Public Perception and Acceptance of Low Carbon Electricity Technologies

Public Perception and Acceptance of Low Carbon Electricity Technologies
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This article discusses the importance of informing the public about low carbon electricity technologies and portfolios and addressing misconceptions and knowledge gaps in order to elicit preferences informed by correct and balanced information.

About Public Perception and Acceptance of Low Carbon Electricity Technologies

PowerPoint presentation about 'Public Perception and Acceptance of Low Carbon Electricity Technologies'. This presentation describes the topic on This article discusses the importance of informing the public about low carbon electricity technologies and portfolios and addressing misconceptions and knowledge gaps in order to elicit preferences informed by correct and balanced information.. The key topics included in this slideshow are public opinion, low carbon electricity, energy infrastructure, misconceptions, knowledge gaps,. Download this presentation absolutely free.

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1. Public choice in the mix of electric power generation Climate and Energy Decision-Making Center Annual Meeting May 21, 2012 Lauren A. Fleishman, RAND Corporation* lfleishm@rand.org Wndi Bruine de Bruin and Granger Morgan Engineering and Public Policy, Carnegie Mellon University *Work completed while at Carnegie Mellon

2. People hold gaps and misconceptions about low-carbon electricity technologies Many public opinion studies provide un- or under- informed and unreliable results In two studies, we have aimed to: Better inform people about low-carbon electricity technologies and portfolios Overcome the barriers of their misconceptions and knowledge gaps Elicit preferences informed by correct and balanced information Public acceptance can be a major obstacle to energy infrastructure development 2 www.nuclear-free.com http://blogs.chron.com midtownbrews.net

3. Participants receive homework materials that are technically accurate and understandable present 10 electricity technologies provide multi-attribute descriptions of the costs, risks and benefits of each technology facilitate the ranking of technologies at home 3 Materials: http://www.cedm.epp.cmu.edu/tool-public-lowcarbon.php

4. In a first study, participants asked to rank pre-determined low-carbon portfolios before and after a group discussion 4 Fleishman LA, Bruine de Bruin, W and Morgan, MG. (2010) Informed Public Preferences for Electricity Portfolios with CCS and Other Low-Carbon Technologies, 2010, Risk Analysis , 30(9):1399-1410. Mean participant portfolio rankings (SD), from 1 (best) to 7 (worst)

5. build a combination of new power plants [to meet increased demand] that you think is the best[It] must make 60 TWh of electricity per year, but release 50% of the CO 2 that would have been released using the original plan [current PA energy mix]. In a second study, participants are asked to create a low-carbon portfolio with a decision tool 5

6. Compare Screen 6 When you have saved 3 combinations you like, hit the compare button. Compare the combinations and decide which one you would like to use as your advice to the governor Participants designed portfolios before and after a group discussion

7. Participants 10 Workshops: Held at local community organizations Including 4-9 participants each Lasting 2.5 3.5 hours Carefully scripted following Risk Ranking procedures Paid $95 (to keep or donate to organization) 69 Participants: Ages 22 to 85 years old (m=53.9) 70% Females, 13% African-American or other minority All had HS diploma, 58% at least a Bachelor s degree 7

8. Technology Rankings 8 Graph shows mean participant technology rankings (SD), from 1 (best) to 10 (worst) Note: Superscripted letters next to mean technology rankings refer to Wilcoxon paired-rank tests results (p < 0.01), suggesting that: a: PC with CCS, Wind, PV Solar, IGCC, PC with biomass and PC were ranked significantly worse b: PC with CCS, PV Solar, IGCC, PC with biomass and PC were ranked significantly worse c: PV Solar, IGCC, PC with biomass and PC were ranked significantly worse d: IGCC, PC with biomass and PC were ranked significantly worse e: PC with biomass and PC were ranked significantly worse f: PC was ranked significantly worse Energy efficiency, nuclear, IGCC with CCS and natural gas were not ranked significantly different from one another Both coal technologies with CCS were ranked better than IGCC and PC IGCC with CCS ranked better than PC with CCS

9. 9 Participants mean standardized technology percentages standard deviation, where 0 is no inclusion and 100 is full inclusion in portfolio Note: Superscripted letters next to mean standardized technology percentages refer to t -test results ( p < 0.01) suggesting that standardized technology percentages of : a: natural gas, IGCC with CCS, wind, PC with CCS, PV solar, PC, IGCC, and PC with biomass were significantly less b: IGCC with CCS, wind, PC with CCS, PV solar, PC, IGCC, and PC with biomass were significantly less c: PC with CCS, PV solar, PC, IGCC, and PC with biomass were significantly less d: PV solar, PC, IGCC, and PC with biomass were significantly less e: PC with biomass was significantly less f: all other technologies were significantly less g: wind, PC with CCS, PV Solar, PC, IGCC, and PC with biomass were significantly less Portfolio Designs

10. Portfolio Designs Participants had to include at least one low-carbon baseload technology (natural gas, coal with CCS, nuclear) in portfolio Most frequent design included all three (58.2% pre-discussion, 60.3% post-discussion) The most common portfolio included energy efficiency, nuclear, natural gas, wind and coal with CCS (31% pre-discussion, 38% post- discussion) 10 Most common portfolio, on average, post-discussion

11. Overall Conclusions 11 It is possible to design communications to inform people about the costs, risks, benefits and limitations of low-carbon electricity technologies and portfolios Our informed participants designed diverse portfolios including nuclear, CCS, energy efficiency, wind and natural gas similar to EPRI full preferred coal with CCS to coal without CCS Results contrast those of other studies showing much lower preference of CCS and nuclear our participants were given balanced and comparative information and adequate time Source: www.epri.com EPRI full portfolio

12. Thank You! Lauren A. Fleishman, Ph.D. RAND Corporation lfleishm@rand.org Fleishman LA, Bruine de Bruin, W and Morgan, MG. Informed Public Preferences for Electricity Portfolios with CCS and Other Low-Carbon Technologies, 2010, Risk Analysis 30(9):1399-1410. Materials: http://www.cedm.epp.cmu.edu/tool-public-lowcarbon.php Funding provided by: 12

13. Back Up 13

14. Group Workshop Procedure Step 1: Step 1: Homework Assignment Received : Technology-related information Provided : Pre-discussion technology rankings Ste p 2: Ste p 2: Computer Tool ( pre-discussion) Received : Computer tool Provided : Pre-discussion portfolio designs Ste p 3: Ste p 3: Computer Tool ( post-discussion) Received : Pre-set portfolios Provided: P ost-discussion portfolio designs Experimenter explanation of homework materials & introduction of computer tool Group discussion : Participants present portfolio designs on a projected Compare screen 14

15. Participant comprehension and satisfaction 24 true-or-false homework knowledge questions M =90%, SD =11%, range: 46-100% Scores significantly better than chance (t=28.2, p < 0.001) 13 computer knowledge questions M = 93%, SD = 10%, range 62-100% Participants thought that using the computer tool was: an enjoyable experience ( M =6.5, SD =1.0, t =20.3, p <0.001) and a valuable use of [their] time ( M =6.4, SD =1.2, t =17.9, p <0.001) They learned a great deal about the different electricity options ( M =6.4, SD =1.2, t =16.3, p <0.001) 15

16. Standardized Technology Distributions 16