional innovation
Mechanism of knowledge externalities
Collaboration: a growing phenomenon?-Share of co-publications over time-
0
0,1
0,2
0,3
0,4
0,5
0,6
0,7
0,8
0,9
1988 1989 1990 1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004
Agriculture&Food Chemistry Analysis, measurement and control techno
Biotechnology Information Technology
Optics Organic Fine Chemistry
Semi-conducters Telecommunications
• Knowledge production function approach: regional innovation is a function of regional private and academic R&D expenditures
• Academic R&D can also come from other regions
In two ways:
a. Through localized mechanisms (from nearby regions)
b. Through networks of research collaboration (from 'connected' regions)
• Spatial cross-regressive model:
Research design
, , 2 , 3 , 4 ,ln ln ln (ln ) (ln )i k i k i k space j i k network j i kP RDp RDu W RDu W RDu
Data
• Focus on science-based technologies (7) in the Netherlands: 4 physical science-based and 3 life-sciences-based industries
• Regional innovation measured by patent intensity (EPO, 1999-2001)
• Technology specific private and university R&D (1996-1998)
Biotechnology, 1988-2004
+/- 70% abroad
Semiconductors, 1988-2004
+/- 80% abroad
• Spatial weight matrix: inverse travel time between regions i and j (cut-off point 90 minutes)
• Network weight matrix: intensity of research collaboration between university in region i and firms in region j
Weight matrices
, , 2 , 3 , 4 ,ln ln ln (ln ) (ln )i k i k i k space j i k network j i kP RDp RDu W RDu W RDu
• Research collaboration measured by co-publications between firms and universities in the relevant scientific fields (1993-1995)
• Relevant scientific fields defined by analysis of citations of patents per technology to scientific journals (classified in scientific subfields)
• Assumption: co-publication reflects (formal) research collaboration and knowledge exchange between organisations involved.
Specification of network weight matrix
Specification of network weight matrix
1
Region 1 Region 2
Region 4Region 3
Specification of network weight matrix
Sending/
Receiving
1 2 3 4
1 - 0 5 0
2 10 - 0 0
3 20 0 - 0
4 10 0 10 -
1
Region 1 Region 2
Region 4Region 3
Sending/
Receiving
1 2 3 4
1 - 0 1 0
2 1 - 0 0
3 1 0 - 0
4 1/2 0 1/2 -
Number of patents – lifesciences- Negative Binominal regression (robust standard errors between parentheses)
1 2 3 4
University R&D0.287**(0.046)
0.334**(0.044)
0.313**(0.043)
0.350**(0.039)
Private R&D0.629**(0.103)
0.559**(0.097)
0.380**(0.113)
0.318**(0.110)
W space0.677**(0.157)
0.642**(0.153)
W networks0.163**(0.065)
0.155**(0.056)
Dummy Agriculture & food chemistry
-0.182(0.281)
-0.098(0.268
-0.187(0.240)
-0.143(0.227)
Dummy Biotechnology
0.206(0.297)
0.143(0.265
0.191(0.261)
0.111(0.220)
Constant-0.181(0.292)
-0.806**(0.278
0.082(0.290)
-0.486*(0.269)
Alpha0.867**(0.189)
0.737**(0.161
0.729**(0.151)
0.597**(0.119)
Cragg & Uhler's R2 0.506 0.564 0.548 0.606
• Knowledge production function approach (KPF) with (column standardized) spatial and relational weight matrices for academic R&D to explain regional patent intensity
• Pooled technologies: 3 x 40 observations life-sciences based technologies, 4 x 40 observations physical science-based technologies
• Technology dummies
Empirical model
Number of patents – physical sciences- Negative Binominal regression (robust standard errors between parentheses)
1 2 3 4
University R&D0.234**(0.068)
0.228**(0.073)
0.183**(0.052)
0.158**(0.055)
Private R&D0.989**(0.112)
0.993**(0.115)
0.645**(0.111)
0.497**(0.101)
W space-0.039(0.258)
-0.453(0.374)
W networks0.188**(0.030)
0.200**(0.028)
Dummy Optics
-2.415**(0.383)
-2.416**(0.383)
-1.879**(0.335)
-2.392**(0.371)
DummyInformation technology
-0.830**(0.329)
-0.836**(0.333)
-0.595**(0.284)
-0.797**(0.302)
Dummy semiconductors
-2.106**(0.340)
-2.103**(0.337)
-1.871**(0.295)
-1.895**(0.290)
Constant0.431
(0.230)0.464
(0.338)0.642**(0.226)
0.475(0.325)
Alpha1.189**(0.155)
1.187**(0.156)
0.919**(0.158)
0.843**(0.160)
Cragg & Uhler's R2 0.697 0.697 0.732 0.743
• The results suggest the presence of network knowledge
externalities in both life-sciences and physical sciences
based technologies.
• Localized academic knowledge externalities seem to
occur - in both technologies - within the regions where
the university is located, so at a very local scale.
• Interregional localized externalities seem only to take
place within life-sciences based technologies.
Conclusions
• These outcomes suggest that, within the Netherlands,
academic knowledge externalities within science-based
technologies cannot be easily attached to a specific
spatial scale (global-local paradox).
• It seems that policy measures focussing on an increase
of academic knowledge externalities (if necessary at all)
should not be focussed on specific regions. Given the
wide spatial range of these externalities, the national
scale seems more appropriate.
Conclusions
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