some stuff[ed] by Victoria Bolton

2010 woodhead scholar-trip:

some stuff [ed] victoria bolton

contents 01_ the trip + planning 02_ university campus plannng

4-9 18-41

03_ pedagogy 45-53 04_ scientific lab design

56-83

05_ other stuff mixed 06_ what is the future?

86-89

WARNING: This report was written for fun - itâ&#x20AC;&#x2122;s intention is not to be a serious academic paper - but rather a catalyst for conversation about pedagogy, sustainability and airstreams. Enjoy!

victoria bolton - some stuff [ed]

the plan victoria bolton - some stuff [ed]

introduction: the timetable

2010

SA) fornia, U li a C , s Angele xico) rive (Los r il A – New Me r , e e b u q g Counc m r e in e t d u p il q e u u S b lb 4 2 Green tober (A y the US of Labs r – 2 Oc b e n b u r m e t p esign orksho 27 Sep nergy D ll day w E fu w a o – L r , e emb rmance 27 Sept igh Perfo H n o ) rence (USGBC 1 Confe 2 s b a L er – eptemb 28-30 S Fiesta Balloon r e b o t c 1O a) dale e, Arizon p m e t, Scotts (T s r e e W b o n t e c 4O Talies y Wright’s Universit d e t y a lo t L S k a n t Arizon Visit Fra stitute a In n ig s Biode Visit the izona) scon, Ar u (T r e b o fornia) 5-6 Oct go, Cali ie D n a tober (S rnia) 8-10 Oc s, Califo nce 3 le e g n A os , BioScie ll (L a r e H b s o s t c ue Gro 11-14 O – Bill & S e in v Ir rnia) ber UC s) co, Califo 11 Octo is c n a h facilitie r c F r a n e a s e (S r (great ctober lanning 14-15 O p r e t s a –M ture” Berkeley r the Fu fo ) g io h in 15th UC n O n n: Pla cinnati, ber (Cin 020:Visio o 2 t “ c e O c n 9 24-2 onfere SCUP C – r e b o t c 25 -27 O PA Labs 28-29 E York York) er, New er (New in b m o a t x c E O 1-2 edical Chief M e h t f o e c tralia) Visit Offi ney, Aus d y (S e iv er - Arr 3 Octob 6

victoria bolton - some stuff [ed]

introduction: the submission May 10, 2010: this is an extract from my scholarship application:

Over the p have be ast two decade come ou s Austra li r countr portfolio y’s third a’s education in has bec stitution la rgest ex o to grow me the la s, in port (1). particula rg e s t W in rly in the ithin Wo particular our u the com niversitie od p A a sian ma As a com s, rket and ny, and the exp head our Educa pany we ectation tion in the fie educatio “need to is ld t n debat hat it wil of labor demons e atory de l continu t class th sign(2). inking re through a carefu rate to the mark e garding et that w lly cons idered a ‘learning e c To lead a n lead the nd space’ d the deb hig esign” (2 articulated des ates on they are ign proc her ). a n interna being ad ess and tion dressed world and who al level we nee This yea d to kno is leadin r there a w what g the dis re universit the issu cussion y campu two key interna es are, h s . tional co ses and Woodhe ow nference the tren ad. In be ds in lab s lookin tween th to visit k ga de e ey new laborato se conferences sign that I would t the issues of t and cha he ry I would like to a llenges like to u ttend on future of echo tha projects and vis s e t it behalf o t o h p f e My goal ost Wor Australia contacts f ld War II is to cre n t In h a s t t it I u have ma ate a rep campus tions. Woodhe es whos de or ad can u e condit se for re t + presentation io n fe o s rence as ft On a pe rso it pitche he conference and cas s for mo registere nal note 2010 is e re Educ d a ational p studies that doing so architect. I have significant yea r o jects. r for me sp h – it’s the – what s ave been interro ent the past fe y w e ort of ar g a a m r in whic ting m onths chitect d h I will o I want y own work to d preparing for t Answer he exam become a to be an ate and – I want in question d what s to opportu ort of w ing my fu ation and in nity for m specialise in Ed o r t k ure direc do I wan ucation. e to foc tion t to crea us in an I te? area of a see this travel s rchitectu c re that I holarship as a h find inte uge care resting. er References: 1. Professor Denise Bradley, ‘Review of Australian Higher Education: Final Report’, (Commonwealth of Australia: December 2008), xii 2. Mark Clements, ‘Woodhead Education Portfolio’ - Business Plan 2009 victoria bolton - some stuff [ed]

8 victoria bolton - some stuff [ed]

on the road from new mexico to a truck stop near arizona

travelling by airstream living the american dream Source: http://www.pre.wur.nl/UK/Safety/Fume+cupboard/default.htm victoria bolton - some stuff [ed]

â&#x20AC;&#x153;this was the first picture taken of the earth from the moon... it is the image that sparked the environmental movement as people began to realise there is only one planet with finite resourcesâ&#x20AC;? - Dr Trent, Labs21

victoria bolton - some stuff [ed]

sustainability victoria bolton - some stuff [ed]

The image on the previous page is “known as Earth Rise… this one picture exploded the consciousness of humankind… within 18 months of this picture the modern environmental movement had begun” - Al Gore , An Inconvenient Truth

population increase and corresponding C02 emissions Source: Dr Trent’s Plenary speech, Labs21 Conference 2010

victoria bolton - some stuff [ed]

The human population has increased exponentially over the past 100 years. Since the industrial revolution the amount of carbon dioxide we release into the atmosphere has increased equally as rapidly. The carbon has built up and created a layer that traps the heat from the sun within the Earth’s atmosphere causing a ‘warming’ of the Earth’s temperature.

The question we are all asking ourselves is what can we do about it?

University Campuses have the unique opportunity to research and test theories on how we can achieve carbon neutrality within a defined community. This is recognised through the signing of the American College and University Presidents’ Climate Commitment and evident in the case study of Cornell University, Ithaca Campus, New York. 1. Population Increase In 1927 the population was 2 billion, by 1999 that had tripled to 6 billion and by the end of this year 2011 we will have passed the 7 billion mark. Whilst the population has increased dramatically, the size of the Earth has remained the same and the human population is now occupying significantly more of it. Prior to the Industrial Revolution the carbon monoxide levels were fairly constant ranging from 260-280 parts per million (ppm). In the last century the carbon monoxide levels have significantly increased to their current level of over 390 ppm . This increase is due to human activity particularly the burning of fossil fuel (coal, gas and oil) coupled with deforestation.

the greenhouse effect

Source: http://www.independentaustralia.net/2011/environment/galileo-movement-fabricates-science-to-fuel-climate-divide/

Source: http://www.world-nuclear.org/John_Ritch/The_Necessity_of_Nuclear_Power.html

a mapping study of the growth of the human popoulation 1 A.D - 300 million 1927 - 2 billion

1000 - 310 million 1960 - 3 billion

1800 - 1 billion 1974 - 4 billion

1987 - 5 billion

1999 - 6 billion

2050 - 9 billion victoria bolton - some stuff [ed]

Latest data published by the US Energy Information Administration provides a unique picture of economic growth – and decline. China has sped ahead of the US, as shown by this map, which resizes each country according to CO2 emissions. And, for the first time, world emissions have gone down

Key

1 China 7,711 %

Emissions ranking and country

Change in emissions, 2008 to 2009

28 Kazakhstan 185

Regional emissions in 2009

Europe 4,310m Down 6.9%

9.8%

tonnes of CO2 in 2009

7 Canada 541 9.6%

68 Norway 39.6

10 UK 520

52 Belarus 60.6

7.0%

101

8.4%

17 Italy 408

55 Portugal 56.5

28.2%

9.3%

73 Slovakia 35.8

61 44 Romania Hungary 80.5 50.0 58 Serbia 52.3

109 154

179

139

124

66 Bulgaria 44.5

24 Turkey 253 7.3%

39 Greece 100 5.3%

174 102

33 Pakistan 140

122

76 213 Cuba 30.4 150 83 95

13 Mexico 444 1.9%

tonnes of CO2 in 2009

74 Puerto Rico 33.3

on 2008

169

113

Central & South America 1,273m Up 3.6%

88 149

tonnes of CO2 in 2009 on 2008

30 Venezuela 162 1.4%

37 Algeria 114

71 Morocco 36.5

210 146

188 201 195

105 129

211

171

208

194 181

187

119

192

160 190

64 Trinidad & Tobago 47.8

Africa 1,122m Down 3.1%

117

177

163 115

158

151 168

162

104 141 134 206

on 2008

125 126

107 196 116

78 Angola 24.0

on 2008

3.5%

199

46 Nigeria 77.7

tonnes of CO2 in 2009

27 Egypt 192

57 Libya 55.0

143

186 185 164 180

Middle East 1,714m Up 3.3%

80 Tunisia 22.9

6.2%

tonnes of CO2 in 2009

157

49 Colombia 70.1

176 112

216

148

12 South Africa 450

0.3%

6.7%

3.7%

138

127

75 Bahrain 31.1

137

11 Saudi Arabia 470

142

200

110

29 Argentina 167

World 30,452m Down 0.1%

193

Million Percent tonnes change 2009 08—09

7,711 5,425 1,602 1,572 1,098 766 541 528 527 520 470 450 444 420 418 413 408 397 330 291 286 255

13.3 -7.0 8.7 -7.4 -9.7 -7.0 -9.6 1.2 3.2 -7.8 3.2 -6.7 -1.9 -0.3 -1.8 2.4 -9.3 -7.4 -8.4 -3.7 -3.0 -28.2

Rank/ Country change on 2008

23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44

Thailand Turkey Netherlands United Arab Emirates Egypt Kazakhstan Argentina Venezuela Singapore Malaysia Pakistan Belgium Chile Uzbekistan Algeria Iraq Greece Vietnam Czech Republic Hong Kong Kuwait Romania

26 United Arab Emirates 193 1.2%

tonnes of CO2 in 2009

Detailed data Full list of each country’s CO2 emissions and movement in the world emissions league table

China US India Russia Japan Germany Canada South Korea Iran UK Saudi Arabia South Africa Mexico Brazil Australia Indonesia Italy France Spain Taiwan Poland Ukraine

79 Yemen 22.9 63 Oman 49.0

214

3.2%

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22

172

51 Qatar 66.5

3.2%

132

74.1% Biggest % increase

India overt

43 Kuwait 84.9

48 Israel 70.5

35 Chile 119

38 Iraq 104

53 Syria 56.9

161 159

14 Brazil 420

9 Iran 527 3.2%

152 189 178 114 165 145 144 100

131 128

0.4%

155 173

205

77 Ecuador 28.7 70 Peru 38.2

Rank/ Country change on 2008

72 Azerbaijan 36.2

111

50 Austria 69.2

130

North America 6,411m Down 6.9%

9.4%

Biggest % drop in emissions

7.0%

65 Switz. 45.8

7.4%

19 Spain 330

22 Ukraine 255

3.7%

41 Czech Rep 95.3

18 France 397

121

21 Poland 286

6 Germany 766

11.2%

36 Uzbekistan 115

7.4%

0.2%

34 Belgium 137

120 118

62 Denmark 49.6

25 Netherlands 249

UK had been ranked 8th for emissions in 2008

US emissions are down for the second year in succession – after almost uninterrupted year on year increases since these records began in 1980. The decline has matched the country’s economic woes which have seen it only just emerge from recession. Since 2000 the country’s CO2 emissions have fallen by 7.5%

103

59 Finland 52.2

7.8%

67 Ireland 40.3

212

60 Sweden 50.6

54 Turkmenistan 56.8

4 Russia 1,572

136 175

5,425 million tonnes

on 2008

184

2 US

E 2 D

Million tonnes of CO2 emitted in 2009

Million Percent tonnes change 2009 08—09

253 253 249 193 192 185 167 162 161 148 140 137 119 115 114 104 100 98.8 95.3 86.0 84.9 80.5

-0.1 -7.3 -0.2 -1.2 3.5 9.8 -3.2 -1.4 -0.1 -0.2 0.4 -11.2 74.1 -9.4 6.2 3.7 -5.3 -4.9 -3.8 10.3 6.3 -16.6

Rank/ Country change on 2008

45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66

North Korea Nigeria Philippines Israel Colombia Austria Qatar Belarus Syria Turkmenistan Portugal Bangladesh Libya Serbia Finland Sweden Hungary Denmark Oman Trinidad and Tobago Switzerland Bulgaria

Million Percent tonnes change 2009 08—09

79.5 77.7 72.4 70.5 70.1 69.2 66.5 60.6 56.9 56.8 56.5 55.1 55.0 52.3 52.2 50.6 50.0 49.6 49.0 47.8 45.8 44.5

14.3 -22.4 -2.9 4.8 7.9 -2.5 4.8 -9.5 6.1 -1.2 1.5 9.4 -3.9 -3.2 -4.9 -7.7 -10.7 -8.6 9.9 -4.1 1.0 -11.9

Rank/ Country change on 2008

67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88

Ireland Norway New Zealand Peru Morocco Azerbaijan Slovakia Puerto Rico Bahrain Cuba Ecuador Angola Yemen Tunisia Croatia Jordan Dominican Republic Bosnia and Herzegovina Estonia Slovenia Lithuania Panama

on 2008

Million Percent tonnes change 2009 08—09

40.3 39.6 39.1 38.2 36.5 36.2 35.8 33.3 31.1 30.4 28.7 24.0 22.9 22.9 21.5 20.0 19.9 18.3 17.5 17.4 15.8 15.5

-11.2 -0.3 -1.1 4.0 -2.2 -8.9 -4.5 -3.2 1.6 4.7 1.7 1.8 13.5 5.7 -4.7 2.4 2.1 -15.9 -11.8 0.5 -12.8 1.7

Rank/ Country change on 2008

89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110

Lebanon Bolivia Sudan Sri Lanka Burma US Virgin Islands Jamaica Netherlands Antilles Kenya Guatemala Armenia Zimbabwe Luxembourg Cyprus Latvia Ghana Honduras Brunei Cameroon Mongolia Macedonia Uruguay

Million Percent tonnes change 2009 08—09

14.8 13.9 13.0 12.8 12.5 12.5 12.1 11.6 11.5 11.3 11.2 10.6 10.6 9.4 8.5 8.1 7.9 7.6 7.5 7.4 7.3 7.2

3.6 -2.7 7.0 1.7 -9.5 -3.5 -4.6 -4.1 2.4 -1.4 1.5 18.6 -11.2 -3.5 8.1 9.6 -2.4 -27.1 -1.9 -3.8 -20.1 -10.2

Rank/ Country change on 2008

111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132

Moldova Ethiopia Costa Rica Tanzania IvoryCoast Congo Senegal Tajikistan El Salvador Kyrgyzstan Georgia Bahamas Papua New Guinea Albania Equatorial Guinea Gabon Mauritius Botswana Nicaragua Gibraltar Namibia Paraguay

Million Percent tonnes change 2009 08—09

7.1 6.9 6.8 6.7 6.6 6.3 6.2 6.1 5.9 5.7 5.3 5.2 4.8 4.6 4.6 4.6 4.6 4.5 4.5 4.4 4.1 4.0

-4.1 7.1 -4.4 7.1 2.2 3.8 1.8 -10.4 0.0 -0.4 -4.9 3.1 6.7 3.8 -2.1 -3.2 -1.0 7.7 -2.9 -3.8 3.7 3.7

Rank/ Country change on 2008

133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154

Cambodia Benin Nepal Iceland Palestine Madagascar Malta New Caledonia Togo Reunion Mauritania Zambia Congo, Dem Rep Martinique Macau Mozambique Guadeloupe Haiti Suriname Uganda Fiji Montenegro

Million Percent tonnes change 2009 08—09

3.9 3.5 3.4 3.4 3.2 3.1 3.1 3.0 2.8 2.8 2.7 2.7 2.7 2.6 2.4 2.3 2.2 2.1 2.0 1.9 1.9 1.9

-6.1 4.3 3.8 -7.4 4.3 13.4 -2.5 0.0 5.6 0.0 5.3 18.8 -2.6 6.3 1.3 4.6 -5.1 2.9 4.0 -3.0 -6.2 4.3

tan

enn

Eurasia 2,358m Down 9.2%

tonnes of CO2 in 2009

120 118

8 South Korea 528

on 2008

45 North Korea 79.5

36 Uzbekistan 115 9.4%

2. Global Warming

1.2%

108

5 Japan 1,098

The more insidious issue of population increase is the corresponding rise of Green House Gas (GHG) emissions and pollution which cause ‘Global Warming’. GHGs ‘thicken’ the Earth’s atmosphere (making it like the glass of a Greenhouse) trapping the heat of the sun and preventing it from radiating back out into space. According to the UNFCC the average temperature of the Earth during 1906 – 2005 increased by 0.74°C, it is projected that the temperature will continue to increase by 0.2°C per decade. In addition the increased Carbon Dioxide levels will result in acidification of the oceans .

9.7%

1 China

7,711

million tonnes

13.3% Only three years earlier, in 2006, China was in second place, and until recently had been very close to US emissions. But from 2008 to 2009, rapid growth has matched the country’s 9-10% growth in GDP. Since 2000 the country’s CO2 emissions have risen by 170.6% 174

20 Taiwan 291 3.7%

33 Pakistan 140 0.4%

147

135 191

40 Vietnam 98.8

166

56 Bangladesh 55.1

47 Philippines 72.4

4.9%

23 Thailand 253

3 India 1,602

42 Hong Kong 86.0

106

0.1%

156

32 Malaysia 148

8.7%

215

0.2%

202

India overtook Russia in 2009

123

31 Singapore 161

16 Indonesia 413

0.1%

197

204

209 207

153

182 203

140

2.4% 183

172

198

167

133

170

217

Asia & Oceania

13,264m Up 7.5%

tonnes of CO2 in 2009

15 Australia 418

on 2008

1.8% 69 New Zealand 39.1

Million Percent tonnes change 2009 08—09

3.9 3.5 3.4 3.4 3.2 3.1 3.1 3.0 2.8 2.8 2.7 2.7 2.7 2.6 2.4 2.3 2.2 2.1 2.0 1.9 1.9 1.9

-6.1 4.3 3.8 -7.4 4.3 13.4 -2.5 0.0 5.6 0.0 5.3 18.8 -2.6 6.3 1.3 4.6 -5.1 2.9 4.0 -3.0 -6.2 4.3

Rank/ Country change on 2008

155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176

Djibouti Guam Guyana Burkina Faso Seychelles Barbados Swaziland Niger Guinea Sierra Leone Malawi Laos Wake Island French Guiana Aruba French Polynesia Belize Maldives Somalia Afghanistan Faroe Islands Eritrea

Million Percent tonnes change 2009 08—09

1.8 1.7 1.5 1.4 1.4 1.4 1.4 1.3 1.3 1.3 1.3 1.2 1.2 1.1 1.1 1.1 0.94 0.92 0.90 0.83 0.80 0.77

3.4 -3.5 0.0 2.1 6.1 -4.0 17.0 3.5 -1.2 5.9 4.6 1.1 -4.3 6.1 4.2 7.7 -5.4 3.4 3.4 -2.9 6.4 6.4

Rank/ Country change on 2008

177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198

Mali Rwanda Bermuda Liberia Antigua and Barbuda American Samoa East Timor Greenland Guinea-Bissau Gambia Cayman Islands Saint Lucia Burundi Cape Verde Bhutan Western Sahara Antarctica Saint Kitts and Nevis Grenada Central African Republic Solomon Islands US Pacific Islands

Million Percent tonnes change 2009 08—09

0.74 0.74 0.71 0.69 0.69 0.67 0.63 0.61 0.46 0.44 0.43 0.41 0.37 0.34 0.33 0.32 0.31 0.30 0.30 0.29 0.29 0.29

6.4 0.0 4.2 2.2 4.4 2.2 8.7 -4.8 0.0 15.4 -11.8 0.0 4.0 4.5 -11.1 0.0 17.6 11.1 4.8 -13.0 25.0 0.0

Rank/ Country change on 2008

199 200 201 202 203 204 205 206 207 208 209 210 211 212 213 214 215 216 217

Chad Lesotho Saint Vincent/Grenadines Nauru Tonga Cook Islands Comoros Sao Tome and Principe Vanuatu British Virgin Islands Samoa Montserrat Dominica Saint Pierre and Miquelon Turks and Caicos Islands Falkland Islands Kiribati Saint Helena Niue

Million Percent tonnes change 2009 08—09

0.29 0.27 0.27 0.20 0.15 0.15 0.15 0.15 0.15 0.15 0.15 0.15 0.14 0.11 0.08 0.05 0.04 0.01 0.01

11.1 5.9 17.6 9.1 -23.1 66.7 25.0 11.1 25.0 25.0 -16.7 58.7 11.1 16.7 0.0 0.0 0.0 11.2 2.9

Table shows total carbon dioxide emissions from the consumption of energy GRAPHIC: MARK McCORMICK, PAUL SCRUTON.

SOURCE: EIA

In 1997 the Kyoto Protocol was established by the United Nations Framework Convention on Climate Change (UNFCCC) to commit industrialised countries to reduce their carbon emissions. Currently 37 countries and the EU have committed themselves to the reduced carbon and GHG targets. The goal is the “stabilization of greenhouse gas concentrations in the atmosphere at a level that would prevent dangerous anthropogenic interference with the climate system. Such a level should be achieved within a time-frame sufficient to allow ecosystems to adapt naturally to climate change, to ensure that food production is not threatened and to enable economic development to proceed in a sustainable manner.” But simply committing to targets from a governmental level is not enough. It is up to us the citizens to make the change. Universities are in the unique position of having a defined educated community with a significant population, money to invest in research and a built environment that they can control.

Text of the American College & University Presidents’ Climate Commitment

While we understand that there might be short-term challenges associated with this effort, we believe that there will be great short-, medium-, and long-term economic, health, social and environmental benefits, including achieving energy independence for the U.S. as quickly as possible. We believe colleges and universities must exercise leadership in their communities and throughout society by modeling ways to minimize global warming emissions, and by providing the knowledge and the educated graduates to achieve climate neutrality. Campuses that address the climate challenge by reducing global warming emissions and by integrating sustainability into their curriculum will better serve their students and meet their social mandate to help create a thriving, ethical and civil society. These colleges and universities will be providing students with the knowledge and skills needed to address the critical, systemic challenges faced by the world in this new century and enable them to benefit from the economic opportunities that will arise as a result of solutions they develop. We further believe that colleges and universities that exert leadership in addressing climate change will stabilize and reduce their long-term energy costs, attract excellent students and faculty, attract new sources of funding, and increase the support of alumni and local communities. Accordingly, we commit our institutions to taking the following steps in pursuit of climate neutrality. 1. Initiate the development of a comprehensive plan to achieve climate neutrality as soon as possible. a. Within two months of signing this document, create institutional structures to guide the development and implementation of the plan. b. Within one year of signing this document, complete a comprehensive inventory of all greenhouse gas emissions (including emissions from electricity, heating, commuting, and air travel) and update the inventory every other year thereafter.

victoria bolton - some stuff [ed]

c. Within two years of signing this document, develop an institutional action plan for becoming climate neutral, which will include: i. A target date for achieving climate neutrality as soon as possible. ii. Interim targets for goals and actions that will lead to climate neutrality. iii. Actions to make climate neutrality and sustainability a part of the curriculum and other educational experience for all students. iv. Actions to expand research or other efforts necessary to achieve climate neutrality. v. Mechanisms for tracking progress on goals and actions. 2. Initiate two or more of the following tangible actions to reduce greenhouse gases while the more comprehensive plan is being developed. a. Establish a policy that all new campus construction will be built to at least the U.S. Green Building Council’s LEED Silver standard or equivalent. b. Adopt an energy-efficient appliance purchasing policy requiring purchase of ENERGY STAR certified products in all areas for which such ratings exist. c. Establish a policy of offsetting all greenhouse gas emissions generated by air travel paid for by our institution. d. Encourage use of and provide access to public transportation for all faculty, staff, students and visitors at our institution. e. Within one year of signing this document, begin purchasing or producing at least 15% of our institution’s electricity consumption from renewable sources. f. Establish a policy or a committee that supports climate and sustainability shareholder proposals at companies where our institution’s endowment is invested. g. Participate in the Waste Minimization component of the national RecycleMania competition, and adopt 3 or more associated measures to reduce waste. 3. Make the action plan, inventory, and periodic progress reports publicly available by submitting them to the ACUPCC Reporting System for posting and dissemination.

In recognition of the need to build support for this effort among college and university administrations across America, we will encourage other presidents to join this effort and become signatories to this commitment. Signed, The Signatories of the American College & University Presidents Climate Commitment

Source: http://www.presidentsclimatecommitment.org/about/commitment

We, the undersigned presidents and chancellors of colleges and universities, are deeply concerned about the unprecedented scale and speed of global warming and its potential for largescale, adverse health, social, economic and ecological effects. We recognize the scientific consensus that global warming is real and is largely being caused by humans. We further recognize the need to reduce the global emission of greenhouse gases by 80% by mid-century at the latest, in order to avert the worst impacts of global warming and to reestablish the more stable climatic conditions that have made human progress over the last 10,000 years possible.

“Never doubt that a small group of thoughtful committed people can change the world. Indeed, it is the only thing that ever has” - Margaret Mead

3. American College and University President’s Climate Commitment The American College and University Presidents’ Climate Commitment (ACUPCC) was established in 2006 after the Association for the Advancement of Sustainability in Higher Education (AASHE) annual conference. The ACUPCC signatories have pledged to eliminate their campus’ net green house gases (that is to be carbon neutral) by 2025, 2040, or 2050. There are 685 universities who have agrees to the ACUPCC and over 200 have submitted their plans. Refer to

In Australia, we have the Australiasian Campuses Towards Sustainability (ACTS), refer to http://www.acts.asn.au/. Established in 2006, this group promotes and provides resources for sustainable campus design, but unlike the ACUPCC it does not yet set targets. This is in part because it does not have the support of the government; whereas in the USA APUPCC has been endorsed by the president, and it has the potential to tie funding to targets.

http://acupcc.aashe.org/

Regardless, ACTS has significant following in Australia. Its members include: - James Cook University, - Australian National University - Griffith University - the University of Technology Sydney - the University of Melbourne, and - the University of New South Wales.

victoria bolton - some stuff [ed]

Example Carbon Emissions Inventory This shows how each campus is unique and has different areas it needs to focus on to achieve carbon neutrality. For example Cal Poly’s Transport carbon emissions are it’s biggest concern, whereas Cornell’s issue it’s its electricity consumption.neutral/

4. Carbon Neutral Research Campuses Particular emphasis needs to be placed on Campuses with laboratories, as these are the most energy heavy. Laboratories can use 3-8 times the amount of energy of a typical office building, multiply that operational expenditure across several research buildings on a campus, then multiply that by several campuses and you can understand why the US Government set up the National Renewable Energy Laboratory (NREL).

The NREL Climate Neutral Research Campuses outlines a 5 step process for setting up a Climate Action Plan (CAP).

1. Determine Baseline Energy Consumption 2. Analyse Technology Options 3. Prepare a plan and set priorities 4. Implement the Climate Action Plan 5. Measure and Evaluate the Process

For more information on the process refer to http://www.nrel.gov/tech_deployment/climate_neutral/

cornell university sustainable campus design 5. Case Study: Cornell University Cornell Universityâ&#x20AC;&#x2122;s Ithaca Campus has set their sustainability target to be Carbon Neutral by 2050. That is CAP is to reduce their carbon based emissions to zero by 2050. Their CAP can be divided into 5 broad streams: - Green Development: Building Energy Standards, Space Planning and Management; Improved Land Use - Energy Conservation: Building energy conservation, conservation outreach, steam line upgrade, smart grid - Alternative Transportation: Commuter Travel, Business Travel, Campus Fleet - Fuel Mix and Renewables: Hybrid; Wind Power, CURBI, Upgraded Hydro Capacity; Wood Co-firing, Turbine Generator Replacement - Offsetting Actions: Defined Offsets, Undefined Offsets, Community Offsets.

Extract from Cornellâ&#x20AC;&#x2122;s Carbon Action Plan victoria bolton - some stuff [ed]

Whilst these initiatives are environmental, at the core of the decision making is money, the campus was spending almost US$60 million per year on utilities on a building area of approximately 125.4 ha (13.5m sqf). Therefore, their focus has been on renewable energy including: - Hydroelectric plant (produces 4GW/ht or 2% of the campus consumption) - Co-generation plant, built 1986, (produces 30GW/hr or 12%) - Lake Source Cooling, saves over 25 GW/yr - Combustion Turbine with Heat Recovery Steam Generator For more information refer to www. sustainablecampus.cornell.edu/climate

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Above: Analysis of carbon emissions for the Ithaca Campus Below: Schmatic of Heating and Cooling System for the Campus.

NREL Carbon Neutral Campus Guides - http://www.nrel.gov/tech_ deployment/climate_neutral/ ACUPPC - http://acupcc.aashe.org/ UNFCC - http://unfccc.int/press/fact_sheets/items/4978.php Labs 21 - www.labs21century.gov Database of State Incentives for Renewable Energy - www.dsireusa.org American Institute of Physics - http://www.aip.org/history/climate/co2.htm Whole Building Design Guide - www.wbdg.org Australiasian Campuses Towards Sustainability - http://www.acts.asn.au/ EAUC - http://www.eauc.org.uk/ Sustainable University Guides: Cornell - www.sustainablecampus.cornell.edu/climate Arizona State University Campus Metabolism: http://cm.asu.edu/ Harvard - http://green.harvard.edu/ Rensselear + SOM CASE - www.case.rpi.edu Melbourne Uni - http://sustainablecampus.unimelb.edu.au/ UTS - http://www.green.uts.edu.au/index.html

- David W. Orr, professor and author, Oberlin Collge, from The Last Refuge

Government / Corporate:

â&#x20AC;&#x153;No institutions in modern society are better equipped to catalyse the necessary transition to a sustainable world than colleges and universities. They have access to the leaders of tomorrow and the leaders of today. What they do matters to the wider publicâ&#x20AC;?

Resources for Further Reading:

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facilities management: top 10 issues According to the APPA Thought Leaders Series 2009

1. Adjusting to the new sustainability reality. 2. Developing an institutional vision of sustainability. 3. Creating a leadership role for facilities managers in addressing sustainability. 4. Confronting economic challenges. 5. Fixing broken budget models. 6. Managing rising energy costs and energy volatility. 7. Engaging the campus to address energy challenges. 8. Managing space. 9. Prioritizing renewal needs. 10. Meeting the challenges of workforce development.

To read the full article please refer to: http://www.appa.org/tools/measures/documents/ThoughtLeaders2009ReportFinal.pdf

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1 October, 2010 .... we camped with the â&#x20AC;&#x153;four cornersâ&#x20AC;? airstream convention. 80 airstreams of different ages parked overlooking the albuquerque balloon fiesta

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how does the campus respond to the urban edge?

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cooper union, new york Urban sprawl and densification mean that universities which were once on the periphery of the city are now integrated into its urban fabric. To examine the way institutions respond their urban edge let’s looks at two contrasting case studies in New York - the neo-Classical University of Columbia and the up and coming Cooper Union.

When I looked in I had a moment where I was caught in the gaze of a student looking at directly at me whilst fixing her hair. It was unsettling and the experience evoked a memory of Beatriz Colomina’s analysis of Adolf Loos’ ‘House for Josephine Baker. Loos designed this house for the dancer as a series of rooms for him to frame Baker for his viewing pleasure in her domestic life. Culminating in a central backlit pool in which :

Cooper Union is so woven into the fabric of downtown NY that it is kind of sneaks up on you. There is no traditional fenced in campus – rather the university occupies 3 buildings and students frequent the shops, bars and eateries of the neighbourhood creating a seamless university precinct. Whilst being integrated into the city has its advantages, major issues it faces are those of publicity/privacy, identity and place that has been addressed through the introduction of a vertical piazza the new 41 Cooper Square Building.

“Swimmers can see their own body reflected in the window frames, superimposed on top of the visitor’s eyes, whose shadowy form is cropped by the frame... [their] narcissistic gaze is interposed as a layer on top of that of the voyeur.”

What is interesting about Cooper Union is that there is no sense of “us and them”. In the older buildings there is a dichotomy between the security guards at every entrance, and the visual permeability of the ground floor. A passerby can look directly into the study space of the library – the theatre of studying. At night the students are backlit; their focused and furrowed brows illuminated by the light emanating from their laptops. victoria bolton - some stuff [ed]

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2. Vertical Piazza Cut to the new 41 Cooper Square Building designed by Morphosis, which manifests the institution ideal as a centre for innovative teaching in Architecture, Art and Engineering. The key driver of this building is inviting in public and fostering community and collaboration through the internal grand staircase in the atrium. Unlike the old buildings, the new building is transparent and inviting manifesting the institutions goal of â&#x20AC;&#x153;free, open and accessible education. The ground level is an open semi-public space from which one can easily access the 200-seat auditorium and a gallery space located one level down. The real feature of this building is central staircase. It is 20 ft wide and connected all four levels of the building through a central atrium off which social and collaborative spaces hinge. Their generous proportions and location make them a place where people gather and meet (think of the Spanish Steps in Rome). What I love about this building is that it is social, sculptural and sustainable. It a joy to see both day and night as the light and shadows â&#x20AC;&#x2DC;reverberateâ&#x20AC;&#x2122; off its mesh skin.

Right and above : Images of the vertical piazza, Source: Morphosis

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columbia university, new york My first impression of Columbia University made me think of Robert Frost’s observation that “good fences make good neighbours”. The giant wall around the perimeter of this campus was affronting, it set a clear delineation between itself and the city of New York, and the neoclassic proportions and architecture were at odds with the city beyond. What is interesting is that this is all about to change with the proposed Manhattanville – a 17-acre extension of the campus which has recently received governmental approval.

McKim emulated the “City Beautiful” approach which focused on the use of axis and centralism. At Columbia the most important building, the Low Library, is placed at the centre of the intersecting major axes atop of set of stairs so that students could “climb the stairway to knowledge”. McKim set up simple rules for the layout of the masterplan which allowed for the steady addition of new buildings as funding became available.

Columbia University was established in 1754 as Kings College by King George II of England. It is fifth oldest institution in the USA. Originally located in 49th st and Madison it moved in 1897 to 116th and Broadway. The neo-classical university masterplan was designed by Charles Follen McKim (of McKim, Mead and White) and exemplifies the “City Beautiful” movement of the early 20th Century.

It’s interesting to note that McKim’s original the intention was to keep the north-south axis clear so that one could stand in front of the library and seamless read the city as an extension of the university, but the Butler Library now obscures that vista and makes the campus feel inward focused. The placement of one building within a view plane can significantly alter the perception of a campuses relationship to the city.

The notion of placing important buildings at the heart of the city with an open area for gathering known as the ‘agora’ harks back to the Hippodamian plan . This reference to the ancient world also extends to the vocabulary of the library which emulates the Panthenon in Rome and the herringbone pattern of the stone in the South Court is akin to that of the Roman Forum.

Right: Masterplan of Columbia’s Morningside Height’s Campus victoria bolton - some stuff [ed]

34 victoria bolton - some stuff [ed]

http://www.neighbors.columbia.edu/pages/manplanning/index.html

http://therealdeal.com/issues_articles/columbia-breaks-conventions-with-its-new-academic-building/

http://c250.columbia.edu/dkv/extracts/0240_low.html

http://www.columbia.edu/content/history.html

Resources:

As Columbia continues to grow the edges of the campus are being altered. The proportions of the City Beautiful Campus are being challenged by the new modernist and post-modernist constructions. The Northwest Corner Building designed by Rafael Moneo has recently caused a stir, and the pedestrian link to the Greene Building creates more connection to the city beyond. But the defined campus cannot accommodate the Columbia’s growth, hence “Manhattanville”. Manhattanville is the proposed new 17-acre satellite campus development designed by Renzo Piano and Skidmore, Owings & Merrill (SOM). This is currently under construction and is located in West Harlem in an ex-industrial zone. The new campus will include new buildings for the Business School, School of the Art and the School of Engineering and Applied Sciences. Unlike it’s Morningside Height’s campus, Manhattanville will seamlessly intergrate Columbia University into the city of New York. It’s defined series of blocks and focus on pedestrians will give it the potential to identify the campus as a neighbourhood. Will this be sufficient to a significant identity for the new ampus with a heart and soul? Or will it just be a seemless extension of the city like Cooper Union?

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cincinnati university From 1990 to 2000 the University of Cincinnati’s campus underwent a significant building program which now has it listed in Forbes ‘The Worlds’ Most Beautiful College Campuses’ putting it the same category as Stanford, Oxford and Princeton. Just 20 years ago this was not the case, the building program was ad hoc and the rate of student acceptance was in decline. The UC ‘Master Plan 2000’ is a clear example of the power of a good master plan to redefine an institution. The four guiding imperatives of the ‘Master Plan 2000’ were academic, open space, connectivity and quality of student life and services. • Academic: the establishment of state-of-the-art teaching and research facilities that put the University at the forefront of learning, culture and research development the world over. • Open Space: The creation of a campus for students that is conductive to learning and reinforces the University’s image and identity • Connectivity: The creation of a campus as a fully connected pedestrian environment whose many distinct districts and campuses are connected for both functional gathering and for reinforcing coherent identity • Quality of Student Life and Services: the recognition that learning extends beyond classroom and the provision of the various recreation, retail, social, dining, residential, cultural and administrative faculties and services that will radically remake the University campus into a thriving energetic, round-the-clock hub that stimulates all parts of a student’s development. victoria bolton - some stuff [ed]

For the purposes of this report we will focus on the physical changes to the campus namely the strategic open space and connectivity design of the campus. However there were a series of other initiatives which programmatically complemented and informed the built form. These included: • Internal initiatives: the establishment of the Medical Campus, an increase oncampus housing and more on-campus recreation including “Varsity Village”. • External Initiatives: an alliance with the Hospital, community partnerships and the development of light rail. The focus on the Campus design was on the creating a framework for the Open Space to make the campus people friendly. The understanding being that people’s experience of a university heavily dependant on their impressions of the campus which has more to do with the open space than the building that frame them. The landscape/urban design strategy was developed by Hargreaves Associates. Each of the eight districts were given distinct landscaped identities and connected through a series of pedestrianised routes which responded to the ‘force fields’. The campus was analysed to determine where buildings should sit relative to the open space, and these voids were filled by Starchitecture.

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Buildings from this period include: - Michael Graves, Engineering Research Centre, 1994 - Peter Eisenman, Aronoff Center for Art And Design, 1996 - Pei, Cobb Freed and Partners, College-Conservatory of Music, 1999 - Frank O. Gehry, Vontz Center for Molecular Studies, 1999 - Gwathmey Siegel & Associates Architects, Tangeman University Center, 2004 - Moore Ruble Yudell, Steger Student Life Center, 2005 - Morphosis (Thom Mayne), Campus Recreation Center, 2006 - Bernard Tschumi, Lindner Athletic Center, 2006 - STUDIOS Architecture, Care/Crawley Building, 2008

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on the road from las vegas to new mexico

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blog rant: sticky spaces + starbucks s in? y space pm k ic 1 t s :4 6 e r rs Why a 2010 @ I hing hou ts, c s ber 16, a k o e e t t e c t w c O a : 2 cu nt Blog budget road for ot just Less co o . t e 1 h e t u n d o – motion being ucks – n es, and pro tudents b , s r s r a t le fo S b a e Okay so t g v a g time re is a me to lo einated bever the conflictin education. The in er ff have co a s c k t c e ces rath nce a a swe tarbu t p S ir s is l e y d r h ia f t e r it o v r fo ee sIs ms. I for tuto becaus ternet. A tyauditoriu hat ference e r in p s e but also ree wireless in r n u t e e lec ution t sf d by tw than larg least one instit USA ha ype surrounde eir d e g t a educe th of a dle r dt n id w l’ o t a o a m n s n e , r k ie s m e t h en utu strateg xt 10 ing stud group of 10 ‘a r the ne oking at e f v lo o o someth lf d % a n 0 h by 4 about smen a lectures ion. busines s I realize that s s e s s o ver their p ne ears. book lo tops in ne. As o course aving a t y p li h la n e e r o v a s a e “in a cours is tha people them h 2. More or noted urse ly some eresting lly s t d s in e t fe it o is r t m p y co Ad wha ssfu universit asier to check e succe hat, but in to e s social c Starbucks hav f ‘sticky it 300 ronic log s in a t f c o o le w e in o a h ia head nce v some rate ch attenda an it is to count tudents a corpo d e t a e h r t ns c webinar atre”, in additio /bulletin t ’. o s n e c is he spa e’ I am lecture t omments on wik ky spac y bar on a late ic t ‘s c y t a s g s te of can po f dod When I carpet o n excellent sta o t g in r a i the ky s boards refer go to un pe er a stic ucks ha o h b t d r a s a r t t t n u (S e stud night ense torial ty ess), b 3. When more tu face-tocleanlin ional design s / r e fo n r o is ie f g e c at hy eats preferen hich gives them an educ arning s r. w space in to informal le place were g in ach instructo e t ir g e a in h r t r is y h e a f it e wit is re nd st ntially face tim ng out a e s. Esse a t h n e , t d e u e t s m ; th come to rn peer to peer otes people a le p ing rom ce us to n r p a m le a l c on orma chan ns and te of inf aggrega ler’ conversatio oo ‘waterc s. meeting

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As an architect and an educator I am fascinated by the places in which people learn. I believe that the built environment is the third teacher. Consequently I find the pedagogical trends that have emerged in the past 20 years due to the internet intriguing as they have significantly physically altered learning and teaching suite. Teaching is less didactic, more ‘active’ and experiential. Learning is not limited to the classroom, but can occur in any space one has access to the internet. As now learning occur in any space, therefore the notion of ‘place’ is more potent. Thus I believe we are on the cusp of significantly transforming our university campuses to focus more on the ‘genius loci’ and sense of community.

why should students physically go to university? how can we encourage them to choose go to campus? how can we make them want to stay there?

pedagogy victoria bolton - some stuff [ed]

Above: Learning Centres for student centric learning, Source: Dr Kenn Fisher

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designing for learning The advent of the digital age has seen a huge paradigm shift in the way information is disseminated. Pedagogy has shifted from being teacher-centric to learnercentric. Teacher-Centric Traditionally teaching was didactic – the knowledge was held by a professor who would ‘broadcast’ the information via a packed theatre hall. If you weren’t there you would miss out or have to get notes from someone else. Similarly the library was the cornerstone of knowledge for the university – students would have to physically go there to research information.

The physical implications for this were: - Broadcasting: large lecture theatre halls – for 200- 500+ people - Medium sized classrooms for 40-100 people - Small tutorial sized rooms for 6-25 - The library was a quite space for focused research Learner Centric However the introduction of the world wide web has completely shifted the knowledge base. If a student (or for that matter a layman) wants to find something out they just have to google it. The role of a teacher is becoming less about being an absolute authority on a subject and more of a guide to facilitate students learning - showing them how to evaluate data and information sets (get them to look at sources such as Wikipedia critically). Moreover there is an increased focus on online learning. A student’s base for learning is wherever their laptop (and wifi) is. Refer to Dr Kenn Fisher’s learning spaces on the right.

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Above: Macquarie Bank at 1 Shelley Street, Sydney | Middle: Tapscott’s ‘Grown Up DIgital’ Bottom Right: Glasgow’s Saltire Centre Learning Commons

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Every university in the nation has an online portal to load up course materials, have discussions and collate marks. The nature of these portals varies considerably from informal facebook like applications such as ‘Ning’ or the more rigidly structured WebCT. The implications of this increased online presence is less class time but more a lot more preparatory work for academics – marginally for coursework, but considerably more time spent answering questions online. It becomes harder for academics/tutors to be able to ‘switch off’. But this is an issue of our times – not limited to the HE sector.

Informal Learning and the ‘sticky campus’ As there is an increase of information and learning online there is less requirement for students to physically go to campus. Infact students can take courses entirely online. So why go? Answer: Make the campus AWESOME, make the learning environment a destination for students which is superior to working home, the beach or the local café. To this end universities have set about making incredible informal learning spaces or commons.

The physical implications:

Evolving Workplace

- Broadcasting: lecture theatres are being retrofitted with recording devices so that students can watch the information on-line (I have worked with a university in Sydney who were looking to reduce their physical lectures by almost two-thirds) - Smaller Tutorial Space for more focused discussions - it is anticipated that students will access the information prior to the class so tutorials are more focused on ideas or reviewing students work. - More experiential learning – in the form of TEAL labs, or workshops - Increased informal learning spaces where group work and study can take place – often this manifests as ‘learning commons’

Moreover today’s students are next year’s workers, thus we can see this phenomenon of informal learning manifest in the workplace in the form of “Activity Based Working” (ABW). This format of working has been adopted by Google in all of its offices and can be seen in Sydney at both Macquarie Group’s 1 Shelley Street and Commonwealth Bank’s Darling Quarter Offices.

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active teaching There is a lot of work being done on Technology Enabled Active Learning, also known as TEAL Labs. A site I highly recommend has been setup by North Carolina State University (NCSU) – http://scaleup.ncsu.edu/

The Student-Centered Activities for Large Enrolment Undergraduate Program, or SCALE-UP was established to create “a highly collaborative, hands-on, computerrich, interactive learning environment for large, introductory college courses” (Beichner)

Cooperative Groups According to Johnson, Johnson and Smith there are 5 critical characterics that define successful cooperative learning: 1. Positive interdependence. Team members have to rely upon one another and benefit from working together 2. Individual Accountability. Each member is responsible for doing his or her own fair share of the work and for mastering all the material 3. Face-to-face interaction. Some or all of the group effort must be spent with members working together

This project was initially piloted in 1993 in the faculty of the Engineering and Science and known as the IMPEC (Intergrated Maths, Physics, Engineering and Chemistry) project.

4. Appropriate use of interpersonal skills. Members must receive instruction and then practice leadership, decision making, communication and conflict resolution.

The concept was that the traditional lecture/ laboratory format would be replaced with a studio and workshop. The class size ranged from 50 to 100 and the staff to student ratio was varied 24:1 to 50:1.

5. Regular self assessment of group functioning. Groups need to evaluate how well their team is functioning, where they could improve and what they should do differently in the future.

In the class students would work through activities in small groups of 3-4, supported by 2-4 instructors.

This notion is also explained by Edgar Dale’s Cone of Learning, which is based on the premise that “the more you do, the more you learn”. victoria bolton - some stuff [ed]

Pedagogical Goals:

Grading

• Create a co-operative learning environment that encourages students to collaborate with their peers, questioning and teaching one another • Use PER-based activities as much as possible to minimise lectures • Coach students during activities by assisting them in answering their own questions and by letting • The studio/workshop is taught in 2 hour blocks organised in 5-15 minute segments interspersed with brief class wide discussions. Students are scheduled for 4-6 hours of studio/ workshop. • In-class activities focus on problem solving and conceptual understanding • Typical lectures are replaces with readings for which students are tested online prior to the class commencing. There is still a broadcast within the workshop/studio but this is limited to 10-15 minutes to provide a summary, overview or motivation. • Technology is used to provide a phenomenological focus for students , allowing date collection, analysis mathematical modelling, microcomputer-based laboratories and video-based laboratories as well as applets and simulations” • Students are asked to explain their thinking and resolve cognitive-conflict through semiSocratic dialogues.

Is not done on a typical bell curve this can discourage collaboration. Rather marks are earned throughout the term across a broad range of quizzes, lab notes with only 10-15% on midterms.

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Educational Impact Below is a table showing the results of 6000 students at six different institutions, who all took the same test. It shows demonstrates that students who in an interactive collaborative students had a better conceptual understanding of the subject. Key References: Robert Beichner et el “The Student-Centered Activities for Large Enrolment Undergraduate Programs (SCALE-UP) Project – www. ncsu.edu/per/Articles/Varenna_SCALEUP_Paper.pdf http://scaleup.ncsu.edu/

blog: libraries are no place for books e d and th ing store n will be e b s k o ctio of bo the colle amount 1 pm of times nd, the :4 la rs 2 e b @ m d nu 4, 2010 estimate ir rary b n of the vember li d. o e e s N s s : e u c g roportio c o p ok a h e o Blo rg ‘b o t la ir d ring a ve the the nee y of t ill be sto ave opted to ha h ie w it r S w a T v U d e e.g. re h wide “… Fac n, therefo d offer a y overcrowded n a collectio ’ on site. ls is ia r d se g books mate in alrea warehou libraries s of storin ater access e n ic o ic ti m v o r e n e d e gre k the new s aign s, aca lly I thin online th am far more n camp building a Persona more we store I s c u is y t p e a h h m T gle, ca rce ns. T ation. a od. The io c o rm t g s can goo fo p I d t in o a n e th a w th n e ll s f o d a g ti n e a a n in a hav by all to cess a dissert library ew build puses. They c e, n nd of a c . e a ly ts k t c to p s a ri ly c b o iz m like to the for c manus llege ca ection s ll than go ancient be an o f r t o c s e o c u n s th e m it o ra il p re space arch, ially lim ugh the work the al recording of sort thro arehousing to to artific impacting rese igit d t r p fo with w m n k e ig t at ersuing For boo bitious campa ey can gatively h e s been p t a n r m h a y O le y b g . ll e o a g equ ther arnin hich Go hem copies (w g and le haring t At teachin ollections by s ships, housing hard d by all. c rigour). er n e ot share t g n r on a a e re c n p a e n a l] ts re m ensiv ortia though p s a confe y x n d e m e o ing the r d s e e [c n s e v e Howe ar I att Upon s e . y s s t through ollections in le e u e s ri p la ra f m o d Lib next to m c the end ious ca c mons an librarian sitting e s r m k o p o C o selected g b g in ks the Learnin storing and sav r uses.” e of boo g the notion of . Dewy has space, e arehous e in s h w us b t u ri lo o o c u h s r ic d rid s fo st. De store l was aga post-modern an eing the a b building tr n m e o c fr d as rs. ve away g commons an what do by size any yea ries mo and has for so m mes arnin d o e le c As libra e rk g to o b in ed hard w y n e c o rk b n ti o s w ta to n of e ti s s u s a a he the q 0 sectio ewy h of book ersities, opies? There is opy of “An in the 72 m and a s true, D iv it le n d b u n a f a rt o c … mfo miu hub ardc 4ths to at a pre peer e feel co ith the h it is the e move made m But with space ccessibility and we do w ks out (unless 1.0), so now w . a ry oo op ards the libra throw b t. ting tow Photosh uide to e pedagogy shif e all must adap g th s t’ n o io . s id w m ie e g c li th in o g rn p a usin rying based le ut: wareho cation. pted va ecking o nd the lo or ave ado a h t s p e e ri k worth ch r ra s s e k b k li o n th 2/future li t o e r n b h Othe /2007/1 Differe s on w m rdcopy d o a c n h t. e l e o p a p e c th f lo td logs extent o t of books kep gblog.b to record extensive l n ligation http://bld s an a h ooks.htm y The exte rary has an ob it nivers wanted-b n U b u li y fe e n -o th d e s not s.com/ .g. Sy warehou ordpres tions (e .w ry ) e ra it ib s publica rl u or off eningyo ). f use (on archive http://gre wareho e cost o e th . th e f i. o s– on e locati conomic Whilst th rgely on the e la s depend

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universities are based on ratios 3 x Higher Degree by Research (HDR)

1 x Post Doctorate

1 x academic

20 x Effective FullTime Student Unit (EFTSU)

0.6 x General Staff

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... so if a campus has 50,000 EFTSU

ons of the ti a d n e m m o c ge once the re n a h c is th s e o implemented? ...how d re a rt o p e R y Bradle these ratios? t c e ff a g in rn a -le ... how does e victoria bolton - some stuff [ed]

“Labs embody the spirit, culture, and economy of our age… what the cathedral was to the 14th century and the office building was to the 20th century, the laboratory is to the 21st century” - Don Prowler, Labs21

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labs victoria bolton - some stuff [ed]

trends in lab design When talking about Lab Design there are some clear trends which kept coming up.

3. Design for Sustainability On average, a typical laboratory uses 3-8 times the amount of energy of a typical office building. Where does the energy go?

1. Flexibility In design to accommodate change – be generic not specific. Funding sources will change and the nature of the research will follow. Use a adaptable grid as the basis for design. Select furniture which can be disassembled and re-assembled.

2. Design for technology There are increasing research tasks which are computer based – consider how equipment, bench space and workstation may need to be integrated For teaching environments consider how interactive teaching equipment is integrated into the labs - e.g. the London Metropolitan University’s SuperLab or the University of Bristol’s Dynamic Lab Manual. Create state of the art conference education and presentation centres to provide high level multiuse access to advanced interactive computer systems 58

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What can we do? - Fume Cupboard – use efficient hoods (VAV preferably) educate users about electricity cost - HVAC – optimise ventilation rates and design low pressure drop HVAC design - Electrical – design appropriate plug loads; use lights that have sensors to turn off when lab is unoccupied - Natural Daylight into labs (where appropriate) for reduced energy use and occupant productivity - Minimise heating and cooling - analyse occupancy, fume hood and equipment location/density, climate - Maximise Energy Recovery - Use Renewable Energy Sources- such as fuel cells, photovoltaics or wind turbines. - Water efficiency (recycled, waterless urinals)

4. Share Resources Shared resources and expensive equipment across faculties and disciplines minimise space which can only be used by one group Specialist equipment such as SEMs, NMRs are expensive and if under utilised fall into disrepair (Case Study: UNSW’s Analytical Centre to see how this can be achieved)

5. Connectivity Create a Social Building which fosters opportunities for both formal and informal interaction across disciplines.

What is the capacity to do course work from home? How is it integrated? Are tutorials in large rooms or filmed/ streamed? Look at the pages on for more information

8. Metering and Commissioning Begin this at an early stage by an independent authority to pick up on problems and ensure equipment is functional and operational. Large saving to be made from correcting faulty equipment and practices,

Create a sense of community within the building Research has become more team based and this needs to be accommodated Meeting places break out/ meeting rooms atrium spaces – places for people to congregate outside of the their labs to talk with one another

6. More team based research Write up space and offices need to allow for teams to work together, and should be located in close proximity to the labs.

7. Home vs. University For undergraduates there is the question of learning from home vs. coming to university

Resources Daniel D. Watch, “Building Type Basics for Research Labs” 2nd Ed. (John Wiley & Sons, 2008) Brian Griffin, “Laboratory Design Guide” 3rd Ed. (Architectural Press, 2005) Labs21 Conference www.RealWinWin.org http://eetd.lbl.gov/emills/PUBS/Cx-Costs-Benefits. html www.BCxA.org www.PECI.org www.CaCx.org www.ASHRAE.org www.ACEEE.org

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the biodesign institute arizona state university Located on the eastern edge of the Tempe Campus, the Biodesign Institute is significant as both a physical gateway to the campus and an intellectual gateway for research on the campus. There are currently 32,500 m² (350,000 sqf) of research space across two buildings including research labs, offices and ancillary spaces. The basement level of Building A includes a specialised area for nano-engineering and research. The 13-acre site will eventually have another 2 buildings – bringing the total research space to 74,300 m² (800,000 sqf).

The BioDesign Institute, Arizona State University, Tempe, AZ

Where as traditional research facilities separate scientists via their speciality, there has been as increasing emphasis on “transparency of research” interdisciplinary research practices. There Architect: Gould Evan Associates (www.gouldevans.com) are 15 centres that occupy this building; with Lord Aeck & Sargent Architecture these have been organised around 4 key (www.lordaecksargent.com) strategic research focuses: biosignatures, biosensors (nano), bionics (cognitive) and Cost: $149.5 million biofactories (sustainability). Size: 32,552 sqm (350,392 sqf)

- 12,179 sqm (131,089 sqf) of lab space LEED Certfied Thanks to Tom Mason and Susan Quisenberry

This notion of interdisciplinary work is manifested architecturally as a large 4-storey atrium running the length of the building. The stairs are centralised and on the cross bridges there is ample room to stop and have a chat or use one of the white boards which are strategically victoria bolton - some stuff [ed]

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located throughout the building. In between building A and B is an area known as co-lab â&#x20AC;&#x201C; a larger informal space with seating and vending machines adjacent which provides a hub for researches to meet informally (showing off the values of communication, collaboration and connection). We meet Susan and Tom at the entry and pass through the secured access (which has a iris scan for after hours access). The most striking thing upon entry is how light and transparent the building is. The entire building is naturally lit by diffused light from the overhead skylight 4 storeys above. As we move through the building there is a clear delineation between the fully glazed offices on our left and then the open plan labs to our right.

connection through transparency The labs are designed to be open plan with all the services (water, air, etc) coming from above. Moreove all the joinery items are on wheels allowing for easy adaptability, adjustability and expandability. In its current layout there is a clear zoning of furniture with the lighter write up desks adjacent to the walkway, the research benches and then the â&#x20AC;&#x2DC;heavierâ&#x20AC;&#x2122; equipment closer to the service risers. A nice detail is the presence of the white boards at the end of the research benches, scrawled with noted they allow the passer by to see what is happening behind previously closed doors and makes the research activities truly transparent.

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What impressed me about this lab was the attention given to appropriate lab support. There are three types of lab support: 1. The equipment to support the labs directly accessible from the labs e.g. fume hoods 2. The shared lab support not directly accessible from the labs such as autoclaves, media prep, cold rooms, etc 3. Lab support pass-through which connect the open labs to the support zones, these spaces have been designed to be wide enough to afford large equipment which has a high heatload and/or are noise generating e.g. ultra-low freezers or centrifuges. All these support spaces are anchored off the vertical service chases to minimise service runs and allow for easy servicing, refer to diagram below. As you can see from the section both the chase and service penthouse a the easily serviceable. Servicing is a key item when designing research labs, the goals is not to have any days when the labs cannot operate due to maintenance as this is a huge cost issue. The ideal is to have a clear delivery system, zone for back of house, then research area and office space. The Biodesign Institute exemplifies this notion. In terms of delivery the building is 1.5m (5’) above natural ground level to allow for the a shared servicing between all four of the planned buildings, and account for the cross fall on the 13-acre site. The site itself has been landscaped with a Sanoran Desert Garden visible from all the offices.

Green Project: •Building A received LEED® Gold Certification •Building B received LEED® Platinium Certification •Fly ash – a waste by-product of coal burning power plants – was used to offset the energy demands of a typical concrete structure. •A reflective roof membrane and high-albedo paving materials mitigate the Phoenix area’s urban heat island effect. •A 5,000-gallon irrigation water cistern collects air conditioning condensate water, which eliminates the use of potable water in landscape irrigation. Rain water from the roof and paving are routed directly via pipes to the droughtresistant native desert landscaping. •Low-flow lavatories, kitchen sinks, showers and waterless urinals use 30 percent less water than conventional fixtures. •An exterior shading system on south and west facades controls unwanted heat from the hot desert sun. •The top portion of the interior shade louver system is automatically controlled to maximize daylight penetration by reflecting diffuse light onto the ceilings. •Office occupancy sensors automatically control artificial lighting, reducing both lighting energy demand and associated cooling loads. These strategies reduce energy use by 29 percent.

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OFFICES

LABORATORY

BOH SERVICE RISER

Typical Laboratory Level.

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OFFICES

LABORATORY

BOH SERVICE RISER

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plant room

back of house vertical chase labs services in ceiling interstitial floor vavarium

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offices

•Terrazzo floors were made with locally available materials, including area river rock. This pays tribute to the Salt River that flowed through the site long ago. •Ozone-friendly refrigerants were used to help mitigate ozone depletion. - An innovative variable-volume exhaust system was designed in place of a conventional, constantvolume system, reducing energy demand associated with meeting laboratory ventilation requirements in the desert. - A two-week flush-out was performed to improve indoor environmental air quality before occupying the building.

Project Awards 2006 Lab of the Year award from R&D Magazine References: ‘Connection Through Transparency – The Biodesign Institute at Arizona State University’, Lord, Aeck & Sargeant Architecture (2006) http://www.sourcesanddesign.com/ archives/0709/0709_green_scene.html http://www.dpr.com/projects/phoenix/ detail.cfm?ProjectID=321 http://www.biodesign.asu.edu/

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bill + sue gross hall uc irvine Gross Hall is located in the Science district of the campus. The key concept in the layout of the labs is that there are 3 zones of mechanical services – the workbenches, the equipment and the offices. There is no heavy equipment within the labs themselves rather the fridges, incubators etc are all located within a designated zone on the periphery of the lab (and central to the building) which has higher electrical and mechanical loading.

Bill + Sue Gross Hall, UC Irvine, CA

Design Strategies:

Cost: $80 million

Centralized Demand Controlled Ventilation – realtime indoor air quality monitoring, varies the ventilation rate

Size: 9, 300 sqm (100,000 sqf) LEED Platinum Certfied Thanks to Matt Gudorf + Lynette Willliams

Occupancy Based Controls – controls both ventilation system & lighting Natural Ventilation – operable windows linked with mechanical ventilation Smart Lighting Controls – day lighting sensors used with perforated blinds Energy Star Equipment – freezers, refrigerators, ice machines & copiers Air Handling System – larger components allow a low velocity system, reducing pressure drops throughout the system Building Exhaust – right sized exhaust system eliminates bypass air victoria bolton - some stuff [ed]

offices

laboratories hospital

deliveries around the back cast of CSI:NY 72

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public entry

office of the chief medical examiner, new york Office of the Chief Medical Examiner DNA Building, New York “Science Serving Justice” Architect: Perkins Eastman (http://www.perkinseastman.com/)

Lab Designer: Health, Education + Research Associates (www.herainc.com) Cost: $167 million Size: 33445 sqm (360 000 sqf) - 6500 sqm (70 000 sqf) of office space, - 5780 sqm (62 000 sqf) of lab space Thanks to Laurie Sperling, Mecki Prinz + Zoran Budimlija

I think the thing that surprises me the most about this lab is that whilst I have never been in a forensic lab, TV shows such as “CSI” have somewhat prepared me for what I am about to see. There is the crime scene reconstruction, the lab for the examination of cars involved in crimes and the analysis labs where cool scientists (like Abbey) analyse the DNA of the crime scene. However, for all its apparent similarities there is a lot of innovation and nuance in the design that one does not appreciate on TV. For starters this is a narrow site and the available footprint is much smaller than a typical lab. The designers have overcome this by the use of dumbwaiters which allow the main flow of evidence to be vertical rather than horizontal. The OCME building is on 26th Street, adjacent to the heritage Bellevue Hospital – an old sandstone and copper building from 1736 which is credited as the oldest public hospital in USA. These two Medical icons are connected at ground level by a common garden. The entrance lobby of the OCME is a grand 2 storey event with a security desk,

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waiting area, large pieces of art and an inscription on the wall reading “Science Serving Justice” – a fair call considering this building processes the majority crime DNA identification for greater NY – processing around 100,000 specimens per year. In fact this was the first lab in the USA to use Y-chromosome STR’s in forensic casework; and from 1999 it has been DNA testing sexual assault cases. Also, it is here that all 1618 victims of the September 11 were identified by DNA analysis. For the people who work in the labs the evidence is delivered at ground floor, it catalogued and it travels up to the first of the forensic labs. It’s interesting to note that the size of the samples from a piece of torn cloth, a glass, a gun to a king size mattress or even a car. So if you complain about filing paper – think about the type of filing these guys have to manage. Once the DNA has been extracted in the labs, it is tested using PCR and catalogued to be kept for umpteen years as per the legal requirements. What is interesting is that these Images of the labs inside OCME. Source: HERA

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samples move vertically through the lab via dumbwaiters; or in the case of amplification travel horizontally via passthroughs. The OCME also have a full level dedicated to training Medical Examiners, who also move vertically through the building as they progress. The labs themselves are accessed via bio-vestibules (for gowning/de-gowning) to protect both the evidence and the personnel. The labs, designed by HERA (who also designed the State of New Mexico Labs) are beautiful and functional. The layout has been arranged on a modular grid with repetitive functions centrally located to allow for future flexibility. These working labs of the building are located on the lower levels up to the height of the Bellevue Hospital. The circulation of these labs is along the northern face of the building which has been glazed to borrow the view of the adjacent heritage hospital; the aged sandstone and green copper juxtapose with the new sterile white labs. The labs salute the old traditions of nursing and are themselves a testament to the advances of medical technology.

The forensic labs on the lower levels deal with not only the minutia of DNA analysis but also crime scene reconstruction. We enter the lab of the Forensic Analysis and Reconstruction Unit (FARU), a is large room with fixed joinery and facilities at the extreme ends, and no other fixed furniture. Instead there is an expressed 2.4m steel grid on the ceiling from which technicians can hang partitions to set up the scene as per a crime. When we walk in there are two scenes in progress, one of which has a dummy in front of a wall with spattering of â&#x20AC;&#x153;bloodâ&#x20AC;? on the wall behind. Very CSI. With all this work comes a tonne of report writing and paperwork, lucky for the team at OCME they have some of the most spectacular offices in the city. To the east is a view to Manhattan, to the west an unobstructed view over the river and Brooklyn. Everyday the staff at OCME are able to look out over the city which they serve through science. (Also worth checking out is the extension to the Bellevue hospital next door by I.M. Pei)

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care crawley university of cincinatti The University of Cincinnati’s new Center for Academic and Research Excellence, also known as the CARE / Crawley Building, is home to state-of-the art laboratory and teaching spaces. It is strength is its internal urbanlike setting in the atrium which fosters interactivity and community. CARE Crawley, University of Cincinatti, Ohio “fosters collaboration between scientists and students” Architect: STUDIOS Architecture in collaboration with Harley Ellis Devereaux Cost: $177 million Size: 22,297 sqm (240,000 sqf) Gold LEED Certification Opened August 2008 -Thanks to Gregory Braswell and Jacquie Thomas

This building was one of my favorites of the trip because it had excellent technical and pedagogical spaces, which were supported by varying social spaces that created a sense of community. The main architectural feature of the building is the large nine storey glass atrium which connects the old Medical Sciences Building to the new laboratory space. The two buildings are physically linked by seven glass bridges which span between the old and the new. The new consists of six floors of open bench teaching victoria bolton - some stuff [ed]

laboratories with conference rooms and back of house ancillary spaces. At ground level there are a series of informal study spaces ranging from open seating, to semi-private booths to ‘study huts’ which the students/ scientists can book for meetings or discussions. In the centre of the space is the new research library. A glass circular construction which references the library at Alexandria.

Designers paid careful attention not only to high-tech qualities, but also to “humanistic elements” that nurture innovative thinking, scholarly collaboration and scientific discovery among researchers and students. - UC Media Release [http://magazine.uc.edu/issues/0904/construction.html]

In addition, the there is a new dining area, fitness centre and bookstore. The building received a LEED Gold Rating from USGBC. Some of the strategies adopted include: - Naturally ventilated central atrium space - Natural Daylight to 75% of the spaces, and views to daylight to 90% - Automated occupancy sensors in the classrooms and labs to control the lighting - Extensive stormwater system designed to hold 90,000 gallons of water used to irrigate the campus. - Reflective roofing material to reduce the radiant heat gain.

Above: Section through CARE/Crawley Atrium, Right: Photo though CARE/Crawley Atrium, Source: Greg Braswell

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Simulated Learning A key part of the teaching suite is the simulation labs. There are 16 doctor consult rooms located around a communal learning area. Students learn in a group environment (pictured bottom left) where they go through the theory and can practice on mannequins (e.g. how to insert needles into plastic arms bottom right). They then break off into the sixteen consult rooms (pictured top right) where they practice â&#x20AC;&#x2DC;typical scenariosâ&#x20AC;&#x2122; with actors. Their performance is recorded and analysed by the staff (pictured top left).

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Ground floor plan (NTS) victoria bolton - some stuff [ed]

fume-a-saurus

scientists using fume-a-saurus to extract the heat from equipment

tyranasaurus

stegasaurus

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(Image Source: HERA, OCME)

air flow On average 44% of a Laboratories energy usage is consumed by ventilation. Therefore the design and strategic management of air is very important. A key principle of ventilation design is that air will flow from low velocity to high velocity. Thus the circulation space will have a low velocity, a laboratory will have a higher ACH and the fume cupboards/ air extractors will have the highest velocity. Therefore is it important to understand the ventilation requirements â&#x20AC;&#x201C; how much play do you have with the variants in temperature? Air Changes per Hour (ACH)? What is codified? Standardized? Applicable? 1. Optimise Air Change Rates - Labs use a once-through airflow system - What is the safest lowest ACH (air change per hour) - 4-6 ACH at night 2. Reduce Fume Hood Energy use - VAV vs fixed volume - Locate supply air so that it doesnâ&#x20AC;&#x2122;t blow into fume hoods - Avoid locating Fume Hoods near circulation routes

3. Minimise simultaneous heating and cooling - Separate ventilation from thermal loads Moreover, using demand-based control of air change rates can more than halve the use of outside air in lab buildings. That is when a lab is in use it can have 8-10 ACH, and at night this can drop to 4-6 ACH. Further savings can be made when this is combined with the reduction of fume hood velocity to minimum flow rates (as prescribed in ANSI Z9.5). This demand based control of air-change rates has been used in over 75 facilities in the US. University of Pennsylvania (UPenn) where it is their campusâ&#x20AC;&#x2122;s single largest energy conservation measure, or at the ASU (Arizona State University) Biodesign Institute facility where they have calculated potential savings of about $1 million a year from this 330K sq. ft (gross) project. Demand based controls can also be used beyond the lab. At ASU they have adopted the Aircuity based demand control ventilation approaches in over 20 of their buildings including sports arenas, offices and classrooms.

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84 victoria bolton - some stuff [ed]

on the road from los angeles to las vegas

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“the stone age didn’t end because we ran out of stones” - Dr Trent, Labs21

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the future??? victoria bolton - some stuff [ed]

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what next? knowledge clusters... We as architects are designing buildings for the next 50 years, so we need to be mindful of what the campus of the future is and how the buildings we design respond to that narrative. Universities are no longer just for teaching and producing primary research, they are catalysts for economic development! When examining the discourse of the campus must look at how they integrated into the built fabric and anchors for knowledge clusters. What I would like to further analyse is the importance of place and the quality of the built environment into the discussion on knowledge clusters. Simultaneously taking the conversation about education out of the classroom and into broader context the role of universities within future regional development. What can we as designers do to cultivate a unique sense of place and identity? How can we develop the third spaces? Foster linkages and networks? Create anchors of activity? What elements in the built environment are critical? Increasingly universities are the anchors for knowledge clusters . The university acts as an attractor for talent to the local area where students’ explicit and tacit skills are developed, and primary research is conducted. The industry benefits by recruiting from the pool of talent, and there is an ongoing support form the university for the firm’s R + D. In addition both partners benefit from the greater network of knowledge. Successful examples include North Carolina’s Research Triangle Park and Hsinchu Science-based Industrial Park in Taiwan. In both these examples there is a strong symbiotic relationship between industry and academia. What I am finding in my research in on knowledge clusters is that the papers highlight the importance of university-industry connection, the governance, local leadership and place. Yet this idea of what makes place successful is largely undefined, but critical if incorrect.

“Japanese experience, such as the Kyoto Research Park, has shown that technology clusters grow and develop better when the people within them interact on a daily basis. Indeed, the lack of social interaction and need to welcome newcomers has been one of the biggest challenges for the two major Japanese science cities (Kansai Science City and Tsukuba Science City).” Looking forward I believe that universities need to strategically redefine their role and work with industry to develop knowledge clusters. There have been key recent examples of universities acting as the catalyst and anchor for these clusters, either forming organically as at in Massachusetts Institute of Technology’s ICT corridor of Route 128; or through strategic government intervention as in Japan’s MEXT “Regional Innovation Cluster Program” and METI “Industrial Cluster Program” . Research around what makes knowledge clusters successful highlight the importance of university-industry connection, governance, local leadership and place . Yet this idea of what makes place successful is largely undefined. Richard Florida in his writings on “creative capital theory” asserts the quality of place is a key draw card . This is evident in the Bay Area of San Francisco where UC Berkeley and Stanford University provide the anchor for Apple, Facebook, Google and AutoDesk – the power of physical location has overcome the delocalising capacity of the internet. victoria bolton - some stuff [ed]

Image Source: http://www.dangerousminds.net/tag/Neil-Young

Looking forwardfrom I believe thatof universities need to industry benefits by recruiting the pool talent, redefine their and work and there is anstrategically ongoing support form therole university for with industry to In develop knowledge clusters. There have been key the firm’s R + D. addition both partners benefit from recentofexamples of universities as the catalyst and the greater network knowledge. Successful acting examples anchor forResearch these clusters, either include North Carolina’s Triangle Parkforming and organically as at in Massachusetts Technology’s ICT corridor of Hsinchu Science-based IndustrialInstitute Park in of Taiwan. Route 128; or through strategic government intervention In both these examples there is a strong symbiotic as in Japan’s MEXT “Regional Innovation Cluster relationship between industry and academia. Program” and METI “Industrial Cluster Program” . What I am finding in my research in on knowledge around what knowledge clusters is thatResearch the papers highlight themakes importance of clusters successful highlight importance of university-industry university-industry connection, the the governance, local governance, local leadership leadership andconnection, place. Yet this idea of what makes place and place . Yet this idea of what successful is largely successful is largely undefined, but makes critical place if incorrect. undefined. Richard Florida in his writings on “creative “Japanese experience, such as the Kyoto Research capital theory” asserts the quality of place is a key draw Park, has shown that technology clusters grow and of San Francisco card . This is evident in the Bay Area develop better where when the within them interact UC people Berkeley and Stanford University provide the on a daily basis. Indeed, lackFacebook, of social interaction anchor for the Apple, Google and AutoDesk – the and need to welcome newcomers has been of the the de-localising power of physical location hasone overcome biggest challenges for the twointernet. major Japanese science capacity of the cities (Kansai Science City and Tsukuba Science City).” What I would like to further analyse is the importance of We as architects are and designing buildings theenvironment next 50 place the quality of thefor built into the years, so we need to be mindful of what the campus discussion on knowledge clusters. Simultaneously taking of the future is the andconversation how the buildings design out of the classroom aboutwe education respond to thatand narrative. Universities are norole longer into broader context the of universities within just for teaching and regional producing primary research, future development. they are catalysts for economic development! When can we as designers do to cultivate a unique sense examining the What discourse of the campus must look at of place How can we develop how they integrated intoand theidentity? built fabric and anchors for the third spaces? Foster linkages and networks? Create anchors knowledge clusters. of activity? What elements in the built environment are critical? Increasingly universities are the anchors for knowledge clusters . The university acts as an attractor for talent to the local area where students’ explicit and tacit skills are developed, and primary research is conducted. The

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thanks The Bolton Family: Mumma, Pappa, BB and MB Tim Martin + the Martin Family Juliette Churchill Geoff Hanmer, Mark Clements and David Holm. Lynette Williams Jacquie Thomas Nicole Robinson Jennifer Krack Anna-Marie Pittman + Rache Moore @ Fraggle Rock Tom Bassett, Minna Ninova + Andrea Marpillero-Colomina Christian and Ulysses Oliver (Marshmallow Productions)

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other stuff victoria bolton - some stuff [ed]