General Equilibrium Analysis of the Cobenefits and Trade-Offs of

Jan 8, 2019 - ... and pollutants discharge module in Shenzhen, the fourth largest city in China. ... Shenzhen's GDP and welfare losses are projected t...
0 downloads 0 Views 447KB Size
Subscriber access provided by United Arab Emirates University | Libraries Deanship

Energy and the Environment

A general equilibrium analysis of co-benefits and trade-offs of carbon mitigation on local industrial water use and pollutants discharge in China Qiong Su, Hancheng Dai, Huan Chen, Yun Lin, Yang Xie, and Raghupathy Karthikeyan Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.8b05763 • Publication Date (Web): 08 Jan 2019 Downloaded from http://pubs.acs.org on January 11, 2019

Just Accepted “Just Accepted” manuscripts have been peer-reviewed and accepted for publication. They are posted online prior to technical editing, formatting for publication and author proofing. The American Chemical Society provides “Just Accepted” as a service to the research community to expedite the dissemination of scientific material as soon as possible after acceptance. “Just Accepted” manuscripts appear in full in PDF format accompanied by an HTML abstract. “Just Accepted” manuscripts have been fully peer reviewed, but should not be considered the official version of record. They are citable by the Digital Object Identifier (DOI®). “Just Accepted” is an optional service offered to authors. Therefore, the “Just Accepted” Web site may not include all articles that will be published in the journal. After a manuscript is technically edited and formatted, it will be removed from the “Just Accepted” Web site and published as an ASAP article. Note that technical editing may introduce minor changes to the manuscript text and/or graphics which could affect content, and all legal disclaimers and ethical guidelines that apply to the journal pertain. ACS cannot be held responsible for errors or consequences arising from the use of information contained in these “Just Accepted” manuscripts.

is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.

Page 1 of 23

Environmental Science & Technology

None 84x34mm (600 x 600 DPI)

ACS Paragon Plus Environment

Environmental Science & Technology

1

A general equilibrium analysis of co-benefits and trade-offs of carbon mitigation on local

2

industrial water use and pollutants discharge in China

3

Qiong Sua, Hancheng Daib, *, Huan Chenc, Yun Lind, Yang Xiee, Raghupathy Karthikeyana,f

4 5

aDepartment

of Water Management & Hydrological Science, Texas A&M University, College

6

Station, Texas 77843, USA

7

bCollege

8

cBelle

9

USA

of Environmental Sciences and Engineering, Peking University, Beijing 100871, China

W. Baruch Institute of Coastal Ecology and Forest Science, Clemson University, SC 29442,

10

dAtmospheric

Science and Global Change Division, Pacific Northwest National Laboratory

11

Richland, WA, USA

12

eSchool

13

fDepartment

14

Texas 77843, USA

of Economics and Management, Beihang University, Beijing 100191, China of Biological and Agricultural Engineering, Texas A&M University, College Station,

15 16 17 18 19

* Corresponding Author, Email address: [email protected] (H.C., Dai) Room 246,

20

Environmental Building, College of Environmental Sciences and Engineering, Peking University,

21

Beijing 100871, China; TEL/Fax: (+86) 10-6276-4974

22 23 24

Author contributions: Q.S. and H.C.D designed the research and developed the integrated model;

25

Q. S., H.C.D., H.C., Y.L., X.Y., R.K., analyzed data; Q.S., H.C.D wrote the paper.

1 ACS Paragon Plus Environment

Page 2 of 23

Page 3 of 23

Environmental Science & Technology

26

Abstract:

27

Carbon mitigation strategies have been developed without sufficient consideration of their impacts

28

on the water system. Here, our study evaluates whether carbon mitigation strategies would decrease

29

or increase local industrial water use and water-related pollutants discharge by using a computable

30

general equilibrium (CGE) model coupled with a water withdrawals and pollutants discharge

31

module in Shenzhen, the fourth largest city in China. To fulfill China’s Nationally Determined

32

Contributions (NDC) targets, Shenzhen’s GDP and welfare losses are projected to be 1.6% and

33

5.6% in 2030, respectively. The carbon abatement cost will increase from 56 USD/t CO2 in 2020

34

to 274 USD/t CO2 in 2030. The results reveal that carbon mitigation accelerates local industrial

35

structure upgrading by restricting carbon-, energy-, and water-intensive industries, e.g., natural gas

36

mining, non-metal, agriculture, food production, and textile sectors. Accordingly, carbon

37

mitigation improves energy use efficiency and decreases 55% of primary energy use in 2030.

38

Meanwhile, it reduces 4% of total industrial water use and 2.2-2.4% of two major pollutants

39

discharge, i.e., CODCr and NH3-N. Carbon mitigation can also decrease petroleum (2.2%) and V-

40

ArOH (0.8%) discharge but has negative impacts on most heavy metal(loid)s pollutants discharge

41

(increased by -0.01% to 4.6%). These negative impacts are evaluated to be negligible on the

42

environment. This study highlights the importance of considering the energy-water nexus for

43

better-coordinated energy and water resources management at local and national levels.

44 45 46

Keywords: Energy-Water Nexus, CO2 emission control, IMED|CGE model, discharge reduction,

47

China

48

2 ACS Paragon Plus Environment

Environmental Science & Technology

49

1. INTRODUCTION

50

With continuous population and economic growth, China has become one of the largest

51

greenhouse gas emitters since 2006.1 To mitigate climate change impacts, the Chinese government

52

announced its Nationally Determined Contributions (NDC) in the Paris Agreement to reduce

53

carbon dioxide (CO2) emissions per unit of GDP by 60% to 65% in 2030 compared with 2015

54

level.2 The implementation of China’s NDC is supposed to improve energy use efficiency and

55

accelerate industrial structure upgrading by decreasing the proportion of energy- and carbon-

56

intensive industries.3, 4 However, the industry structure upgrading may also have significant impacts

57

on water use and pollutants discharge in related industrial sectors considering that energy and water

58

are two basic inputs of industrial production.5-7 Given this context, modeling the impacts of China’s

59

NDC on energy use, economic development, water use, and water-related pollutants discharge is

60

crucial to design effective policies and measures for addressing energy and water issues.

61

Until now, energy-water nexus studies have been focusing on assessing the impacts of carbon

62

mitigation strategies on water use in a single8-10 or two11 industrial sectors. Carbon mitigation could

63

increase water consumption in the U.S. electric sector at both regional12 and national13 scales. But

64

the impacts have high uncertainty due to the choice of energy sources and the cooling system14-16,

65

e.g., the studies in China showed that carbon mitigation could promote renewable energy

66

technologies and reduce water consumption in the power generation sector.17,18 Previous studies

67

evaluated carbon mitigation impacts on water use in the power generation sector. The multi-sector

68

model like MARKAL was used to simulate the energy and water competition between

69

thermoelectric power generation and transportation sectors in the U.S. under different carbon

70

mitigation scenarios.11 However, these studies are limited to capture the cross-sector interactions

71

and feedbacks among economic, energy, and water system. Therefore, they cannot provide an

72

integrated view of how carbon mitigation strategies might affect the economic outputs and water

73

use in different industrial sectors.

3 ACS Paragon Plus Environment

Page 4 of 23

Page 5 of 23

Environmental Science & Technology

74

On the other hand, the impacts of carbon mitigation strategies on water-related pollutant

75

emissions have not been well evaluated. The co-benefits between energy use and pollutant

76

emissions in the energy-water nexus have been identified using technology-based bottom-up

77

approaches.19, 20 However, the changes in energy and water use and pollutant emissions that may

78

result from carbon mitigation are not quantitatively evaluated in these studies. In addition, sufficient

79

regional details of sectoral water use and pollutant emissions data are usually unavailable in

80

developing countries, such as China. To address these gaps, we evaluate the impacts of China’s

81

NDC on local industrial water use and water-related pollutants discharge by coupling a computable

82

general equilibrium (CGE) model with a water withdrawals and pollutants discharge module. The

83

industrial sectors include primary (e.g., agriculture), secondary (e.g., manufacturing, mining, power

84

generation, and construction), and tertiary industries. The CGE model could be used to simulate

85

the interactions between macro-economy and environmental system at regional or global scales.21

86

This integrated economic and water model could evaluate the impacts of carbon mitigation

87

strategies on economic, energy, and water system. Also, the possible co-benefits or trade-offs

88

across these systems could be identified to support the designing of effective policies and measures.

89

Our study selected Shenzhen as the study area. It is the fourth largest city in China and has

90

been chosen as a pilot city to perform China’s NDC. It had a total population of 0.7% of China and

91

consumed nearly 4.3% and 3.1% of total petroleum and natural gas use of China in 2007,

92

respectively (Table S1). Additionally, it has very limited local water resources and environmental

93

capacity and is challenged in fulfilling the national industrial water conservation and main

94

pollutants discharge reduction targets (i.e., chemical oxygen demand, CODCr, and ammonia

95

nitrogen, NH3-N).22, 23 Here, we aim (1) to assess the impacts of China’s NDC on the total amount

96

and intensity of energy use and sectoral CO2 emissions; (2) to evaluate the economic impacts in

97

Shenzhen when China’s NDC targets are achieved in 2030; and (3) to quantify the impacts of

98

carbon mitigation on local industrial water use and water-related pollutants discharge.

99 4 ACS Paragon Plus Environment

Environmental Science & Technology

100

2. METHODOLOGY

101

2.1. Integrated economic and water model

102

The integrated model includes 1) a city level CGE model and 2) water withdrawal and

103

pollutants discharge module. As shown in Figure 1, the CGE model can be used to estimate CO2

104

emissions, energy use, macroeconomic impacts, and detailed economic outputs for each sector

105

under different carbon mitigation scenarios. The model provides a comprehensive analysis of the

106

macroeconomic costs of carbon mitigation. The selected macroeconomic indicators include Gross

107

Domestic Products (GDP), government expenditure, welfare, import, and export. The economic

108

outputs for each sector are drivers of the water module so that the impacts of CO2 mitigation

109

strategies on sectoral water use and water-related pollutants discharge can be estimated.

110 111

Figure1 Research framework

112 113 114

2.1.1 The IMED|CGE model

115

The CGE model can simulate the future economic system (e.g., industry output, domestics,

116

and international trade) and capture the interactions and feedbacks among different industrial

117

sectors, final consumers, and rest of the world. The IMED|CGE (Integrated Model of Energy,

118

Environment and Economy for Sustainable Development | Computable General Equilibrium)

119

model used in this study has been widely used for assessing the economic and environmental

120

impacts of China's CO2 mitigation strategies at the city,4, 24 provincial,25, 26 and national3, 27 levels.

121

The version of this study is a single-region, recursive dynamic CGE model for Shenzhen City with

122

22 economic sectors (Table S2) developed by the Laboratory of Energy & Environmental

123

Economics and Policy (LEEEP) at Peking University. The 2007 input-output table and 2007 energy

124

balance tables of Shenzhen were used for the base year calibration. The model includes a production 5 ACS Paragon Plus Environment

Page 6 of 23

Page 7 of 23

Environmental Science & Technology

125

block, a market block with domestic, government and household incomes and expenditures blocks,

126

and international transactions, which is similar to the one-region version.28 The outputs for each

127

sector follow a nested constant elasticity of substitution (CES) production function. Inputs include

128

material commodities, energy commodities, labor, capital, and resources (including water use).

129

More details are included in Supporting Information, in addition, an up-to-date technical

130

introduction is available at http://scholar.pku.edu.cn/hanchengdai/imedcge.

131 132

2.1.2 Water withdrawals and pollutants discharge module

133

Once the economic outputs for each sector associated with different scenarios are known from

134

CGE simulations, the effects of CO2 mitigation strategies on water use and water pollutants

135

discharge can be estimated by multiplying time-evolving water intensity and pollutant discharge

136

intensity, as shown in Eqs. (1) and (2).

137

𝑊𝑡 = ∑𝑖𝑊𝑡𝑖 = ∑𝑖𝑂𝑈𝑇𝑡𝑖 × 𝑊𝐼𝑡𝑖 (1)

138

𝑃𝑡 = ∑𝑖∑𝑗𝑃𝑡𝑖𝑗 = ∑𝑖∑𝑗𝑂𝑈𝑇𝑡𝑖 × 𝑃𝐼𝑡𝑖𝑗 (2)

139

where, t is time (year); OUTti is the output of ith industry sector (million dollars); Wt and Pt represent

140

the total water withdrawals and pollutants discharge in year t; 𝑊𝑡𝑖 and 𝑊𝐼𝑡𝑖 are water withdrawals

141

(million tons) and water intensity (water withdrawals per unit output, m3 per million dollar) of the

142

ith industry sector, respectively. 𝑃𝑡𝑖𝑗 and 𝑃𝐼𝑡𝑖𝑗 are pollutant discharge (tons) and pollutant discharge

143

intensity (pollutant discharge per unit output, tons/million dollar) of the ith industry sector and the

144

jth type of pollutants including CODCr, NH3-N, Petroleum, Volatile phenol (V-ArOH), lead (Pb),

145

hexavalent chromium (Cr6+), mercury (Hg), cadmium (Cd), and Arsenic(As).

146

Time-evolving water intensity (WI) values were applied22 considering the relatively long-term

147

historical changes because of technology improvement, as shown in Eq. (3).

148

𝑊𝐼 (𝑡)𝑖 = 𝑊𝐼0𝑖 × exp (𝛼𝑖 × 𝑇) (3) 6 ACS Paragon Plus Environment

Environmental Science & Technology

149

where, WI0i is water withdrawal per unit Output (m3/million dollar) of the ith industry in the initial

150

year (2014); T is the number of year since the initial year; 𝛼𝑖 is the exponential rates of water

151

intensity of ith industry; and 𝑒𝛼𝑖 is considered the water intensity change rate (WR) of the ith

152

industry. Water use, or water withdrawals, are defined as the total amount of water removed from

153

water resources. The term ‘water consumption’ used in this study refers to water consumed and not

154

available to be reused anymore.

155

To reduce the source uncertainty, the four-year mean values of water use intensity in each

156

industrial sector were used for the initial year (WI0i,) calculation and were detailed in Table S3. The

157

rates of the technology-induced water use intensity change in different industrial sectors (WR) were

158

calibrated using regression analysis of the historical data during the period of 2000 and 2015, with

159

R2 ranging from 0.78 to 0.98 (except 0.53 in the agricultural sector) (Table S4). Though the

160

agricultural sector had a low R2 due to its high variability over time, its impacts are negligible given

161

that the water withdrawals from the agricultural sector only accounted for 4% of total water

162

withdrawals in 2015 in Shenzhen City.

163

A similar procedure was applied to calculate the pollutant intensity (PI) values of different

164

pollutants in each sector, as shown in Eq. (4).

165

𝑃𝐼 (𝑡)𝑖𝑗 = 𝑃𝐼0𝑖𝑗 × exp (𝛽𝑖 × 𝑇) (4)

166

where, PI0ij are the jth pollutant discharge per unit Output (m3/million dollar) of the ith industry in

167

the initial year (2014); T is the number of year since the initial year; 𝛽𝑖 is the exponential rates of

168

the pollutant discharge intensity of ith industry; and 𝑒𝛽𝑖 is considered the pollutant discharge

169

intensity change rate (PR) of the ith industry.

170

The initial year pollutant intensity values for each industrial sector were collected from the

171

pollutant sources survey of Shenzhen (2011-2014),29 and the mean value and its standard deviation

172

for each sector are provided in Table S5. The PR of CODCr was used to represent the technology7 ACS Paragon Plus Environment

Page 8 of 23

Page 9 of 23

Environmental Science & Technology

173

induced wastewater treatment improvement in different industrial sectors since it is the prime water

174

pollutant discharge control target in China. The PRs of CODCr were calibrated using regression

175

analysis of the historical data during the period of 1996-200730 with R2 ranging from 0.47 to 0.95

176

(Table S6). A national dataset (2002-2012) was used in sectors with insufficient data.31 Also, non-

177

point source pollution from the agriculture sector is not considered due to its relatively small

178

amount compared with emissions from other industrial sectors.6

179

180

2.2. Scenarios

181

Two scenarios, including a Business as Usual (BaU) scenario and a Nationally Determined

182

Contributions (NDC) scenario, are evaluated. The BaU scenario simulates the economic, energy,

183

and water system change without the implementation of explicit carbon mitigation policy or water

184

saving policies. The future GDP and population growth rate are based on our previous study22 and

185

the 13th Five-Year Plan for economic and social development of Shenzhen,32 as detailed in Table

186

1. The annual mean growth rates of GDP and population are set at 9.10% and 0.57% between 2007

187

and 2020, and 6.40% and 0.22% between 2020 and 2030, respectively. No CO2 emission intensity

188

constraint is considered in the BaU scenario. By contrast, the NDC scenario has a constraint on the

189

CO2 emission intensity of Shenzhen, which is set to decrease by 45% in 2020 and 65% in 2030 on

190

the basis of 2007 level, fulfilling China’s NDC commitment.2 The other settings in the NDC

191

scenario are the same as those in the BaU scenario.

192 193 194

Table 1. Configurations for the two scenarios.

195

8 ACS Paragon Plus Environment

Environmental Science & Technology

196

3. RESULTS

197

3.1. Energy use and CO2 emissions

198

Carbon mitigation substantially reduces the local CO2 emissions and energy use, i.e., by 67%

199

and 55% in 2030 compared with the BaU scenario, respectively (Figure 2). The total CO2 emissions

200

and the primary energy use under the NDC scenario in 2030 are projected to be 140.4 Mt and 0.30

201

EJ, respectively. The carbon intensity of Shenzhen in 2007 was 0.81 kg/USD, less than half of the

202

mean value of China (1.7 kg/USD). The carbon intensity shows a slightly increasing trend under

203

the BaU scenario, but with the carbon emissions constraint, it will decrease by 39% in 2020 and

204

64% in 2030, fulfilling the regional carbon intensity reduction target. In addition, the energy

205

intensity decreases by 49% in 2030 under the NDC scenario, and the energy intensity reduction

206

rate is much larger than the BaU scenario (decreases by 15%). When the constraint is imposed,

207

carbon emission allowance becomes a scarce resource, and a carbon shadow price is generated

208

endogenously in the CGE model. As explained in our previous study,33 the carbon shadow price,

209

or the carbon abatement cost, is considered the marginal cost to achieve the required emission

210

reduction target. It is an equilibrium price, which could balance the supply and demand of the

211

carbon emission allowance. The supply of carbon emissions is represented by the future GDP and

212

carbon intensity target, and the demand is determined by the emissions requirement of different

213

industrial sectors and households, which is influenced by the industrial output in different sectors

214

and households’ income level, respectively. The carbon abatement cost is evenly distributed in all

215

sectors and will increase from 56 USD/t CO2 in 2020 to 274 USD/t CO2 in 2030 because of more

216

stringent carbon constraints and adverse endogenous factors such as few available low carbon

217

technologies and higher renewable energy prices in Shenzhen. The carbon abatement cost increases

218

the production prices of all sectors, which is dependent on the carbon intensity of each sector. On

219

the demand side, consumers respond to the price changes and will accordingly adjust their activities

220

to decrease the demand for energy- and carbon-intensive products as well as fossil energy. 9 ACS Paragon Plus Environment

Page 10 of 23

Page 11 of 23

Environmental Science & Technology

221

Among all sectors in Shenzhen, the transport, natural gas, residential, power generation,

222

construction, services, and electronics sector are the main contributors to CO2 emissions and play

223

an important role in achieving carbon mitigation target. In 2007, these seven major sectors

224

accounted for about 82% of total CO2 emissions, i.e., transport (25%), natural gas (14%), residential

225

(10%), power generation (9%), construction (8%), services (8%), and electronics (8%) sectors

226

(Figure 2a). Under the BaU scenario, CO2 emissions from residential, services, and construction

227

sectors will significantly increase, while those from natural gas, power generation, and electronics

228

sectors are decreasing from 2007 to 2030. With carbon mitigation, CO2 emissions from most sectors

229

are projected to be reduced by 53%-89% and their carbon intensity will decrease by 29%-88% in

230

2030 compared with the BaU scenario. The residential sector will decrease by the largest amount

231

(70.5 Mt) in 2030, followed by transport (59.3Mt), services (36.1 Mt), and construction sectors

232

(19.5 Mt). Accordingly, the transport sector contributes the largest CO2 emissions under NDC

233

scenario, followed by services and power generation sectors. Unlike other sectors, the carbon

234

intensity of the power generation sector has a very limited decrease of 1% in 2030 under the NDC

235

scenario. The reason is that the power generation sector has high reduction rate of autonomous

236

carbon intensity since this sector can cut emissions through the adoption of renewable energy

237

resources and efficient technologies even without the implementation of carbon mitigation

238

strategies. For example, the nuclear power accounts for 47% of the total energy source in the power

239

generation sector in 2015 and the non-fossil power contributes an increasingly higher proportion

240

of the total power generation. Even without the implementation of carbon mitigation, its carbon

241

intensity decreases by 58% in 2030 relative to the 2007 level under the BaU scenario.

242 243 244

Figure 2. Variations in the (a) sectoral CO2 emissions and relative CO2 intensity, and (b) primary

245

primary energy use and relative energy intensity under different scenarios.

246 10 ACS Paragon Plus Environment

Environmental Science & Technology

247 248

3.2. Impacts on macroeconomics and industrial outputs

249

The implementation of carbon mitigation has macroeconomic impacts on Shenzhen with all

250

selected indicators decreasing since carbon emission is not a free product any more under the NDC

251

scenario (Figure 3a). Among these macroeconomic indicators, the export and import will be

252

influenced the most, with a loss of 3.3% and 3.6% in 2020 and 11.2% and 8.8% in 2030,

253

respectively. The consumption is projected to be reduced by 2.0% in 2020 and 5.6% in 2030. The

254

GDP and government expenditure will be slightly affected by a reduction rate of 0.1%-1.6% from

255

2020 to 2030. For example, the GDP loss of Shenzhen is projected to be 0.2% in 2020 and 1.6% in

256

2030, equivalent to 0.6 and 8.0 billion USD loss relative to the BaU scenario. The macroeconomic

257

costs here were compared with the study in Shanghai,4 another pilot megacity to perform China’s

258

NDC. To achieve the same carbon mitigation targets, the GDP and welfare losses of Shenzhen are

259

slightly lower than in Shanghai. In contrast, Shenzhen suffers more export loss than Shanghai. The

260

reason is that the main export products of Shenzhen are labor-intensive products such as textiles,

261

clothes, and toys. Those labor-intensive sectors suffer larger economic output loss with the carbon

262

mitigation constraints. As shown in Figure 3b, the sectoral outputs of some labor-intensive sectors

263

will be significantly affected, e.g., the manufactured gas sector will suffer the most loss (90%) in

264

2030, followed by natural gas mining (68%), transport (41%), non-metal (30%), and agriculture

265

(12%) sectors. Other labor-intensive industries such as food production, textile, services, and

266

construction sector also suffer noticeable output losses, ranging from 1% to 5%. To achieve the

267

carbon mitigation target, industrial sectors with higher carbon and energy intensity rely on reducing

268

productions and therefore would suffer economic loss. The projected total economic outputs loss

269

is larger in 2030 (4%) than in 2020 (1%) due to the higher carbon intensity mitigation rate. The

270

transport sector is the most influenced one and contributes to 64% of the total outputs loss. This is

271

because, in the current model settings, transport sector still relies on traditional gasoline combustion

272

engine which is vulnerable to the carbon cost. Shenzhen is home to the most famous electric vehicle 11 ACS Paragon Plus Environment

Page 12 of 23

Page 13 of 23

Environmental Science & Technology

273

manufacturer - Biyadi. Therefore, to further reduce the carbon intensity in the transport sector, the

274

Shenzhen government should promote the use of new energy automobiles, such as hybrid and

275

electric vehicles.

276

Carbon mitigation is beneficial to certain industries, e.g., the outputs of power generation

277

(6%), electronics (6%), and paper (4%) sectors will have a slight increase in 2030. In addition to

278

the higher reduction rate of autonomous carbon intensity in the power generation sector, carbon

279

mitigation decreases the proportion of direct use of fossil fuel and increases the electrification rate

280

in the whole economy. As a result, the production of the power generation sector will be expanded.

281

However, in regions with high shares of coal-fired thermal power and limited capacity of renewable

282

energy, power generation sector may suffer an economic loss under carbon mitigation, e.g., the

283

study in Shanghai.4 Electronics and paper sectors are easier than other sectors to reduce the carbon

284

intensity by adopting advanced technology and renewable energy resources, which is represented

285

in the CGE model by the substitution of energy by capital. Meanwhile, their production efficiencies

286

will be improved due to the lower carbon transformation.

287 288 289

Figure 3. Relative changes in (a) the selected macroeconomic indicators (b) the sectoral outputs

290

(using a Logarithmic scale) between NDC and BaU scenario in 2020 and 2030.

291 292

3.3. Impacts on water withdrawals

293

Carbon mitigation accelerates local industrial structure upgrading by restricting carbon and

294

energy-intensive industries. Since many of those industries are also water-intensive, it could be

295

observed that carbon mitigation has co-benefits on local industrial water withdrawals. Under the

296

BaU scenario, the total water withdrawals of Shenzhen will increase from 1,192 Mt in 2007 to

297

1,317 Mt in 2020, and to 1,252 Mt in 2030 (Figure 4a). Although the economic output in 2030 is

298

nearly four times that in 2007, the total water withdrawals only increase by 5%. The main reason 12 ACS Paragon Plus Environment

Environmental Science & Technology

299

is that water intensity will be gradually reduced due to the water-saving technology improvement,

300

e.g., the total WI reduces by 51% (2020) and 79% (2030) compared to the 2007 level under the

301

BaU scenario (Figure 4a). Carbon mitigation can further reduce total water withdrawals by 1% in

302

2020 and 4% in 2030, approximately 14 Mt and 47 Mt per year, respectively.

303

As shown in Figure 4b, carbon mitigation has uneven impacts on sectoral water use. To

304

reduce local water use, we would expect that industrial sectors with comparative higher water use

305

intensity appear in the co-benefits quadrant instead of in the worse-off and trade-offs quadrants.

306

The synergistic water-saving effect is observed in most industrial sectors, e.g., services, transport,

307

natural gas mining, non-metal, agriculture, food production, and textile sectors, and such effect is

308

enhanced in 2030 compared to 2020 with more stringent carbon constraints. Compared to the

309

sectors in the trade-offs quadrant, these sectors have higher WI, e.g., the mean water intensities

310

(2011-2014) of natural gas mining, non-metal, agriculture, food production, and textile sectors were

311

4, 4, 335, 3, 16 times of electronics sector (Figure S1 and Table S3). The decreasing proportion of

312

these water-intensive industries will improve total water use efficiency, i.e., total WI decrease by

313

less than 1% in 2030 compared with the BaU scenario. The limited decrease is because of the

314

expansion of the services sector, e.g., under the BaU scenario, its proportion in total output is

315

projected to increase from 24% in 2007 to 67% in 2030; in the same periods, the share of water

316

withdrawals from the services sector increases from 25% to 70% (Figure 4a). In addition, WI in

317

the services sector is close to the total WI, e.g., its WI is 5% higher than the total WI in 2030.

318

Accordingly, the diminishing of these water-intensive industries has limited effects on the reduction

319

of total water intensity. Services and transport sectors are the top two contributors to the reduction

320

of both carbon emission and water use (Figure 4b), and it is estimated that there is a high potential

321

to reduce water use by improving water use efficiency in the services and transport sector, e.g., a

322

10% reduction of industrial water use is expected in 2020 compared with the level in 2010 with the

323

use of water-saving devices in the these two sectors.5

13 ACS Paragon Plus Environment

Page 14 of 23

Page 15 of 23

Environmental Science & Technology

324

The carbon-water conflict is found in certain industrial sectors such as power generation,

325

paper, and electronics sector. Carbon mitigation promotes the production in these sectors. Thus

326

more attention should be paid to reduce water use intensity in these sectors, especially the power

327

generation sector in the worse-offs quadrant, which has higher water intensity (Figure 4b, Table

328

S3). Under the NDC scenario, water withdrawals from the power generation sector are projected

329

to be enhanced by 6% because of its production expansion. Such trade-offs in water use may be

330

exacerbated if high water use intensity technologies are used to reduce carbon emissions in the

331

power generation sector. Water use intensity of the power generation is dependent on the choices

332

of the cooling system and renewable energy penetration,15, 16, 34 e.g., carbon mitigation may promote

333

the adoption of high water use intensity technologies such as nuclear and coal-fired plants with

334

carbon capture and storage (CCS) technology and thus increase total water use in the power

335

generation sector,12,14 although large-scale deployment of CCS technology is not possible in

336

Shenzhen by 2030. In the study area, increasing the proportion of nuclear power may have co-

337

benefits in water use since seawater is used for cooling in nuclear power generation. A study in

338

China’s nuclear power plants showed that the freshwater use in plants equipped with seawater

339

closed-loop cooling technology is only 2% of traditional nuclear power plants.35

340 341 342 343

Figure 4 (a) Variations in the annual sectoral water withdrawals and relative water intensity under

344

different scenarios; (b) The carbon emission change (NDC compared with the BaU scenario) versus

345

water use change (NDC compared with the BaU scenario) in 2020 and 2030(Bubble size indicates

346

sectoral water use intensity. In quadrant 4 (grey area), sectors have no water use and energy use

347

change because of relatively small outputs).

348 349 14 ACS Paragon Plus Environment

Environmental Science & Technology

350

3.4. Impacts on water pollutants discharge.

351

As shown in Figure 5, carbon mitigation can reduce CODCr, NH3-N, petroleum, and V-ArOH

352

discharges, but slightly increase the discharges of heavy metal(loid)s, including Pb, Hg, Cd, and

353

As. In 2030, the CODCr, NH3-N, petroleum, and V-ArOH discharges under the BaU scenario are

354

estimated to be 1.9×104 t, 1.7×103 t, 10.1 t, and 0.8 kg, respectively. Under the NDC scenario, the

355

two main pollutants discharges will decrease by 2.2-2.4%, namely 431 t (CODCr) and 41 t (NH3-

356

N). The decrease of these two pollutants is also attributed to the local industrial structure upgrading

357

under the NDC scenario. Many of the carbon and energy-intensive industries have higher pollutants

358

discharge intensity, e.g., the mean CODCr and NH3-N discharge intensity (2011-2014) of non-

359

metal, food production, and textile sectors were 3, 4, 8 and 3, 4, 7 times the electronics sector (Table

360

S5), respectively.

361

Carbon mitigation has trade-offs on heavy metal(loid)s discharges, e.g., the Pb, Cr, Hg, Cd,

362

and As discharges will slightly increase by 0.43, -0.02, 0.03, 0.5, and 1.9 kg in 2030, respectively,

363

corresponding to increase rates of 2.0%, -0.01%, 4.3%, 3.8 %, and 4.6% of the BaU scenario.

364

Unlike CODCr and NH3-N, heavy metal(loid)s discharges are dominated by particular industries.

365

For example, under the BaU scenario the metal sector discharges 61% of V-ArOH, 53% of Pb, and

366

94% of Cr; the electronic sector discharges 46% of Pb, 38% of Hg, 81% of Cd, and 43% of As; the

367

power generation sector discharges 41% of Hg. Accordingly, these pollutants discharges are

368

sensitive to the implementation of carbon mitigation strategies. As mentioned in section 3.2, carbon

369

mitigation promotes the productions in electronics and power generation sectors and therefore

370

increase the discharges of Pb, Cd, As, and Hg. The increased discharges of heavy metal(loid)s have

371

limited impacts on the local water environment. The contributions of heavy metal(loid)s on the

372

Water Pollution Index (WPI) of Shenzhen River was as high as 5% during the period of 1984-1997,

373

but the heavy metal(loid)s discharge have been well controlled and their effects on water

374

environment became negligible since 1997.22

375

discharges will be decreased in 2030 relative to the 2007 level under both scenarios, e.g., Pb, Hg,

Our results show that the heavy metal(loid)s

15 ACS Paragon Plus Environment

Page 16 of 23

Page 17 of 23

Environmental Science & Technology

376

Cd, and As discharges are projected to decrease by 49%, 97%, 56%, and 63% in 2030 under BaU

377

scenario, respectively.

378

It should also be noted that the technology-induced reduction in pollutants discharge is larger

379

than the reduction induced by industrial structure change. As shown in Figure 5, the textile and

380

food production sectors are the top two contributors to CODCr and NH3-N discharges, accounting

381

for about 27% and 28% (CODCr), and 24% and 30% (NH3-N) in 2020 under the BaU scenario,

382

respectively. The pollutant intensity reduces much faster in the textile sector than in the food

383

production sector due to the wastewater treatment technology improvement (Table S6). With the

384

similar increase rates of economic outputs during the period of 2020-2030, the textile sector reduces

385

by 84% of pollutant emissions, but food production sector increases by 43% and becomes the top

386

emitters of CODCr and NH3-N in 2030 under both scenarios. Although carbon mitigation can reduce

387

pollutants discharge in the food production sector by 5%, more effort should be made to improve

388

cleaner technology.

389 390

Figure 5. Variations in the annual sectoral pollutants loadings under different scenarios.

391

392

4. DISCUSSION

393

4.1. Sensitivity Analysis

394

Given that the long-term projections may involve considerable uncertainties, we analyzed

395

several additional scenarios to gain a better understanding of how the water use and pollutants

396

discharge may potentially change with a range of different key factors. The uncertainties include

397

(1) the assumption of the future economic growth in the CGE model and (2) the calculation of the

398

future water withdrawals and pollutants discharge. The first uncertainty was assessed by adding

399

two GDP growth rates scenarios in the CGE model, i.e., the annual average GDP over 2007-2030 16 ACS Paragon Plus Environment

Environmental Science & Technology

400

was increased from 7.9% to 9.1% or slowed down to 6.7%, corresponding to the 28% higher or

401

22% lower GDP in 2030 than that in the BaU scenario. The energy use, CO2 emission, GDP loss,

402

water demand, and pollutants discharge in 2030 under the GDP_high and GDP_low scenarios are

403

compared with the values in the NDC scenario, and their relative change rates are shown in Table

404

2. The GDP and welfare losses are less sensitive to GDP growth rate changes than the energy use,

405

CO2 emission, water demand, and water pollutants discharge. In addition, the impacts of the GDP

406

growth rate changes on the energy use, CO2 emission, and water use are slightly larger compared

407

with most of the water pollutants discharges except for Hg. Regarding the secondary uncertainty,

408

we calculated the 95% CI of WR and PR in each sector, and their impacts on total water use and

409

pollutant discharges are also shown in Table 2. Water demand ranges between -17.0% and 29.7%,

410

CODCr and NH3-N discharges range between -5.0% and 29.8%, petroleum discharge between -8.5%

411

and 9.6%, Pb, Cr, Cd, and As between -0.8% and 3.6, and V-ArOH and Pb between -41.6% and

412

190.4%. This indicates that V-ArOH and Pb discharge are very sensitive to technology

413

improvement in wastewater treatment. Nevertheless, the projected V-ArOH and Pb discharge are

414

only 0.56 and 0.42 kg under NDC scenario in 2030 so that the large variability of these two

415

pollutants are not likely to have a significant influence on the results.

416 417 418

Table 2. Relative Changes from the projected values in 2030 under the NDC scenario

419 420

4.2. Policy implications

421

Currently, the energy-water nexus has been given scant consideration in the energy and water

422

management in China. One possible reason is that policy-making related to energy and water are

423

performed by different departments without fully understanding of the other’s needs. The integrated

424

model developed in this study captures the cross-sector interactions and feedbacks among

425

economic, energy, and water systems, and thus it can be used to help policymaker identifying the 17 ACS Paragon Plus Environment

Page 18 of 23

Page 19 of 23

Environmental Science & Technology

426

possible co-benefits or trade-offs across these systems and designing effective policies and

427

measures. The suggested strategies include: (1) mitigating the energy-water conflict. Carbon

428

mitigation promotes the electrification rate in the whole economy and expands the production in

429

the power generation sector in Shenzhen. Due to its relatively higher water use intensity than other

430

sectors, trade-offs in water use in the power generation sector are observed. In addition, carbon

431

mitigation at national scale can increase the shares of low-carbon energy in power generation in

432

China. This will probably increase the consumptive water use from power generation sector due to

433

the adoption of high water use intensity technologies such as nuclear and coal-fired plants with

434

carbon capture and storage (CCS) technology, especially in areas where freshwater is used for

435

cooling in power plants. However, power plants may prefer to save energy other than water under

436

the current examination system.35 Therefore, incentive measures such as allowances for water

437

saving and preferential taxes for power plants equipped with low water intensity technology should

438

be promoted to improve water use efficiency in power generation. In addition, to reduce the

439

negative impacts of carbon mitigation on the heavy metal(loid)s discharges, the local government

440

should close small-size plants which cannot satisfy the national discharge standards, particularly in

441

sectors such as chemical, metal produces, electronic, and power generation. Also, cleaner

442

technologies should be promoted in both existing and new plants by setting pollutant discharge

443

standards; (2) Promoting the energy-water co-benefits in the transport and services sectors. They

444

are the top two contributors to the reduction of both CO2 emissions and water use. It should be

445

noted that to fulfill the carbon mitigation target, the transport sector is projected to suffer significant

446

economic loss, e.g., its economic output will be reduced by nearly 41% in 2030 compared with the

447

BaU scenario. To reduce these economic losses, low-carbon transport policies including speed

448

control, an intelligent transport system, and mass transit systems improvement are suggested.36

449

These two sectors also have lower levels of water-related pollutant emissions and high potential to

450

reduce water use intensity, which implies that the local government should pay more attention to

451

the utilization of water-saving technologies in these sectors. 18 ACS Paragon Plus Environment

Environmental Science & Technology

452

Based on the analysis, more coordinated policies need to be designed to ensure water and

453

energy security in the future, especially in the light of governmental reform that the carbon

454

mitigation responsibility has been moved into the newly founded Ministry of Ecology and

455

Environment in 2018. The study highlights the importance of integrated approaches in energy and

456

water resources management. Although the current study focuses on a populated, developed

457

megacity in southeast China, the framework could be applied at the city, region, and national scales,

458

especially in areas with severe competition for energy and water resources.

459 460

4.3. Limitations

461

The effects of carbon mitigation on pollutants discharge in construction, transport, and

462

services sectors are not considered due to the lack of data in this study. In China, the water

463

pollutants discharges from these three sectors are assumed to be related to residential activities and

464

not reported separately. Considering the projected economic output decrease in these sectors with

465

carbon mitigation, the co-benefits on the water pollutants discharge may be underestimated. In

466

addition, with carbon constraints, some labor-intensive sectors, such as natural gas mining, non-

467

metal, agriculture, food production, textile, service, and construction sectors, suffer more economic

468

output losses. It implies that the future local labor force market would be significantly influenced,

469

and the total labor force demand is expected to decrease. Labor force migration accounts for nearly

470

70% of the total population in Shenzhen in 2016. Therefore, domestic water use and pollutants

471

discharge are expected to be greatly reduced. We did not consider this co-benefit in our study due

472

to the lack of detailed sectoral labor force data.

473

19 ACS Paragon Plus Environment

Page 20 of 23

Page 21 of 23

Environmental Science & Technology

474 475 476 477 478 479 480 481 482 483

Supporting Information. Table S1, selected indicators of Shenzhen and their percentages in China in 2007; Table S2, sector classification of the CGE model; Table S3, average water intensity (2011-2014) in different sectors; Table S4, estimated parameter values for water use intensity; Table S5, average pollutant discharge intensity (2011-2014) in different sectors; Table S6, estimated parameter values for pollutant intensity; Figure S1, the carbon emission change rate (NDC compared with the BaU scenario) versus water use change rate (NDC compared with the BaU scenario); Equations and parameters in the CGE model; Figure S2, production tree of basic sectors; Figure S3, production tree of energy transformation sectors.

484

Acknowledgment

485

The authors would like to thank Dr. Lei, Liu (Associated professor at the School of Public

486

Administration of Sichuan University, China) for assistance in collecting data of Input and output

487

Table and Energy Balance Table of Shenzhen. This research was supported by the National Natural

488

Science Foundation of China (51861135102,71704005, 71690241, 71690245), the special fund of

489

State Key Joint Laboratory of Environment Simulation and Pollution Control (18K01ESPCP), and

490

the Key Projects of National Key Research and Development Program of the Ministry of Science

491

and Technology of China (2017YFC0213000).

492 493 494 495 496 497

498

References

499 500 501 502 503 504 505 506

(1) International Energy Agency. World energy outlook. https://www.iea.org/publications/freepublications/publication/weo2009.pdf (accessed October 3, 2018). (2) UNFCCC. Adoption of the Paris Agreement. Proposal by the President. https://unfccc.int/documents/9064 (accessed October 3, 2018). (3) Dai, H. C.; Masui, T.; Matsuoka, Y.; Fujimori, S., Assessment of China's climate commitment and non-fossil energy plan towards 2020 using hybrid AIM/CGE model. Energy Policy 2011, 39(5), 2875-2887. 20 ACS Paragon Plus Environment

Environmental Science & Technology

507 508 509 510 511 512 513 514 515 516 517 518 519 520 521 522 523 524 525 526 527 528 529 530 531 532 533 534 535 536 537 538 539 540 541 542 543 544 545 546 547 548 549 550 551 552 553 554 555 556 557 558

(4) Wu, R.; Dai, H. C.; Geng, Y.; Xie, Y.; Masui, T.; Tian, X., Achieving China's INDC through carbon cap-and-trade: Insights from Shanghai. Appl. Energy 2016, 184, 1114-1122. (5) Qin, H. P.; Su, Q.; Khu, S. T., Assessment of environmental improvement measures using a novel integrated model: A case study of the Shenzhen River catchment, China. J. Environ. Manage. 2013, 114, 486-495. (6) Qin, H. P.; Su, Q.; Khu, S. T.; Tang, N., Water Quality Changes during Rapid Urbanization in the Shenzhen River Catchment: An Integrated View of Socio-Economic and Infrastructure Development. Sustainability 2014, 6 (10), 7433-7451. (7) Jiang, L.; Wu, F.; Liu, Y.; Deng, X. Z., Modeling the Impacts of Urbanization and Industrial Transformation on Water Resources in China: An Integrated Hydro-Economic CGE Analysis. Sustainability 2014, 6 (11), 7586-7600. (8) Zhang, X. D.; Vesselinov, V. V., Energy-water nexus: Balancing the tradeoffs between two-level decision makers. Appl. Energy 2016, 183, 77-87. (9) Ackerman, F.; Fisher, J., Is there a water-energy nexus in electricity generation? Longterm scenarios for the western United States. Energy Policy 2013, 59, 235-241. (10) Khan, Z.; Linares, P.; Garcia-Gonzalez, J., Integrating water and energy models for policy driven applications. A review of contemporary work and recommendations for future developments. Renew. Sust. Energ. Rev. 2017, 67, 1123-1138. (11) Dodder, R.; Felgenhauer, T.; Yelverton, W.; King, C., Water and Greenhouse Gas Tradeoffs Associated with a Transition to a Low Carbon Transportation System. Proceedings of the Asme International Mechanical Engineering Congress and Exposition, 2011, Vol 1 2012, 531547. (12) Talati, S.; Zhai, H. B.; Kyle, G. P.; Morgan, M. G.; Patel, P.; Liu, L., Consumptive Water Use from Electricity Generation in the Southwest under Alternative Climate, Technology, and Policy Futures. Environ. Sci. Technol. 2016, 50 (22), 12095-12104. (13) Cameron, C.; Yelverton, W.; Dodder, R.; West, J. J., Strategic responses to CO2 emission reduction targets drive shift in U.S. electric sector water use. Energy Strategy Rev. 2014, 4, 16-27. (14) Macknick, J.; Sattler, S.; Averyt, K.; Clemmer, S.; Rogers, J., The water implications of generating electricity: water use across the United States based on different electricity pathways through 2050. Environ. Res. Lett. 2012, 7 (4), 045803. (15) Clemmer, S.; Rogers, J.; Sattler, S.; Macknick, J.; Mai, T., Modeling low-carbon US electricity futures to explore impacts on national and regional water use. Environ. Res. Lett. 2013, 8, (1). (16) Chandel, M. K.; Pratson, L. F.; Jackson, R. B., The potential impacts of climate-change policy on freshwater use in thermoelectric power generation. Energy Policy 2011, 39 (10), 62346242. (17) Li, X.; Feng, K. S.; Siu, Y. L.; Hubacek, K., Energy-water nexus of wind power in China: The balancing act between CO2 emissions and water consumption. Energy Policy 2012, 45, 440448. (18) Huang, W. L.; Ma, D.; Chen, W. Y., Connecting water and energy: Assessing the impacts of carbon and water constraints on China's power sector. Appl. Energy 2017, 185, 1497-1505. (19) Wen, Z. G.; Xu, C.; Zhang, X. Y., Integrated Control of Emission Reductions, EnergySaving, and Cost-Benefit Using a Multi-Objective Optimization Technique in the Pulp and Paper Industry. Environ. Sci. Technol. 2015, 49 (6), 3636-3643. (20) Wang, C. Y.; Wang, R. R.; Hertwich, E.; Liu, Y., A technology-based analysis of the waterenergy-emission nexus of China's steel industry. Resour. Conserv. Recycl. 2017, 124, 116-128. (21) Zhang, C.; Chen, X.; Li, Y.; Ding, W.; Fu, G., Water-energy-food nexus: Concepts, questions and methodologies. J. Clean Prod. 2018, 195, 625-639. (22) Qin, H. P.; Su, Q.; Khu, S. T., An integrated model for water management in a rapidly urbanizing catchment. Environ. Modell. Softw. 2011, 26 (12), 1502-1514. (23) Su, Q.; Qin, H. P.; Fu, G. T., Environmental and ecological impacts of water supplement schemes in a heavily polluted estuary. Sci. Total Environ. 2014, 472, 704-711. 21 ACS Paragon Plus Environment

Page 22 of 23

Page 23 of 23

559 560 561 562 563 564 565 566 567 568 569 570 571 572 573 574 575 576 577 578 579 580 581 582 583 584 585 586 587 588 589 590 591 592

Environmental Science & Technology

(24) Tian, X.; Geng, Y.; Dai, H. C.; Fujita, T.; Wu, R.; Liu, Z.; Masui, T.; Yang, X., The effects of household consumption pattern on regional development: A case study of Shanghai. Energy 2016, 103, 49-60. (25) Dong, H. J.; Dai, H. C.; Dong, L.; Fujita, T.; Geng, Y.; Klimont, Z.; Inoue, T.; Bunya, S.; Fujii, M.; Masui, T., Pursuing air pollutant co-benefits of CO2 mitigation in China: A provincial leveled analysis. Appl. Energy 2015, 144, 165-174. (26) Xie, Y.; Dai, H. C.; Dong, H. J.; Hanaoka, T.; Masui, T., Economic Impacts from PM2.5 Pollution-Related Health Effects in China: A Provincial-Level Analysis. Environ. Sci. Technol. 2016, 50 (9), 4836-4843. (27) Dai, H. C.; Xie, X. X.; Xie, Y.; Liu, J.; Masui, T., Green growth: The economic impacts of large-scale renewable energy development in China. Appl. Energy 2016, 162, 435-449. (28) Dai, H. C. Integrated assessment of China's provincial low carbon economy development towards 2030: Jiangxi Province as an example. Ph.D. Dissertation, Tokyo Institute of Technology, Tokyo, 2012. (29) Shenzhen Statistical Bureau. Shenzhen statistical yearbook (In Chinese); China Statistics Press: Beijing, 2011-2014 (30) Shenzhen Statistical Bureau. Shenzhen statistical yearbook (In Chinese); China Statistics Press: Beijing, 1996-2007. (31) NBS. China statistical yearbook 2012 (In Chinese); China Statistics Press: Beijing, 2012. (32) Shenzhen Municipal Government. 13th Five-Year Plan for economic and social http://www.szpb.gov.cn/xxgk/ghjh/fzgh/201604/P020160412406655403778.pdf (accessed October 3, 2018). (33) Su, Q.; Dai, H.; Lin, Y.; Chen, H.; Karthikeyan, R., Modeling the carbon-energy-water nexus in a rapidly urbanizing catchment: A general equilibrium assessment. J. Environ. Manage. 2018, 225, 93-103. (34) Li, M. Q.; Dai, H. C.; Xie, Y.; Tao, Y.; Bregnbaek, L.; Sandholt, K., Water conservation from power generation in China: A provincial level scenario towards 2030. Appl. Energy 2017, 208, 580-591. (35) Lin, L.; Chen, Y. D., Evaluation of Future Water Use for Electricity Generation under Different Energy Development Scenarios in China. Sustainability 2018, 10 (1), 30. (36) Zhang, R. S.; Fujimori, S.; Dai, H. C.; Hanaoka, T., Contribution of the transport sector to climate change mitigation: Insights from a global passenger transport model coupled with a computable general equilibrium model. Appl. Energy 2018, 211, 76-88.

22 ACS Paragon Plus Environment