1
Low Carbon Development Plan
In Japan
Junichi FUJINO ([email protected]) NIES (National Institute for Environmental Studies), Japan
Workshop on A Systematic and Quantitative Design of Low Carbon Development Plan for Cambodia
Phnom Penh, 22 April, 2013
Designed by Hajime Sakai
1. If we cannot go to LCS,… 2. LCS offers higher QOL with less energy demand and lower-carbon energy supply 3. LCS needs good design, early action, and innovations
Japan LCS study by AIM 1990 start AIM (Asia-Pacific Integrated Model) project 1997 COP3 simulations (very hard battle with…) 2004-2008 NIES has coordinated Japan LCS research project funded by
MOEJ (led by Prof. Shuzo Nishioka with 60 team members) 2008-2009 COP15 simulations (AIM/Enduse[Japan], AIM/CGE[Japan],
AIM/Enduse[global]) 2009- Middle and Long term roadmap development under MOEJ (led by
Prof. Shuzo Nishioka with 8 working groups and more than 100 experts)
2011- Revision of “Energy and Climate Change Policy” by cabinet office
together with METI and MOEJ (with AIM)
2004-2008
Japan LCS research project
4 Research project on Japan Low-Carbon Society (LCS) scenarios development FY2004-2008 sponsored by Ministry of the Environment, Japan
5 teams: Scenario, Criteria, ICT, Transportation, Urban
2020 2050 2000
Long-term target year
Release of A
IM result
Technology development, socio-economic change projected by historically trend
Forecasting
Back-casting
Normative target world
Reference future world
Service demand change
by changing social behavior, lifestyles
and institutions
Mitigation Technology
development Required Policy intervention and Investment
required intervention policy and measures
Envi
ronm
enta
l pre
ssur
e
Checking year(2015)
Checking year(2025)
Requ
ired
int
erve
ntion
3. We need “Innovation”
to realize visions
2. We need “Visions”
1.”Target” is tough
50% reductions In the world
Forecasting from now and Backcasting from future prescribed/normative world
6
Depicting socio-
economic visions in 2050
Estimating energy service
demands
Exploring innovations for energy demands
and energy supplies
Quantifying energy
demand and supply to estimate
CO2 emissions
Checking potentials for energy
supply
Achieving energy- related CO2
emissions target
Step4
Scenario Approach to Develop Japan Low-Carbon Society (LCS)
Step1
Step2
Step3
Step5
7
Vision A “Doraemon” Vision B “Satsuki and Mei”
Vivid, Technology-driven Slow, Natural-oriented Urban/Personal Decentralized/Community
Technology breakthrough Centralized production /recycle
Self-sufficient Produce locally, consume locally
Comfortable and Convenient Social and Cultural Values
2%/yr GDP per capita growth 1%/yr GDP per capita growth
As for LCS visions, we prepared two different but likely future societies
Akemi Imagawa
Doraemon is a Japanese comic series created by Fujiko F. Fujio. The series is about a robotic cat named Doraemon, who travels back in time from the 22nd century. He has a pocket, which connects to the fourth dimension and acts like a wormhole.
Satsuki and Mei’s House reproduced in the 2005 World Expo. Satsuki and Mei are daughters in the film "My Neighbor Totoro". They lived an old house in rural Japan, near which many curious and magical creatures inhabited.
8
High efficiency lighting
【eg LED lighting】
Photovoltaic
Monitoring system equipped with appliances
Eco-life education
Reduce 60% warming energy demand, share 100%
34-69MW (25-47% house has PV on roof (now 1%)) and develop high efficiency (<30%) PV
COP (coefficients of performance=8), share 100%
Super high efficiency air conditioner
Solar heating Diffusion rate: 20-60%
(currently 8%)
Heat-pump heating COP=5 share 30-70%
Fuel cell share 0-20%
High-insulation
Reduce 1/2 energy demand Share 100%
Stand-by energy reduction
Reduce 1/3 energy demand, share 100%
LCS house in 2050 Comfortable and
energy-saving house
rooftop gardening
5
Utilizing solar power
High efficiency appliances reduce energy demand and
support comfortable and safe lifestyle
Good information for economy and environment makes people’s behavior
low-carbon
10-20% energy demand reduction
AIM (Asia-Pacific Integrated Modeling) for Japan LCS scenarios
Energy supply & demand
:Model
:Output of model
Macroeconomy
Stock Activity
Populationand
householdmodel
Residentialsector
Commercialsector
Transpor-tationsector
Industrialsector
Energybalance
table
Popu
latio
nLa
bor
Service
Mat
eria
l sto
ck &
flow
mod
el
Energy supplysector E
nerg
ysu
pply
m
odel
Efficiency
Build
ing
dyna
mic
mod
el
Envi
ronm
enta
l opt
ion
data
base
, Bot
tom
-up
engi
neer
ing
mod
el
Passenger Trns.demand modelFreight Trns.
demand model
Inte
r-se
ctor
and
mac
ro e
cono
mic
mod
el
Household Prd.& lifestyle model
Residential energyservice model
Commercial energyservice model
Industrial production model
Stock
Preference of household
Production amount
Investment
EnergySnapshot
Tool:Data flow Check consistency! Backcast
Model
10
17
10
23
9
3 43 4
0
10
20
30
40
50
60
70
2000 2050A 2050B
Ene
rgy
Con
sum
ptio
n (M
toe)
Change of the numberof householdsChange of servicedemand per householdChange of energydemand per householdImprovement of energyefficiencyElectricity consumption
H2 consumption
Solar consumption
Biomass consumption
Gas consumption
Oil consumption
Energy consumption in2000
Residential sector Energy demand reduction potential: 50%
Change of the number of households: the number of households decrease both in scenario A and B Change of service demand per household: convenient lifestyle increases service demand per household Change of energy demand per household: high insulated dwellings, Home Energy Management System (HEMS) Improvement of energy efficiency: air conditioner, water heater, cooking stove, lighting and standby power
Energy Efficiency
Insulation system
11
Energy demands for achieving 70% reduction of CO2 emissions
Seconday Energy Demands (Mtoe)
Industrial ResidentialCommercial
Trans. Prv.Trans. Frg.
0 50 100 150 200 250 300 350 400
2000(Actual)
2050(Scenario A)
2050(Scenario B)
Industrial Residential Commercial Trans. Prv. Trans. Frg.
Decrease ofenergy demand
Trans.Prv.: Transportation (Private), Trans.Frg.: Transportation (Freight)
40-45% energy demand reduces by structural
change of demand, and efficiency improvement
11
Possible energy demands reductions for each sector: Industry:structural change and introduction of saving energy tech. 20~40% Passenger Transport :land use, saving energy, carbon-intensity change 80% Freight Transport :efficient transportation system, energy efficient 60~70% Residential: high-insulated and energy-saving houses 50% Commercial: high-insulated building and energy saving devices 40%
We can reduce 50% energy input even satisfying service demand
12
Energy supply for achieving 70% reduction of CO2 emissions
Coal Oil Gas
Biomass
Nuclear
Solar and Wind
0 100 200 300 400 500 600
2000(Actual)
2050(Scenario A)
2050(Scenario B)
Primary Energy Consumption (Mtoe)
Coal Oil Gas Biomass Nuclear Hydro Solar and Wind
Centralized style Decentralized style Micro grid
12
Japan LCS research project and CC policy 0. FY1990- start AIM (Asia-Pacific Integrated Model) project FY1997 AIM provided Kyoto Protocol simulations for Japan FY2000 AIM provided IPCC SRES/A1B marker scenario
1. Feb 13th 2007, Interim Report “Japan Scenarios torwards Low-Carbon
Society (LCS) -Feasibility study for 70% CO2 emission reduction by 2050 below 1990 level-”
May 24th 2007 Former Prime Minister Abe launched “Cool Earth 50” to reduce 50% GHG emissions by 2050
June 9th 2008 Former Prime Minister Fukuda set the target of Japanese CO2 emissions reduction by 60-80% in 2050
2. May 22nd 2008, Interim Report “Dozen Actions towards LCSs” July 29th 2008 Japanese government set “Action Plan for Achieving a
Low-carbon Society”
3. April 2009, The Mid-term Target Committee, “six options for 2020” (including 7%, 15%, 25% reduction compared as 1990 level)
September 22nd 2009, New Prime Minister Hatoyama set the target as 25% for 2020.
2008-2011
LCS Middle (2020) and Long (2050) term
strategy and roadmap
for COP15 and further
0
50
100
150
200
250
300
350
2000 2010 2020 2030 2040 2050
CO2
emis
sion
s [M
tC]
80% in 2050
Japanese Emissions Targets towards 2050
Jump
Step
25% in 2020 (incl. credit?)
Hop Kyoto Protocol during 2008-2012 (Sink 3.8%, credit 1.6 %)
Japan Japan
Former Prime Minister Hatoyama 鳩山由紀夫
E-KONZAL Research and Consulting
0
200
400
600
800
1000
0
2
4
6
8
10
12
14
16
18
2019
00
1910
1920
1930
1940
1950
1960
1970
1980
1990
2000
2010
2020
2030
2040
2050
日本
の実
質G
DP(兆
円)
日本
のC
O2・
温室
効果
ガス排
出量
(億
トン
CO
2eq)
▲20% (90年比)
▲80%(90年比)
(100歳)
1) ( )内の年齢は、各年に生まれた人が2050年を迎えたときの年齢
2) GDPの将来値は国立環境研究所 脱温暖化2050プロジェクト A・Bシナリオの想定値
CO2
温室効果ガス
GDP
▲15% (90年比)
▲25% (90年比)
(80歳)(60歳)(40歳)(20歳) (0歳)
• An 80% emission reduction by 2050 will create a largely different society from today. It will be critical to strategically move forward under mid-term 2020 and 2030 targets that take into account this eventual 80% reduction.
16
GDP and Greenhouse Gases Coupling ⇒ Decoupling
Oil Crisis Onset of Financial Crises
Rapid Economic Growth
Japan’s Asset-Inflated Bubble Economy
Japa
n’s C
O2
and
GHG
Em
issio
ns
(100
mill
ion
tons
of C
O2
equi
vale
nt)
GHG
▲15% (Compared to 1990 level)
(0 years old) (20 years old) (40 years old) (60 years old) (80 years old) (100 years old)
1) Parenthesis indicates the age of which persons born in each respective year will be in the year 2050 2) Future GDP values are assumed values based on scenarios A and B from the NIES Low Carbon Society Research
Project 2050
Japa
n’s R
eal G
DP (t
rillio
n ye
n)
▲20% (Compared to 1990 level) ▲25% (Compared to 1990 level) 400
80% Reduction (Compared to the
1990s)
Interactions between simulations and policy assessments
17
Model calculations
Premise for the Macro-frame
Suppositions for the introduction of
countermeasures, etc. Overall review panel /
working group Examination
results Model
calculations
Display as rough draft
Checking of consistency Examination of specific plan
Necessary promotion policy
Social and economic impact
Volume of emissions Volume of reduction
• The model calculations maintain the overall alignment of the path, and the estimated volume of emissions and economic impact are evaluated.
• The overall review panel / WG examines a specific plan that will enable reductions in each field.
Case setting for 2020 estimate • 25% (1): including about 10% of international contribution and sinks • 25% (2): including about 5% of international contribution and sinks • 25% (3): Not including international contribution and sinks
At time of November 11 task force
[Technology]
[Society / Economy]
[People]
18
Industry Commercial Residential Transport
Greenhouse Gases Energy Supply
-2 0 2 4 6 8 10 12 14
18
Agriculture
Volume of greenhouse gas emissions (100 million tons of CO2 in 2007)
Local development (Rural communities)
Daily life
CO2 originating from power generation
Before shift
CO2 originating from power generation
After shift Manufacturing Industry + industry processes + F gases
Residences and buildings
Homes + buildings Railways / marine / air
Transportation
Forest sinks, etc.
Automobiles
Energy supply
(indirect emissions)
(direct emissions)
20
-400
-200
0
200
400
600
800
1,000
1,200
1,400
1,600
2005 MIJ SB Share
非エネ
CCS
エネ転
運輸
業務
家庭
産業
0
100
200
300
400
500
600
2005 MIJ SB Share
地熱
水力
原子力
新エネ
バイオマス
天然ガス
石油
石炭
Possibility on 80% reduction in 2050
Primary energy supply (million ton OEq)
GHG emission (million ton CO2eq)
Without nuclear, we have to depend much on renewable energy and CCS (Carbon Dioxide
Capture and Storage).
Possibility depend on how we design Japanese future. Service oriented society can achieve 80%
reduction with domestic CCS but industry oriented society needs foreign CCS
MIJ Share SB Made in Japan
sharing Service Brand
▲80
%
Vision of Society in 2050
1990 emission
Vision of Society in 2050
Hydro Nuc NG
coal
oil
Non energy Energy shift Transport Office Resident industry
CCS
Analysis by AIM/Enduse in Japan
21
359
413387
369
328309 298
0
50
100
150
200
250
300
350
400
450
Fixe
d
Low
Med
ium
Hig
h
'90 '05 '10 2030
Fina
l Ene
rgy
Con
sum
ptio
n (M
illio
n k
L of
Oil
Equ
ival
ent)
・EV/HV: 70 to 90% of new car sales ・About 40% improvement of freight vehicle
efficiency ・Eco-driving in practice : 15 to 40%(passenger),
25 to 55%(freight)
Transport
・Ensure all newly built homes and buildings use advanced insulation and energy saving designs/features
・High-efficiency water heater: 75 to 90% in households, 40 to 90% in commercial building
・Home/Building energy management system ・PV power: 28 Mil. kW in households, 38 to 73
Mil. kW in commercial building
Commerci
al
Residential
・Commercialization and popularization of best-available-technology
・Fuel conversion to natural gases
Industry
Final energy consumption in 2030 (low growth case)
[業務] 照明照度低減[運輸]貨物車単体対策
[産業]業種横断的技術[業務] 高効率空調
[家庭] 高効率家電[業務] 高効率動力等
[運輸]乗用車単体対策[家庭] HEMS
[業務] 外皮性能向上[電力]太陽光発電(住宅)
[業務] BEMS[業務] 高効率給湯
[家庭] 高効率照明[業務] 高効率照明
[電力]地熱発電[産業]エネ多消費産業固有技術
[電力]太陽光発電(非住宅)
[電力]風力発電[電力]中小水力
[電力]バイオマス・廃棄物発電[家庭] 高効率空調
[家庭] 高効率給湯[家庭] 外皮性能向上
40,000
80,000
120,000
160,000
200,000
0 40,000 80,000 120,000 160,000 200,000 240,000 280,000 320,000 360,000 400,000
[業務] 照明照度低減
[運輸]貨物車単体対策
[業務] 高効率空調
[業務] 外皮性能向上
[電力]太陽光発電(住宅)
[産業]エネ多消費産業固有技術
[電力]地熱発電
[業務] 高効率動力等
[産業]業種横断的技術
[運輸]乗用車単体対策
[電力]太陽光発電(非住宅)
[電力]バイオマス・廃棄物発電
[電力]風力発電
[家庭] 高効率家電
[業務] BEMS
[電力]中小水力
[業務] 高効率給湯[家庭] HEMS
[業務] 高効率照明[家庭] 高効率照明
[家庭] 高効率空調[家庭] 高効率給湯
[家庭] 外皮性能向上
40,000
80,000
120,000
160,000
200,000
0 40,000 80,000 120,000 160,000 200,000 240,000 280,000 320,000 360,000 400,000
削減費用と削減量との関係(3)・2030年 高位ケース
・ 政策による後押しなどによって長期の回収年で投資が行われるようにすると、削減費用は大きく変化する。 ・ 各主体が短期での投資回収のみを目指して投資を行う場合には、家庭部門や運輸部門の対策は削減費用が高い(投資回収年数が産業部門、家庭部門、業務部門、運輸部門で原則3年、再生可能エネルギー発電で10年の場合)。
削減費用(円
/tCO
2)
産業部門・投資回収年数 3年/10年(*1)
家庭部門・投資回収年数 3年(*1)
業務部門・投資回収年数 3年(*1)
運輸部門・投資回収年数 5年
再エネ発電等・投資回収年数 10年 *1 素材産業製造プラント・住宅・建築物は10年
産業部門・投資回収年数 12~15年
家庭部門・投資回収年数 8年(*2)
業務部門・投資回収年数 8年(*3)
運輸部門・投資回収年数 8年
再エネ発電・投資回収年数 12年
*2 住宅は17年,*3 建築物は15年
削減量(千トンCO2) 削減量(千トンCO2)
削減費用(円
/tCO
2)
22
※ 上記グラフが示す削減量は固定ケースと対策ケースの差である。本試算に用いたモデル内では、固定ケースと対策ケースでは原子力発電電力量を同等とし、対策ケースにおいて電力消費量が低減した場合には、火力発電の発電電力量が低減すると想定した。そのため、火力発電の排出係数として0.54kgCO2/kWh(使用端)を仮に用いて電力削減によるCO2削減効果を算出した。ただし、現実の電力設備の運用では電力需要の動向に応じてあらゆる電源で対応することから、全電源平均の係数を用いて電力削減によるCO2削減効果を算定する方法もあるため、実際の削減量はモデルの試算とは必ずしも 致しないことに留意が必要である
(2)我が国のエネルギー消費量・温室効果ガス排出量の見通し
第2部 小委員会等での議論を踏まえたエネルギー消費量・温室効果ガス排出量等の見通しの試算
The result by AIM/Enduse[Japan]
Mitigation cost curve in Japan to take aggressive emissions reductions options by 2030
Longer-term investment
Shorter-term investment
23
• As for the investment amount for global warming, half of the overall investment amount will be collected by 2020 and an amount equal to the investment amount will be collected by 2030 based on energy expenses that can be saved through technologies introduced.
<Low-carbon investment amount and energy reduction expense>
2010
2015
2020
2025
2030
Energy saving investment through
2020
Volume of reduction from energy saving technologies
Energy reduction expense from energy saving investment = approx. 51 trillion yen (25% reduction (3))
In the case of device with 10 year lifespan
Energy reduction expense from energy saving investment = approx. 53 trillion yen (25% reduction (3))
- 41 - 45 - 51
- 40 - 45 - 53
66 85 100
- 150
- 100
- 50
0
50
100
150
25% reduction
① 25% reduction
② 25% reduction
③
Additional investment (’11 – ’20 total)
Energy reduction expense (’11 – ’20 total) Energy reduction expense (’21 – ’30 total)
Relationship between low-carbon investment amount and energy reduction expense
Simulation results provided in June 2012
24
-3-2-10123
high
high
mid
dle
mid
dle
mid
dle
0% 0%* 15% 20% 25%%
com
pare
d to
refe
renc
e ca
se
FinalconsumptionCapitalformationGDP
Macro economic impact compared to reference case in 2030, Low economic growth case [Results from CGE]
0%*: Nuclear will be 0% in 2020.
mitigation options share of nuclear
-200
-150
-100
-50
0
50
100
150
200
low
mid
dle
high low
mid
dle
high
2010-2020 2010-2030
Tri.
Yen
energy saving
Others
Energy
Industry
Commercial
Transportation
Residential
Cumulative additional investment by 2020 and 2030 [Results from Enduse]
For discussion on future energy and mitigation plan after accident at Fukushima dai-ichi nuclear power plant of TEPCO.
CGE can use any values as parameters, but by using Enduse results, more realistic values are available.
2011.3.11-
Revision of Energy and Climate Change Policy
25
26 http://energy.gov/news/documents/050611__Joint_DOE_GoJ_AMS_Data_v3.pptx 26
Post-Fukushima Japan: Response to power deficiency
Ex) energy consumptions in 30 degrees (2010=100) 2011=84 2012=84
Ex) energy consumptions in 30 degrees (2010=100) 2011=95 2012=86
2010 average 2011 average 2012
2010 average 2011 average 2012
0 5 10 15 20 25 30 35 40
6000 5000 4000 3000 2000 1000 0
Temperature (average) degree
0 5 10 15 20 25 30 35 40
(1000kw)
Energy consumption in Tokyo electric power company (9am-21pm)
Energy consumption in Kansai electric power company (9am-21pm)
3000 2000 1000 0
Presentation by the Center for Low Carbon Society Strategy, the Japan Science and Technology Agency (JST), July 2012
2010
2011
2012 2010
2011 2012
Energy reductions in maximum peak demand in 2011 compared to 2010
28
Tokyo electricity Company (w/o regard to temp.)
Tokyo electricity Company (with regard to temp.)
Reduction target of peak demand
-15% (2011)
-
Large electricity customers
-29% (▲600) -27%
Small electricity customers
-19% (▲400) -19%
Household -6%
(▲100) -11%
2011 Total (July-Sept) -18% -
2012 Total (July-Aug)
Under calculation (Jul: -6.4% from
2011) -
Supply-Demand gaps Expected shortage of supply was 6.2GW Set up 15% reduction target in peak demand As a result, Achieved totally 18% (10.77GW) reductions compared to 2010 summer
Tohoku electricity company (w/o regard to temp.)
Kansai electricity company (w/o regard to temp.)
-15% (2011)
-10% (2011&2012)
-18% -9%
-20% -10%
-22% -14%
-15.8% -10% Under
calculation (Jul: +0.1% from 2011)
-11.1% (Jul: -10.6% from 2011)
Maximum peak demand (kW) - week days from 9:00-20:00
(10,000kW) Source: IGES 2011 using data from METI etc
05
1015202530354045
0 5 10 15 20 25 30 35
Ener
gy d
eman
d
Temp
Others (Commercial)
After 3.11 Before 3.11
million MWh
Response to power deficiency by sector
29
0
5
10
15
20
25
30
35
40
0 5 10 15 20 25 30 35
Ener
gy d
eman
d
Temp
Large consumer
Gap: 1700000 MWh
million MWh
0
5
10
15
20
25
0 5 10 15 20 25 30 35
Ener
gy d
eman
d
Temp
Household million MWh
Gap:2500000 MWh
Gap: 2000000 MWh
0
5
10
15
20
25
30
0 5 10 15 20 25 30 35
Ener
gy d
eman
d
Temp
Tokyo electric power company
Gap: 2700000 MWh
million MWh
Before 3.11
After 3.11
Source: IGES 2011 using data from METI
Demand measures of summer in 2011
• L/c voluntarily develop and implement a plan to reduce energy use during a peak demand (Such as shift adjustment of operation and business )
• Gov. invoked Article 27 of the Electricity Business Act (Limit electricity use)
Large consumer
• Gov. provided a list of energy-saving measures as examples (energy-saving of lighting, air conditioning, OA (office automation))
• Gov. promoted s/c to develop and announce voluntary energy conservation action plan (Provided a format)
• Gov. operated door-to-door visits and briefings
Small consumer
•Gov. provided the list of energy-saving measures for households •Gov. called for the implementation of energy saving through
media etc •Gov. distributed education materials about “energy-saving“ to
elementary and junior high schools
Household
• Gov. conducted energy-saving public campaign through various media
• Visualization of electric power supply and demand data (Electricity Forecast)
• Gov. announced the info of the tight power supply and demand
Cross-cutting
Source: METI 2012
April 2012 in Fukushima
× × × = CO2 Service input Energy Consumption CO2 Emission
Satisfaction level Service input Energy Consumption
Demand side
Primary Energy CO2 emission
Secondary Energy Primary Energy
Supply side
Efficient energy conversion tech
Low CO2 energy imput
Reconsider how much satisfaction
we can get thorough energy
Secondary energy× × = CO2 Emissions
How to increase service level
with Less service
input
Energy saving technology
Clean energy supply
technology
Satisfaction Level
※アンケート調査等に基づくものであり、医学的検証は必ずしも十分でない
(出典)伊香賀俊治、江口里佳、村上周三、岩前篤、星旦二ほか:健康維持がもたらす間接的便益(NEB)を考慮した住宅断熱の投資評価、日本建築学会環境系論文集、Vol.76、No.666、pp.735-740、2011.8
Effect to prevent disease Effect to temperature level
0
5
10
15
20
25
0 0.5 1 1.5 2 2.5 3 3.5
アンケート回
答の
室温
(℃)
熱損失係数Q (W/m2・K)
(出典) 南雄三,(2011),「ライフラインが断たれた時の暖房と室温低下の実態調査」,(財)建築環境・省エネルギー機構 CASBEE-健康チェックリスト委員会資料 より作成
※1:アンケート結果一覧をもとに作成。室温の回答に幅がある場合は、平均値を採用。なお、H11年基準未満の住宅のQ値は、H4年基準レベルと仮定。
※2:青森、岩手、宮城の3県において、3月に実施した調査の結果。グラフには、調査戸数54件のうち、停電後1~5日間の室温に関して定量的な回答があったもののみを記載。なおアンケート回答より、外気温は-5~8℃程度と推測
H11年基準 (Ⅱ・Ⅲ地域)
H11年基準 未満
H11年基準 以上
33 Examples of QOL improvement
disease rate (%)
before after
アレルギー性鼻炎 28.9 21.0
アレルギー性結膜炎 13.8 9.3
アトピー性皮膚炎 8.6 3.6
気管支喘息 7.0 2.1
高血圧性疾患 6.7 4.5
関節炎 3.9 1.3
肺炎 3.2 1.2
糖尿病 2.6 0.8
心疾患 2.0 0.4
このスライドは住宅・建築物WGとりまとめ資料を元に作成
(3)各部門における省エネ・CO2削減の効果 第2部 小委員会等での議論を踏まえたエネルギー消費量・温室効果ガス排出量等の見通しの試算
Expectations on Cambodia and Japan: “How to deploy LCS study to real world?”
Research members
Application and development to actual LCS processes
Development and maintenance of study tools/models
Each country’s domestic/ local research institute
Policy makers
Central/ regional
government managers
NGOs
Proposal/ collaborative activity on LCS scenario and roadmap makng
Request of more practical, realistic roadmaps and also tractable tools for real world
LCS is Risk Management • We always face to risks if we are alive. • Global warming is one of risks in our daily life, but it might
become one of the huge/ biggest risks in some future… • Overshoot (expect future technology development) / Early
Action (Stern Review) • Short-term Sweet (Benefit) / Long-term Legality • Neo Liberalism / Eco Modernization -> Smart Regulation • Crisis = 危(danger) + 機(chance) • 創(create) 新(something new) = Innovation • Sense of Urgency for Good Design of our Society
Junichi Fujino, à l’Iddri - 6, rue du Général Clergerie - 75116 Paris (Mo Victor Hugo) Vendredi 12 janvier 2007, de 11 heures à 13 heures
Sustainable Low-Carbon Asia
comes from design,
imagination and
co-working…
Let’s work together! [email protected]