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Editorial	Board	Thoughts:		
Arts	into	Science,	Technology,	
Engineering,	and	Mathematics	–	STEAM,	
Creative	Abrasion,	and	the	Opportunity		
in	Libraries	Today	 Tod	Colegrove	

	

INFORMATION	TECHNOLOGIES	AND	LIBRARIES	|	MARCH	2017	 	 	

	

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Over	the	millennia,	man’s	attempt	to	understand	the	universe	has	been	an	evolution	from	the	
broad	to	the	sharply	focused.	A	wide	range	of	distinctly	separate	disciplines	evolved	from	the	
overarching	natural	philosophy,	the	study	of	nature,	of	Greco-Roman	antiquity:	anatomy	and	
astronomy	through	botany,	mathematics,	and	zoology	among	many	others.	Similarly,	the	Arts,	
Humanities,	and	Engineering	developed	from	broad	over-arching	interest	into	tightly	focused	
disciplines	that	today	are	distinctly	separate.	As	these	legitimate	divisions	formed,	grew,	and	
developed	into	ever-deepening	specialty,	they	enabled	correspondingly	deeper	study	and	
discovery1;	in	response,	the	supporting	collections	of	the	library	divided	and	grew	to	reflect	that	
increasing	complexity.	

Libraries	have	long	been	about	the	organization	of,	and	access	to,	information	resources.	Subject	
classification	systems	in	use	today,	such	as	the	Dewey	Decimal	system,	are	designed	to	group	like	
items	with	like,	albeit	under	broad	overarching	topic.	A	perhaps	inevitable	result	for	print	
collections	housed	under	such	a	classification	system	is	the	physical	isolation	of	items	-	and,	by	
extension,	the	individuals	researching	those	topics	-	from	one	another.	Under	the	Library	of	
Congress	system,	for	example,	items	categorized	as	“geography”	are	physically	removed	from	those	
in	“science;”	further	still	from	“technology.”	End-users	benefit	from	the	possibility	of	serendipitous	
discovery	while	browsing	shelves	nearby,	even	as	they	are	effectively	shielded	from	exposure	to	
distracting	topics	outside	of	their	immediate	focus.		

Recent	years	have	witnessed	a	rediscovery	of,	and	renewed	interest	in,	the	fundamental	role	the	
library	can	have	in	the	creation	of	knowledge,	learning,	and	innovation	among	its	members.	As	
collections	shift	from	print	to	electronic,	libraries	are	increasingly	less	bound	to	the	physical	
constraints	imposed	by	their	print	collections.	Rather	than	a	continued	focus	on	hyper-
specialization	and	separation,	we	have	the	opportunity	to	rethink	the	library:	exploring	novel	
configurations	and	services	that	might	better	support	its	community,	and	embracing	emerging	
roles	of	trans-disciplinary	collaboration	and	innovation.	

The	Library	as	Intersection	

Libraries	reflect	the	institutional	and	organizational	structures	of	their	communities,	even	as	the	
	

Tod	Colegrove	(pcolegrove@unr.edu),	a	member	of	the	ITAL	Editorial	Board,	is	Head	of	
DeLaMare	Science	&	Engineering	Library,	University	of	Nevada,	Reno.	



	
	

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physical	organization	of	the	structures	built	to	house	print	collections	mirror	the	classification	
system	in	use.	Academic	libraries	are	perhaps	most	entrenched	in	the	structural	division:	rather	
than	intrinsically	promoting	collaboration	and	discovery	across	disciplines,	the	organization	of	
print	collections,	and	typically	the	spaces	around	them,	is	designed	to	foster	increased	focus	and	
specialization.	Specialized	almost	to	the	exclusion	of	other	areas	of	study	altogether,	in	branch	
libraries	of	a	college	or	university	this	division	can	reach	a	pinnacle;	libraries	and	collections	
devoted	to	exclusive	topics	of	engineering,	science,	music,	and	others,	exist	on	campuses	across	the	
country.	Amplified	by	separation	and	clustering	of	faculty	and	researchers,	typically	by	department	
and	discipline,	it	becomes	entirely	possible	for	individuals	to	“spend	a	lifetime	working	in	a	
particular	narrow	field	and	never	come	into	contact	with	the	wider	context	of	his	or	her	study.”2	

The	library	is	also	one	of	the	few	places	in	any	community	where	individuals	from	a	variety	of	
backgrounds	and	specialties	can	naturally	cross	paths	with	one	another.		At	a	college	or	university,	
students	and	faculty	from	one	discipline	might	otherwise	rarely	encounter	those	from	other	
disciplines.	Whether	public,	school,	or	academic	library,	outside	of	the	library	individuals	and	
groups	are	typically	isolated	from	one	another	physically,	with	little	opportunity	to	interact	
organically.	Without	active	intervention	and	deliberate	effort	on	the	part	of	the	library,	
opportunities	for	creative	abrasion3	and	trans-disciplinary	collaboration	become	virtually	non-
existent;	its	potential	to	“unleash	the	creative	potential	that	is	latent	in	a	collection	of	unlike-
minded	individuals,”4	untapped.	Leveraged	properly,	however,	the	intersection	of	interests	and	
expertise	that	occurs	naturally	within	the	neutral	spaces	of	the	library	can	become	a	powerful	tool	
that	supports	not	only	research,	but	creativity	and	innovation	-	a	place	where	ideas	and	viewpoints	
can	collide,	building	on	one	another:	

“For	most	of	us,	the	best	chance	to	innovate	lies	at	the	Intersection.	Not	only	do	we	have	a	
greater	chance	of	finding	remarkable	idea	combinations	there,	we	will	also	find	many	more	
of	them....	The	explosion	of	remarkable	ideas	is	what	happened	in	Florence	during	the	
Renaissance,	and	it	suggests	something	very	important.	If	we	can	just	reach	an	intersection	
of	disciplines	or	cultures,	we	will	have	a	greater	chance	of	innovating,	simply	because	there	
are	so	many	unusual	ideas	to	go	around.”5	

Difficult	and	Scary	

The	problem?	“Stimulating	creative	abrasion	is	difficult	and	scary	because	we	are	far	more	
comfortable	being	with	folks	like	us.”6	And	yet	a	quick	review	of	the	literature	reveals	that	
knowledge	creation,	innovation,	and	success	are	inextricably	linked7,	with	the	fundamental	
understanding	of	their	connection	having	undergone	a	dramatic	shift:	“knowledge	is	in	fact	
essential	to	innovate,	and	while	this	might	sound	obvious	today,	putting	knowledge	and	innovation	
and	not	physical	assets	at	the	centre	of	competitive	advantage	was	a	tremendous	change.”8	As	our	
libraries	move	toward	embracing	an	even	more	active	role	within	our	communities,	our	
organizational	priorities	are	undergoing	similarly	dramatic	shifts:	support	for	knowledge	creation	



	

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and	innovation	becomes	more	central,	even	as	physical	assets	shift	toward	a	supporting,	even	
peripheral,	role.	

Libraries,	as	fundamentally	neutral	hubs	of	diverse	communities,	are	uniquely	positioned	to	be	
able	to	cultivate	creative	abrasion	within	and	among	their	communities,	fostering	not	only	
knowledge	creation,	but	innovation	and	success.	Indeed,	the	combination	of	physical,	electronic,	
and	staff	assets	can	be	the	raw	stuff	by	which	trans-disciplinary	engagement	is	encouraged.	The	
active	cultivation	and	support	of	creative	abrasion,	with	direct	linkage	to	desired	outcomes,	
becomes	arguably	one	of	the	most	vital	services	the	library	can	provide	its	community.	Rather	than	
deepening	the	cycle	of	hyper-specialization,	the	emergence	of	makerspace	in	our	libraries	is	one	
example	of	a	trend	toward	enabling	libraries	to	broaden	and	embrace	that	support.	Building	on	the	
intellectual	diversity	within	the	spaces	of	the	library,	staff	members,	volunteers,	and	fellow	
community	members	can	serve	as	catalyst,	triggering	groups	to	“do	something	with	that	variety”9	
by	engaging	across	traditional	boundaries.	Indeed,	“by	deliberately	creating	diverse	organizations	
and	explicitly	helping	team	members	appreciate	thinking-styles	different	than	their	own,	creative	
abrasion	can	result	in	successful	innovation.”10	Strategic	placement	and	staff	support	of	
makerspace	activity	can	dramatically	increase	the	opportunity	for	creative	abrasion	-	and,	by	
extension,	the	resulting	knowledge	creation,	creativity	and	innovation.	

Arts	Bring	a	Fundamental	Literacy	and	Resource	to	STEM	

In	recent	years,	greater	emphasis	on	students	acquiring	STEM	(Science,	Technology,	Engineering,	
and	Math)	skills	has	raised	the	topic	to	be	one	of	the	most	central	issues	in	education.	Considered	a	
key	solution	to	improving	the	competitiveness	of	American	students	on	the	global	stage,	the	
approach	of	STEM	education	shares	the	common	goal	of	breaking	down	the	artificial	barriers	that	
exist	even	within	the	separate	disciplines	of	sciences,	technology,	engineering,	and	math	-	in	short,	
increasing	the	diversity	of	the	learning	environment.		Proponents	of	STEAM	go	further	by	
suggesting	that	adding	Art	into	the	mix	can	bring	new	energy	and	language	to	the	table,	“sparking	
curiosity,	experimentation,	and	the	desire	to	discover	the	unknown	in	students.”	11	Federal	
agencies	such	as	the	U.S.	Department	of	Education	and	the	National	Science	Foundation	have	
funded	and	underwritten	a	number	of	grants,	conferences,	and	workshops	in	the	field,	including	
the	seminal	forum	hosted	by	the	Rhode	Island	School	of	Design	(RISD),	“Bridging	STEM	to	STEAM:	
Developing	New	Frameworks	for	Art-Science-Design	pedagogy.”12	John	Maeda,	the	president	of	the	
RISD,	identifies	a	direct	connection	between	the	approach	and	the	creativity	and	success	of	late	
Apple	co-founder	Steve	Jobs,	with	STEAM	support	“a	pathway	to	enhance	U.S.	Economic	
competitiveness.”13	

Proponents	go	further,	arguing	the	Arts	bring	both	a	fundamental	literacy	and	resource	to	the	
STEM	disciplines,	providing	“innovations	through	analogies,	models,	skills,	structures,	techniques,	
methods,	and	knowledge.”14	Consider	the	findings	of	a	study	of	Nobel	Prize	winners	in	the	
sciences,	members	of	the	Royal	Society,	and	the	U.S.	National	Academy	of	Sciences;	Nobel	laureates	
were:	



	
	

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- twenty-five	times	as	likely	as	an	average	scientist	to	sing,	dance,	or	act;	
- seventeen	times	as	likely	to	be	an	artist;	
- twelve	times	more	likely	to	write	poetry	and	literature;	
- eight	times	more	likely	to	do	woodworking	or	some	other	craft;	
- four	times	as	likely	to	be	a	musician;	and	
- twice	as	likely	to	be	a	photographer.15	

From	the	standpoint	of	creative	abrasion,	welcoming	the	“A”	of	Art	into	the	library	support	of	STEM	
disciplines	increases	the	diversity	of	the	library,	and	by	default	the	opportunity	for	creative	
abrasion.		From	Aristotle	and	Pythagoras	through	Galileo	Galilei	and	Leonardo	da	Vinci	to	
Benjamin	Franklin,	Richard	Feynman,	and	Noam	Chomsky,	a	long	list	of	individuals	of	wide-
ranging	genius	hints	at	a	potential	left	largely	untapped	by	our	traditional	approach.	Connections	
between	STEM	disciplines,	Art,	and	the	innovation	arising	directly	out	of	their	creative	abrasion	
surround	us:	the	electronic	screens	used	on	a	wide	range	of	technology,	including	computers,	
televisions,	and	cell	phones,	are	the	result	of	a	collaboration	between	a	series	of	painter-scientists	
and	post-impressionist	artists	such	as	Seurat	-	a	combination	of	red,	green,	and	blue	dots	generate	
full-spectrum	images	in	a	way	not	unlike	that	of	the	artistic	technique	of	pointillism.	The	electricity	
to	drive	that	technology	is	understood,	in	part,	due	to	early	work	by	Franklin	-	even	as	he	lay	the	
foundations	of	the	free	public	library	with	the	opening	of	America’s	first	lending	library,	and	
pursued	a	broad	range	of	parallel	interests.	The	stitches	used	in	medical	surgery	are	the	result	of	
Nobel	laureate	Alexis	Carrel	taking	his	knowledge	of	lace	making	from	a	traditional	arena	into	the	
operating	room.	Prominent	American	inventors	“Samuel	Morse	(telegraph)	and	Robert	Fulton	
(steam	ship)	were	among	the	most	prominent	American	artists	before	they	turned	to	inventing.”16		

In	short,	“increasing	success	in	science	is	accompanied	by	developed	ability	in	other	fields	such	as	
the	fine	arts.”17	Rather	than	isolated	in	monastic	study,	“almost	all	Nobel	laureates	in	the	sciences	
are	actively	engaged	in	arts	as	adults.”18	Perhaps	surprisingly,	rather	than	being	rewarded	by	an	
ever-increasing	focus	and	hyper-specialization,	genius	in	the	sciences	seems	tied	to	individuals’	
activity	in	the	arts	and	crafts.	The	study’s	authors	cite	three	different	Nobel	prize	winners,	
including	J.	H.	Van’t	Hoff’s	1878	speculation	that	scientific	imagination	is	correlated	with	creative	
activities	outside	of	science19;	going	on	to	detail	similar	findings	from	general	studies	dating	back	
over	a	century.	Of	even	more	seminal	interest,	the	authors	point	to	a	similar	connection	for	
adolescents/young	adults	where	Milgram	and	colleagues20	found	“having	at	least	one	persistent	
and	intellectually	stimulating	hobby	is	a	better	predictor	of	career	success	in	any	discipline	than	
IQ,	standardized	test	scores,	or	grades.”21	

Discussion	

The	connection	between	individuals	holding	a	multiplicity	of	interests,	trans-disciplinary	activity,	
and	success	is	clear;	what	is	less	clear	is	to	what	extent	we	are	fostering	that	connection	in	our	
libraries	today.	The	potential	is	nevertheless	tantalizing:	a	random	group	of	people,	thrown	
together,	is	not	likely	to	be	very	creative.	By	going	beyond	specialization	and	wading	into	the	



	

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deeper	waters	of	supporting	and	cultivating	creative	abrasion	and	avocation	among	the	
membership	of	our	libraries,	we	are	fostering	success	and	innovation	beyond	what	might	
otherwise	occur.	The	decision	to	catalyze	and	foster	the	cross-curricular	collaboration	that	is	
STEAM22	is	squarely	in	the	hands	of	the	library:	in	the	design	of	its	spaces,	and	in	the	interactions	
of	the	staff	of	the	library	with	the	communities	served.	We	can	choose	to	actively	connect	and	
catalyze	across	traditional	boundaries.	

As	the	head	of	a	science	and	engineering	library,	one	of	the	early	adopters	of	makerspace	and	
actively	exploring	the	possibilities	of	STEAM	engagement	for	several	years,	I	have	time	and	again	
witnessed	the	leaps	of	insight	and	creativity	brought	about	by	creative	abrasion.	From	across	
disciplines	members	are	engaging	with	the	resources	of	the	library	-	and,	with	our	encouragement,	
one	another	-	in	an	ever-increasing	cycle	of	knowledge	creation,	innovation,	and	success.	The	
impact	is	particularly	dramatic	among	individuals	from	strongly	differing	backgrounds	and	
disciplines:	for	example,	when	an	engineering	student,	who	considers	themselves	to	be	expert	
with	a	particular	technology,	witnesses	and	interacts	with	an	art	student	using	that	same	
technology	and	accomplishing	something	truly	unexpected,	even	seemingly	magical.	Or	when	a	
science	student	approaching	a	problem	from	one	perspective	realizes	a	practitioner	from	a	
different	discipline	sees	the	problem	from	an	entirely	different,	and	yet	equally	valid,	point	of	view.	
In	each	case,	it’s	as	if	the	worldview	of	each	suddenly	melts:	shifting	and	expanding,	never	to	
return	to	its	original	shape.	Transformative	experiences	become	the	order	of	the	day,	even	as	the	
informal	environment	offers	a	wealth	of	opportunity	to	engage	with	and	connect	end-users	to	the	
more	traditional	resources	of	library.	

By	actively	seeking	out	opportunities	to	bring	art	into	traditionally	STEM-focused	activity,	and	
vice-versa,	we	are	deliberately	increasing	the	diversity	of	the	environment.	Makerspace	services	
and	activities,	to	the	extent	they	are	open	and	visibly	accessible	to	all,	are	a	natural	for	the	
spontaneous	development	of	trans-disciplinary	collaboration.	Within	the	spaces	of	the	library,	
opportunities	to	connect	individuals	around	shared	avocational	interest	might	range	from	music	
and	spontaneous	performance	areas	to	spaces	salted	with	LEGO	bricks	and	jigsaw	puzzles;	the	
potential	connections	between	our	resources	and	the	members	of	our	communities	are	as	diverse	
as	their	interests.	Indeed,	when	a	practitioner	from	one	discipline	can	interact	and	engage	with	
others	from	across	the	STEAM	spectrum,	the	world	becomes	a	richer	place	–	and	maybe,	just	
maybe,	we	can	fan	the	flames	of	curiosity	along	the	way.	

REFERENCES	
	
1.		 Bohm,	D.,	and	F.	D.	Peat.	1987.	Science,	Order,	and	Creativity:	A	Dramatic	New	Look	at	the	

Creative	Roots	of	Science	and	Life.	London:	Bantam.	

2.		 Ibid.,	18-19.	

3.		 Hirshberg,	Jerry.	1998.	The	Creative	Priority:	Driving	Innovative	Business	in	the	Real	World.	
London:	Penguin.	



	
	

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4.		 Leonard-Barton,	Dorothy,	and	Walter	C.	Swap.	1999.	When	Sparks	Fly:	Harnessing	the	Power	of	

Group	Creativity.	Boston,	Massachusetts:	Harvard	Business	School	Press	Books.		

5.		 Johansson,	Frans.	2004.	The	Medici	Effect:	Breakthrough	Insights	at	the	Intersection	of	Ideas,	
Concepts,	and	Cultures.	Boston,	Massachusetts:	Harvard	Business	School	Press,	20.	

6.	 Leonard-Barton,	Dorothy,	and	Walter	C.	Swap.	1999.	When	Sparks	Fly:	Harnessing	the	Power	of	
Group	Creativity.	Boston,	Massachusetts:	Harvard	Business	School	Press	Books,	25.	

7.		 Nonaka,	Ikujiro.	1994.	“A	Dynamic	Theory	of	Organizational	Knowledge	Creation.”	
Organization	Science	5	(1):	14–37.	

8.		 Correia	de	Sousa,	Milton.	2006.	“The	Sustainable	Innovation	Engine.”	Vine	36	(4):	398–405,	
accessed	February	14,	2017.	https://doi.org/10.1108/03055720610716656.	

9.		 Leonard-Barton,	Dorothy,	and	Walter	C.	Swap.	1999.	When	Sparks	Fly:	Harnessing	the	Power	of	
Group	Creativity.	Boston,	Massachusetts:	Harvard	Business	School	Press	Books,	20.	

10.		Adams,	Karlyn.	2005.	The	Sources	of	Innovation	and	Creativity.	Education,	September,	2005,	
33.	https://doi.org/10.1007/978-3-8349-9320-5.	

11.		Jolly,	Anne.	2014.	“Stem	vs.	STEAM:	Do	the	Arts	Belong?”	Education	Week	Teacher.	
http://www.edweek.org/tm/articles/2014/11/18/ctq-jolly-stem-vs-
steam.html?qs=stem+vs.+steam.	

12.		Rose,	Christopher,	and	Brian	K.	Smith.	2011.	“Bridging	STEM	to	STEAM:	Developing	New	
Frameworks	for	Art-Science-Design	Pedagogy.”	Rhode	Island	School	District	Press	Release.	

13.		Robelen,	Erik	W.	2011.	“STEAM:	Experts	Make	Case	for	Adding	Arts	to	STEM.”	Education	Week.	
http://www.bmfenterprises.com/aep-arts/wp-content/uploads/2012/02/Ed-Week-STEM-
to-STEAM.pdf.	

14.		Root-Bernstein,	Robert.	2011.	“The	Art	of	Scientific	and	Technological	Innovations	–	Art	of	
Science	Learning.”	http://scienceblogs.com/art_of_science_learning/2011/04/11/the-art-of-
scientific-and-tech-1/.	

15.		Ibid.	

16.		Ibid.	

17.		Root-Bernstein,	Robert,	Lindsay	Allen,	Leighanna	Beach,	Ragini	Bhadula,	Justin	Fast,	Chelsea	
Hosey,	Benjamin	Kremkow,	et	al.	2008.	“Arts	Foster	Scientific	Success:	Avocations	of	Nobel,	
National	Academy,	Royal	Society,	and	Sigma	Xi	Members.”	Journal	of	Psychology	of	Science	and	
Technology.	https://doi.org/10.1891/1939-7054.1.2.51.	



	

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18.		Ibid.	

19.		Van’t	Hoff,	Jacobus	Henricus.	1967.	“Imagination	in	Science,”	Molecular	Biology,	Biochemistry	
and	Biophysics,	translated	by	G.	F.	Springer,	1,	Springer-Verlag,	pp.	1-18	

20.		Milgram,	Roberta	M.,	and	Eunsook	Hong.	1997.	"Out-of-school	activities	in	gifted	adolescents	
as	a	predictor	of	vocational	choice	and	work."	Journal	Of	Secondary	Gifted	Education	8,	no.	3:	
111.	Education	Research	Complete,	EBSCOhost	(accessed	February	26,	2017).	

21.		Root-Bernstein,	Robert,	Lindsay	Allen,	Leighanna	Beach,	Ragini	Bhadula,	Justin	Fast,	Chelsea	
Hosey,	Benjamin	Kremkow,	et	al.	2008.	“Arts	Foster	Scientific	Success:	Avocations	of	Nobel,	
National	Academy,	Royal	Society,	and	Sigma	Xi	Members.”	Journal	of	Psychology	of	Science	and	
Technology.	https://doi.org/10.1891/1939-7054.1.2.51.	

22.		Land,	Michelle	H.	2013.	“Full	STEAM	Ahead:	The	Benefits	of	Integrating	the	Arts	into	STEM.”	
Procedia	Computer	Science	20.	Elsevier	Masson	SAS:	547–52.	
https://doi.org/10.1016/j.procs.2013.09.317.