Skip to main content

Towards a carbon-neutral economy: The dynamics of factor substitution in Germany

Environmental Science and Pollution Research volume 27pages 26554–26569 (2020)Cite this article

Abstract

This paper investigates the elasticity of substitution between four inputs—capital, labor, energy, and material—with the translog cost approach for a wide range of industries in Germany by incorporating the slow adjustment process in factor substitution. To this end, we take advantage of EU KLEMS database covering a wide range of industries and consider two models. The first is the static model, in which instantaneous and complete substitution adjustments are assumed. The other model, referred to as dynamic, takes into account the slow adjustment process and applies this to the cost share equations which are estimated using Zellner’s seemingly unrelated regression. The empirical results suggest that (i) the dynamic models have greater explanatory power than the static models; (ii) the production process at the national or industry level in Germany is mainly characterized by a complementarity or weak substitutability between energy and other inputs, which limits German government’s ability to reduce energy use through factor substitution; (iii) among four factor prices, energy demand seems to be more sensitive to changes in the price of material, followed by labor. Hence, an increase in energy prices can be efficient to some extent in order to reduce energy use; (iv) there is a substantial industry heterogeneity in Germany in terms of both input substitution and its adjustment process. Therefore, strategies to mitigate CO2 emissions through input substitution channel should be designed at the industry level based on the industry-specific needs and peculiarities. It is because well-designed comprehensive policies that consider different structures of industries could help to achieve a carbon-neutral economy for Germany.

This is a preview of subscription content, access via your institution.

Access options

Buy single article

Instant access to the full article PDF.

43,34 €

Price includes VAT (Finland)
Tax calculation will be finalised during checkout.

Fig. 1
Fig. 2
Fig. 3
Fig. 4

Notes

  1. In 2015, CO2 contributed 73% of global GHG emissions and the largest source of GHG emissions was the fossil fuel combustion (IEA 2018).

  2. Although some of these studies slightly increase the number of industries, they mainly focus on panel data series for the EU or OECD countries including Germany and do not report country- or industry-specific results (Fiorito and van den Bergh 2016; Wurlod and Noailly 2018).

  3. For further information on theoretical derivations of the static and dynamic models, see Urga and Walters (2003); Cho et al. (2004); Coelli et al. (2005); Lin and Li (2014); Li and Lin (2016).

  4. Although we calculate the AES in the “Empirical analysis” section in order to obtain the OPE and CPE, we do not report it in the study.

  5. The standard errors of OPEii and CPEij can be calculated as: \( \mathrm{SE}\left({\mathrm{OPE}}_{ii}\right)=\frac{1}{s_i}\mathrm{SE}\left({\beta}_{ii}\right) \) and \( \mathrm{SE}\left({\mathrm{CPE}}_{ij}\right)=\frac{1}{s_i}\mathrm{SE}\left({\beta}_{ij}\right) \) (Koetse et al. 2008; Wurlod and Noailly 2018).

  6. The reason for choosing March 2008 version is that the following releases or revisions after March 2008 do not include data for energy and materials.

  7. For further information on the methodology and sources of the EU KLEMS database which is also available at http://www.euklems.net/, see Timmer et al. (2007).

  8. The EU KLEMS database has negative values for capital in some industries, such as agriculture. The main reason for this is the method of calculation for capital which equals to value added minus labor compensation (LAB). In other words, labor is largely self-employed in some industries and the wage rate of it is often unobserved. For this reason, it is assumed that the self-employed received the same hourly wages as employees in these industries. This, in turn, leads to negative values for capital. For further information, see Jager 2016.

    Following Wurlod and Noailly (2018), some aggregates and industries are dropped from the estimations due to both data availability and negative values for CAP in order to obtain more robust and theoretically meaningful estimates. The aggregates and industries removed due to missing observations, data transformation process, and Stata codes used in the estimations can be found at electronic supplementary material.

  9. A number of studies have applied the SUR method to estimate cost share equations (Ma et al. 2009; Lin and Li 2014; Li and Lin 2016; Wang et al. 2018; Liu et al. 2018).

  10. To save space, we do not report all regression results here, but they can be found in the Appendix. See Table 10.

  11. Note that although aggregates G, I, JtK, and LtQ have lower values than other aggregates, these coefficients are not statistically significant. For example, the adjustment parameters of energy (λE) for TOT, D, E, and F are 0.312, 0.318, 0.647, and 0.484, respectively, and all these parameters are statistically significant at conventional levels. On the other hand, these parameters for G, I, JtK, and LtQ are 0.159, 0.132, 0.101, and 0.145, respectively. As clearly seen, all these lower values are statistically insignificant.

  12. See Table 11 for all regression results.

  13. Empirical rejection of concavity may indicate a misspecification problem in the underlying cost function. Therefore, concavity of the second partial derivative should be investigated as a robustness check. To this end, following Baum and Linz (2009), this paper obtains Hessian matrix of second partial derivatives. As discussed by Diewert and Wales (1987) and Ryan and Wales (2000), this condition will be satisfied if and only if the matrix is negative semi definite. Therefore, the presence of positive eigenvalues indicates that the assumption of concavity of the cost function is not satisfied by the estimates. The obtained results show that the sign of eigenvalues under the static and dynamic specifications with constraint model is negative. For example, while 14 out of 84 eigenvalues are positive for both unconstraint static and dynamic specifications, none of the eigenvalues is greater than 0.05 for constraint models. The local concavity which is imposed at a reference time point (prices are rebased in the year 1978) also confirms these findings. To save space, these results are not included in the paper. They are available from the author upon request.

  14. The reported cross price elasticities in Berndt and Wood (1975) are about − 0.15 and − 0.18 for US manufacturing industry. The computed CPEs in Fuss (1977) are − 0.004 and − 0.050 for Canadian manufacturing industry. Westoby and McGuire (1984) and that capital and energy are complements with the value of − 0.0038 and − 0.3042 for the UK electricity industry.

  15. Welsch and Ochsen (2005) show that energy is a complement to material for Germany. The computed parameters are as follows: CPEME= − 0.126, CPEEM= − 1.278, MESME= − 0.733, and MESEM= − 0.392.

  16. Note that the comparison of the studies at the industry level is rather difficult. This is because industrial coverage in terms of amount and classification varies across nearly all studies as they use different data sources and cover less industries than in our study. However, unlike the other studies, Kemfert (1998) and Kemfert and Welsch (2000) use the same data source and industry classification. Therefore, even if we do not report in Table 9, we will briefly discuss their industrial findings in the main text.

  17. While Kemfert (1998) and Kemfert and Welsch (2000) estimate the original CES production function using non-linear estimation process, we estimate cost share equations derived from TPF using the linear estimation technique.

  18. While Falk and Koebel (1999) consider 27 manufacturing industries, Welsch and Ochsen (2005) present the results for the entire German economy.

  19. Fiorito and van den Bergh (2016) calculate the price elasticities for manufacturing sector (D) with TPF for seven countries including Germany using the EU KLEMS database over the period 1978–2005 and therefore is the closest article to our study in terms of data source, time period, and estimation methodology

References

  • Agnolucci P (2009) The effect of the German and British environmental taxation reforms: a simple assessment. Energy Policy 37(8):3043–3051

    Google Scholar 

  • Arnberg S, Bjorner TB (2007) Substitution between energy, capital and labour within industrial companies: a micro panel data analysis. Resour Energy Econ 29(2):122–136

    Google Scholar 

  • Arrow KJ, Chenery HB, Minhas BS, Solow RM (1961) Capital-labor substitution and economic efficiency. Rev Econ Stat 43(3):225–250

    Google Scholar 

  • Baum CF, Linz T (2009) Evaluating concavity for production and cost functions. Stata J 9(1):161–165

    Google Scholar 

  • Berndt ER, Wood DO (1975) Technology, prices, and the derived demand for energy. Rev Econ Stat 57(3):259–268

    Google Scholar 

  • Blackorby C, Russell RR (1989) Will the real elasticity of substitution please stand up? (A comparison of the Allen/Uzawa and Morishima elasticities). Am Econ Rev 79(4):882–888

    Google Scholar 

  • BMU (2018) Climate action in figures facts, trends and incentives for German climate policy 2018 edition. Nature Conservation, Building and Nuclear Safety, Berlin

    Google Scholar 

  • BMUB (2016) Climate action plan 2050 principles and goals of the German governments climate policy. Nature Conservation, Building and Nuclear Safety, Berlin

    Google Scholar 

  • Broadstock D, Hunt L, and Sorrell S (2007) UKERC review of evidence for the rebound effect: technical report 3: elasticity of substitution studies

  • Cadavez VAP, Henningsen A (2012) The use of seemingly unrelated regression to predict the carcass composition of lambs. Meat Sci 92:548–553

    CAS  Google Scholar 

  • Cho WG, Nam K, Pagan JA (2004) Economic growth and interfactor/interfuel substitution in Korea. Energy Econ 26(1):31–50

    Google Scholar 

  • Christensen LR, Jorgenson DW, Lau LJ (1973) Transcendental logarithmic production frontiers. Rev Econ Stat 55(1):28–45

    Google Scholar 

  • Coelli TJ, Rao DSP, O’Donnell CJ, Battese GE (2005) An introduction to efficiency and productivity analysis. Springer Science & Business Media

  • Costantini V, Crespi F, Paglialunga E (2018) Capital-energy substitutability in manufacturing sectors: methodological and policy implications. Eurasian Bus Rev 9:1–26

    Google Scholar 

  • Cox M, Peichl A, Pestel N, Siegloch S (2014) Labor demand effects of rising electricity prices: evidence for Germany. Energy Policy 75:266–277

    Google Scholar 

  • Diewert WE, Wales TJ (1987) Flexible functional forms and global curvature conditions. Econometrica 55(1):43–68

    Google Scholar 

  • Duffy J, Papageorgiou C (2000) A cross-country empirical investigation of the aggregate production function specification. J Econ Growth 5(1):87–120

    Google Scholar 

  • Falk M and Koebel BM (1999) Curvature conditions and substitution pattern among capital, materials and heterogeneous labour. ZEW discussion paper, 99–06. ZEW, Mannheim

  • Fiorito G, van den Bergh JC (2016) Capital-energy substitution in manufacturing for seven OECD countries: learning about potential effects of climate policy and peak oil. Energy Effic 9(1):49–65

    Google Scholar 

  • Frondel M (2004) Empirical assessment of energy-price policies: the case for cross-price elasticities. Energy Policy 32(8):989–1000

    Google Scholar 

  • Frondel M (2011) Modelling energy and non-energy substitution: a brief survey of elasticities. Energy Policy 39(8):4601–4604

    Google Scholar 

  • Fuss MA (1977) The demand for energy in Canadian manufacturing: an example of the estimation of production structures with many inputs. J Econ 5(1):89–116

    Google Scholar 

  • Ghisetti C, Quatraro F (2013) Beyond inducement in climate change: does environ-mental performance spur environmental technologies? A regional analysis of cross-sectoral differences. Ecol Econ 96:99–113

    Google Scholar 

  • Henningsen A, Henningsen G (2012) On estimation of the CES production function-revisited. Econ Lett 115(1):67–69

    Google Scholar 

  • Henningsen A, Henningsen G, van der Werf E (2018) Capital-labour-energy substitution in a nested CES framework: a replication and update of Kemfert (1998). Energy Econ 82:16–25

    Google Scholar 

  • IEA (2018) CO2 emissions from fuel combustion statistics. Available at https://webstore.iea.org/co2-emissions-from-fuel-combustion-2018-highlights

  • IEA (2019) CO2 emissions from fuel combustion statistics. Available at https://www.iea.org/reports/co2-emissions-from-fuel-combustion-2019

  • Jager K (2016) EU KLEMS growth and productivity accounts 2016 release statistical module. The Conference Board

  • Kemfert C (1998) Estimated substitution elasticities of a nested CES production function approach for Germany. Energy Econ 20(3):249–264

    Google Scholar 

  • Kemfert C, Welsch H (2000) Energy-capital-labor substitution and the economic effects of CO2 abatement: evidence for Germany. J Policy Model 22(6):641–660

    Google Scholar 

  • Kim K (2019) Elasticity of substitution of renewable energy for nuclear power: evidence from the Korean electricity industry. Nucl Eng Technol 51(6):1689–1695

    Google Scholar 

  • Koesler S, Schymura M (2015) Substitution elasticities in a constant elasticity of substitution framework empirical estimates using nonlinear least squares. Econ Syst Res 27(1):101–121

    Google Scholar 

  • Koetse MJ, De Groot HL, Florax RJ (2008) Capital-energy substitution and shifts in factor demand: a meta-analysis. Energy Econ 30(5):2236–2251

    Google Scholar 

  • Li J, Lin B (2016) Inter-factor/inter-fuel substitution, carbon intensity, and energy-related CO2 reduction: empirical evidence from China. Energy Econ 56:483–494

    Google Scholar 

  • Lin B, Li J (2014) The rebound effect for heavy industry: empirical evidence from China. Energy Policy 74:589–599

    Google Scholar 

  • Liu K, Bai H, Yin S, Lin B (2018) Factor substitution and decomposition of carbon intensity in china’s heavy industry. Energy 145:582–591

    Google Scholar 

  • Liu H, Du K, Li J (2019) An improved approach to estimate direct rebound effect by incorporating energy efficiency: a revisit of China’s industrial energy demand. Energy Econ 80:720–730

    Google Scholar 

  • Ma H, Oxley L, Gibson J (2009) Substitution possibilities and determinants of energy intensity for China. Energy Policy 37(5):1793–1804

    Google Scholar 

  • Masanjala WH, Papageorgiou C (2004) The Solow model with CES technology: nonlinearities and parameter heterogeneity. J Appl Econ 19(2):171–201

    Google Scholar 

  • Mazzanti M, Zoboli R (2009) Environmental efficiency and labour productivity: trade-o or joint dynamics? A theoretical investigation and empirical evidence from Italy using namea. Ecol Econ 68(4):1182–1194

    Google Scholar 

  • Pablo-Romero MdP, Sanchez-Braza A, Exposito A (2019) Industry level production functions and energy use in 12 EU countries. J Clean Prod 212:880–892

    Google Scholar 

  • Ryan DL, Wales TJ (2000) Imposing local concavity in the translog and generalized Leontief cost functions. Econ Lett 67:253–260

    Google Scholar 

  • Sato K (1967) A two-level constant-elasticity-of-substitution production function. Rev Econ Stud 34(2):201–218

    Google Scholar 

  • Serletis A, Timilsina GR, Vasetsky O (2010) Interfuel substitution in the United States. Energy Econ 32(3):737–745

    Google Scholar 

  • Smyth R, Narayan PK, Shi H (2011) Substitution between energy and classical factor inputs in the Chinese steel sector. Appl Energy 88(1):361–367

    Google Scholar 

  • Solomon S, Qin D, Manning M, Chen Z, Marquis M, Averyt KB, Tignor M, Miller HL, Chen Z (2007) Contribution of working group I to the fourth assessment report of the intergovernmental panel on climate change. Cambridge University Press, New York

    Google Scholar 

  • Sorrell S (2014) Energy substitution, technical change and rebound effects. Energies 7(5):2850–2873

    Google Scholar 

  • Taheri AA (1994) Oil shocks and the dynamics of substitution adjustments of industrial fuels in the US. Appl Econ 26(8):751–756

    Google Scholar 

  • Thompson P, Taylor TG (1995) The capital-energy substitutability debate: a new look. Rev Econ Stat 77(3):565–569

    Google Scholar 

  • Timmer MP, Mahony OM, Van Ark B (2007) The EU KLEMS growth and productivity accounts: an overview. University of Groningen & University of, Birmingham

    Google Scholar 

  • Unruh GC (2000) Understanding carbon lock-in. Energy Policy 28(12):817–830

    Google Scholar 

  • Unruh GC (2002) Escaping carbon lock-in. Energy Policy 30(4):317–325

    Google Scholar 

  • Urga G, Walters C (2003) Dynamic translog and linear logit models: a factor demand analysis of interfuel substitution in us industrial energy demand. Energy Econ 25(1):1–21

    Google Scholar 

  • Wang F, Jiang Y, Zhang W, Yang F (2018) Elasticity of factor substitution and driving factors of energy intensity in Chinas industry. Energy Environ 30(3):385–407

    Google Scholar 

  • Welsch H, Ochsen C (2005) The determinants of aggregate energy use in West Germany: factor substitution, technological change, and trade. Energy Econ 27(1):93–111

    Google Scholar 

  • Westoby R, McGuire A (1984) Factor substitution and complementarity in energy: a case study of the UK electricity industry. Appl Econ 16(1):111–118

    Google Scholar 

  • Wurlod JD, Noailly J (2018) The impact of green innovation on energy intensity: an empirical analysis for 14 industrial sectors in OECD countries. Energy Econ 71:47–61

    Google Scholar 

Download references

Acknowledgments

I would like to thank the anonymous reviewers and Eckhardt Bode for their constructive comments and suggestions that helped me to improve the paper. I am solely responsible for any remaining error.

Author information

Affiliations

  1. Department of Economics, Faculty of Economics and Administrative Sciences, Aydın Adnan Menderes University, Nazilli, Aydın, Turkey

    Sedat Alataş

Authors
  1. Sedat Alataş
    View author publications

    You can also search for this author in PubMed Google Scholar

Corresponding author

Correspondence to Sedat Alataş.

Additional information

Publisher’s note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Responsible Editor: Eyup Dogan

Electronic supplementary material

ESM 1

(DOCX 39 kb)

ESM 2

(TXT 3 kb)

ESM 3

(TXT 3 kb)

ESM 4

(XLSX 657 kb)

ESM 5

(TXT 1 kb)

Rights and permissions

Reprints and Permissions

About this article

Verify currency and authenticity via CrossMark

Cite this article

Alataş, S. Towards a carbon-neutral economy: The dynamics of factor substitution in Germany. Environ Sci Pollut Res 27, 26554–26569 (2020). https://doi.org/10.1007/s11356-020-08955-2

Download citation

  • Received:

  • Accepted:

  • Published:

  • Issue Date:

  • DOI: https://doi.org/10.1007/s11356-020-08955-2

Keywords

  • CO2 emissions
  • Input substitution
  • Translog cost function
  • Germany