New Green NCAP emissions ratings cast doubt on electric cars’ green credentials

Green NCAP, the sustainability offshoot of Independent crash test body Euro NCAP has launched a new life cycle assessment (LCA) programme designed to help consumers choose the most eco-friendly cars.

A total of 61 cars have been assessed for the first phase of the LCA under Euro NCAP’s Green NCAP banner, with an electric Fiat 500 coming out as the car with the smallest whole-life CO2 footprint. However, in contrast to its crash test results, Green NCAP is not offering consumers an easy to compare star rating system. Instead it is providing a ‘best and worst case’ range for each model giving an indication of its eco performance.

There are two key rating elements that make up the Green NCAP LCA results. One rating is for lifetime greenhouse gas emissions, which is an indication of how much CO2 a new car will produce from its manufacture, through a lifetime of use based on 240,000km (around 150,000 miles) of driving over 16 years, to recycling at the end of its life.

The second rating is Primary Energy Demand (PED) which calculates the total amount of energy required over a similar cycle of manufacture, usage and recycling – irrespective of how that energy is derived, be it from renewable energy, fossil fuels or nuclear. Interestingly, in terms of its total demand for energy, a diesel Skoda Octavia Estate has the lowest PED rate of all the cars so far assessed.

According to Green NCAP, consumers should attach the same importance to PED as they do to greenhouse gas emissions. “PED represents the sum of all primary energy extracted from nature to provide the transportation, including coal, oil, natural gas, hydro energy, wind, waste, solar and nuclear energy. As energy supplies are scarce and valuable, they should be utilised wisely and the efficiency of all processes in a vehicle’s life cycle maximised,” it says.

As you might expect, NCAP’s results show that a large electric vehicle needs a lot more energy than a small one and that an electric vehicle in general may have similar or even a higher primary energy demand than a comparable conventional car. For all types of powertrain, the highest PED demand is during the usage phase, so it’s important to reduce consumption of fuel – whether electricity or petrol/diesel – as much as possible, the organisation says.

The best and worst case scenarios given for each car reflect different driving styles, ambient conditions as well as the energy mix prevalent in different countries. For example the same battery electric vehicle (BEV) may provide low greenhouse gas scores in Sweden where it’s likely to be charged exclusively from renewable power, but across its lifetime the same car could generate more greenhouse gas than a petrol equivalent in Poland, where most electricity is generated from coal. Likewise a battery EV could lose half its efficiency if temperatures reach -7 degrees.

A significant conclusion drawn by Green NCAP is that “while compact and mid-sized BEV show slightly less life cycle GHG emissions than conventional powertrain cars in the context of the European average electricity mix, big and powerful BEVs may be in the same range as most diesel or petrol vehicles”.

The organisation states: “While it is true that electric powertrains are highly efficient and the ability to recuperate kinetic energy mitigates the energy losses, the impact of mass remains obvious. The LCA analysis also highlights the increased contributions of the production of a heavier chassis, bigger high voltage batteries and the manufacturing of more electric components, like cables and power circuits, to the estimated greenhouse gas output.”

Green NCAP’s LCA ratings are available here: https://www.greenncap.com

While the UK government is committing £billions to incentivise a rapid switchover to electric cars, Green NCAP’s Technical Manager Aleksandar Damyanov suggests the results of his organisation’s lifecycle assessments show EVs are not a panacea for the climate crisis.

We asked Damyanov whether, given the relative parity between EV and ICE for lifetime greenhouse emissions, it was right for policymakers to focus so much attention – and cash – on incentivising EVs.

“I’m not sure I can state that,” he says. “If the target is reducing CO2, we have options. There is justification for electric if I’m driving only a few kilometers every day, if I don’t need a big car, and if I can charge with a good renewable energy mix. If I’m using an electricity mix that is dirty, and the calculations are not better than a conventional vehicle, I would say something different.” 

Illustrating the point, Damyanov contrasts the car producing the least lifetime C02 – the electric Fiat 500 – with the Ford Mustang Mach-E: “A 2.2 tonne electric vehicle is a different story,” he says. “Of course you can charge it with a hundred percent renewable electricity and this will be better, but in reality who is doing that?” 

Damyanov maintains EVs tend to be compared in best case scenarios, driven by renewable electricity or nuclear electricity, which makes their carbon footprint look advantageous. “This is the political climate that we have now,” he says. “The European commission [like the UK] provides no benefits or incentives for renewable eFuel, so it distorts the balance in favour of EVs. The optimal solution means leaving all possibilities open, so the target should not be to put electric vehicles on the market, but to reduce C02. If a vehicle is emitting nothing in England, but is produced with dirty energy in Asia, how does that help?”

According to Damyanov there should be much greater focus on eFuels in future, synthesised from renewable energy. “The internal combustion engine has a very bad image,  but it is not the engine, it is the fuel that we put in it. If we fill it with dinosaurs, that is our problem. It will burn what it has to burn.” 

Damyanov says he’s under no illusions that his work will draw criticism. “There are people who see only black and white, and there are the EV freaks and the petrolheads,” he says. The only thing we can do is serve the customers, the consumers, who are the biggest stakeholder that we have. 

“If you see a commercial for a big electric SUV, and it says ‘save the planet’, is it really doing that? The manufacturer will say, yes, of course, and others will provide arguments from the other side. Our role is to inform the best way we can, in a very neutral manner.”

Lifetime Greenhouse Gas Emissions(Tons C02-eq)

Lifetime Greenhouse Gas Emissions

Lifetime Greenhouse Gas Emissions

Lifetime Primary Energy Demand

(MWh)

Lifetime Primary Energy Demand

Lifetime Primary Energy Demand

Average

Best

Worst

Average

Best

Worst

FIAT 500

87 KW ELECTRIC 4X2 AUTOMATIC

31

26

25

171

134

198

Lexus UX 300e

ELECTRIC 4X2 AUTOMATIC

38

31

48

207

154

273

Nissan LEAF e+

A03 ELECTRIC 4X2 AUTOMATIC

38

34

45

207

154

273

Toyota Prius

1.8 PLUG-IN HYBRID 4X2 CVT

40

30

54

167

123

232

Škoda Octavia

COMBI 2.0 TDI DIESEL 4X2 MANUAL

42

38

49

164

151

193

Peugeot 208

1.5 BLUE HDI 100 DIESEL 4X2 MANUAL

43

37

48

169

144

191

Toyota Yaris

1.5 HYBRID 4X2 CVT

44

35

55

175

140

220

MAZDA2

SKYACTIV-G 55KW PETROL 4X2 MANUAL

45

43

50

182

173

202

Ford Mustang Mach-E

ELECTRIC 4X4 AUTOMATIC

46

43

55

246

223

311

Honda Jazz

1.5 I-MMD HYBRID 4X2 CVT

46

37

59

183

146

237

Audi A3

SPORTBACK 35 TDI DIESEL 4X2 AUTOMATIC

47

38

55

186

146

237

Kia Niro

1.6 GDI PLUG-IN HYBRID 4X2 AUTOMATIC

47

33

64

195

134

270

SEAT Leon

SPORTSTOURER 2.0 TDI DSG DIESEL 4X2 AUTOMATIC

48

43

54

190

170

214

VW Golf

1.5 TSI PETROL 4X2 MANUAL

48

40

52

190

159

206

Ford Puma

TITANIUM PETROL 4X2 MANUAL

49

45

58

198

178

232

Mercedes-Benz A-Class

A180D DIESEL 4X2 AUTOMATIC

49

43

56

192

167

220

Škoda Fabia

1.0 TSI…

1.0 TSI PETROL 4X2 MANUAL

49

41

56

195

162

223

DS 3 Crossback

1.5 BLUEHDI DIESEL 4X2 AUTOMATIC

50

41

58

197

163

229

Renault Captur

E-TECH 160 PLUG-IN INTENS PLUG-IN HYBRID 4X2 AUTOMATIC

50

38

65

211

158

280

Dacia Sandero

SCE 75 ACCESS PETROL 4X2 MANUAL

51

39

57

203

155

229

Lifetime Greenhouse Gas Emissions(Tons C02-eq)

Lifetime Greenhouse Gas Emissions

Lifetime Greenhouse Gas Emissions

Lifetime Primary Energy Demand

(MWh)

Lifetime Primary Energy Demand

Lifetime Primary Energy Demand

Average

Best

Worst

Average

Best

Worst

Land Rover Discovery Sport

D180 2.0 DIESEL 4X4 AUTOMATIC

71

61

76

281

239

301

Mitsubishi Outlander

2.4 PLUG-IN HYBRID 4X4 CVT

70

49

88

295

203

373

Volvo XC60

B4 DIESEL 4X4 AUTOMATIC

69

60

81

270

233

316

Hyundai Tucson

1.6 GDI PETROL 4X2 MANUAL

68

63

76

271

251

303

MAZDA CX-30

SKYACTIV-X 180 PETROL 4X2 MANUAL

60

48

69

240

190

276

Hyundai NEXO

HYDROGEN…

HYDROGEN 4X2 AUTOMATIC

58

39

68

268

176

320

BMW X1

XDRIVE 18D DIESEL 4X4 AUTOMATIC

57

51

68

224

198

265

Honda Civic

1.0 TURBO PETROL 4X2 MANUAL

56

51

62

223

204

249

MINI Cooper

STEPTRONIC PETROL 4X2 AUTOMATIC

56

43

63

226

170

252

Audi A3

SPORTBACK 1.5 TSI PETROL 4X2 AUTOMATIC

55

52

61

218

209

244

BMW 1 Series

118I PETROL 4X2 MANUAL

53

48

59

213

191

235

Citroën C3

1.2 PURETECH PETROL 4X2 MANUAL

53

43

61

213

169

247

Ford Kuga

2.0 ECOBLUE ST-LINE DIESEL 4X2 MANUAL

53

48

61

208

187

241

VW Golf

GTE 180 KW PLUG-IN HYBRID 4X2 AUTOMATIC

52

30

72

220

123

305

Dacia Sandero

SCE 75 ACCESS PETROL 4X2 MANUAL

51

39

57

203

155

229

FIAT Panda

1.2 8V PETROL 4X2 MANUAL

51

41

57

205

163

228

Opel/Vauxhall Corsa

1.2 DI TURBO PETROL 4X2 AUTOMATIC

51

44

59

204

176

237

DS 3 Crossback

1.5 BLUEHDI DIESEL 4X2 AUTOMATIC

50

38

65

211

158

280

Renault Captur

E-TECH 160 PLUG-IN INTENS PLUG-IN HYBRID 4X2 AUTOMATIC

50

38

65

211

158

280

Ford Puma

TITANIUM PETROL 4X2 MANUAL

49

45

58

198

178

232

Electric cars vs petrol cars vs hybrid cars : which engine choice is right for you? Click here to find out more…