2. Literature Review

The concept of cumulative tariffs along a GVC is not new but calculating cumulative tariffs and analyzing their impact on the GVC are quite new research avenues thanks to the newly released inter-country input–output tables – see the World Input–Output Database (WIOD) (Timmer et al., Reference Timmer, Dietzenbacher, Los, Stehrer and De Vries2015), the Organization for Economic Co-operation and Development (OECD, 2021), and the Eora26 (Lenzen et al., Reference Lenzen, Kanemoto, Moran and Geschke2012, Reference Lenzen, Moran, Kanemoto and Geschke2013). In the earliest studies, Yi (Reference Yi2003, Reference Yi2010) offers a theoretical model investigating a magnified effect of tariff reductions on trade using a multistage production function, that is multiple cross bordering. Ferrantino (Reference Ferrantino2012) illustrates that total trade cost rises exponentially when the number of production stages increases. Baldwin and Venables (Reference Baldwin and Venables2013) characterize production chains as snake and spider types. In their theoretical framework, shipping and any other coordination costs are also included as trade costs through global production chains.

Apart from these conceptual foundations on theoretical models, there are other studies calculating the cumulative cost of trade (Koopman et al., Reference Koopman, Powers, Wang and Wei2010; Fally, Reference Fally2011; Rouzet and Miroudot, Reference Rouzet and Miroudot2013; Muradov, Reference Muradov2017). Koopman et al. (Reference Koopman, Powers, Wang and Wei2010) consider gross trade statistics and multistage production as two reasons for the amplification of trade costs. Their findings regarding both transportation and tariff costs reveal that Asian countries have the highest magnification ratios because of their involvement in longer production chains. It is important to note that following their idea, we track the sector's value-added in the GVC and calculate both tariffs and cumulative tariffs by using value-added trade statistics. Fally (Reference Fally2011) employs transportation costs and defines cumulative tariff rates, but does not give any detailed discussion of the concept. Rouzet and Miroudot (Reference Rouzet and Miroudot2013) elaborate on the concept in a bilateral framework by providing a detailed calculation methodology. Their simulation results suggest that if tariffs on a Chinese product decrease by 30%, cumulative imposed tariffs of the European Union (EU) and Japan on the Chinese product are reduced by 5%. Muradov (Reference Muradov2017) proposes two measures, cumulative tariff rates and the number of border crossings, by employing data from 2001, 2005, and 2010. He finds out that while the average number of border crossings increases, the faced cumulative tariff also increases. Some other studies have employed the methodology addressed in these theoretical models and calculated the cumulative tariff burden. Escaith (Reference Escaith, Dollar, Reis and Wang2017) measures trade costs from the GVC perspective and finds that trade disruptions raise the average production cost by 18%. Recently, Ghodsi and Stehrer (Reference Ghodsi and Stehrer2022) take GVC linkages into account and calculate bilateral ad-valorem equivalents of non-tariff measures. Their results suggest that tariffs have a strong negative impact on both value-added and gross exports. While the impact of technical trade barriers has a significant negative impact on exports, the impact of sanitary and phytosanitary measures is insignificantly positive. Eugster et al. (Reference Eugster, Jaumotte, MacDonald and Piazza2022) calculate cumulative tariffs and report the negative impacts of both tariffs and cumulative tariffs on value-added, employment, and productivity. Our study differs from their study in terms of the calculation of tariff rates, dependent variables, and the size/coverage of the datasets. Even if they employ product-level tariff rates as well as the methodology of Rouzet and Miroudot (Reference Rouzet and Miroudot2013), they reach sector-level tariff rates by using gross trade volumes rather than value-added trade statistics. Also, they are interested in value-added, employment, and productivity rather than GVC participation. Finally, while they employ a country- or sector-level dataset from the Capital, Labor, Energy, Materials, and Service (KLEMS) database, we utilize the country–sector–partner country-level dataset from the Eora26 database, which enables us to gain wider coverage in our analysis. Others (Mao and Görg, Reference Mao and Görg2020; Wu et al., Reference Wu, Wood, Oh and Jang2021) focus on the trade war between the US and China and present some descriptive results. Our study significantly contributes to the scarce empirical literature related to cumulative tariffs.

Regarding the determinants of GVC participation, the literature is quite rich and consists of many studies at the firm level (Lanz and Miroudot, Reference Lanz and Miroudot2011; Cieślik et al., Reference Cieślik, Michałek and Szczygielski2019; Urata and Baek, Reference Urata and Baek2020). At the sector and country level, tariff rates, capital intensity, FDI, and skilled labor are the most frequently utilized determinants or drivers of GVC participation. On the tariff rates, Kowalski et al. (Reference Kowalski, Lopez Gonzalez, Ragoussis and Ugarte2015) indicate that both faced and imposed tariffs have a negative impact on participation. Similarly, Nordas (Reference Nordas2008) emphasizes the importance of open trade policies in the participation of electronics and textile sectors in GVCs. Cheng et al. (Reference Cheng, Rehman, Seneviratne and Zhang2015) show that trade restrictiveness and tariffs imposed on intermediates are negatively associated with the GVC participation of both low- and high-tech manufacturing sectors. Fernandes et al. (Reference Fernandes, Kee and Winkler2020) claim that lower tariffs are important drivers of GVC participation. The idea is that tariffs do not only generate direct and indirect costs but also impede the potential gains from GVCs, which eventually leads to lower GVC participation ratios. Indeed, these types of losses are not only restricted to partner countries, but their wide-reaching impacts also affect all countries in the entire global production network. Regarding capital intensity, some studies (van der Marel, Reference van der Marel2015) reveal that capital endowment has a positive effect on forward linkages whereas others (e.g. Landesmann et al., Reference Landesmann, Leitner and Stehrer2015) find no significant evidence. The studies employing foreign direct investment inflows in their analyses (Kowalski et al., Reference Kowalski, Lopez Gonzalez, Ragoussis and Ugarte2015; Stehrer and Stöllinger, Reference Stehrer and Stöllinger2015; Buelens and Tirpák, Reference Buelens and Tirpák2017; Banerjee and Zeman, Reference Banerjee and Zeman2020) suggest that there is a significantly positive association between FDI inflow and GVC participation. FDI can develop capital and then boost the participation of domestic sectors in global production networks. In fact, FDI can be seen as a major instrument for multinational enterprises to be involved in GVCs (Amador and Cabral, Reference Amador and Cabral2016). Adarov and Stehrer (Reference Adarov and Stehrer2021) also claim a strong impact of FDI and capital accumulation on GVC participation. Related to skilled labor, some studies (e.g. Cheng et al., Reference Cheng, Rehman, Seneviratne and Zhang2015; Taglioni and Winkler, Reference Taglioni and Winkler2016; Farole et al., Reference Farole, Hollweg and Winkler2018; Ignatenko et al., Reference Ignatenko, Raei and Mircheva2019) find that the ability of skilled labor to conduct complex operations can lead to a positive relationship between skilled labor and GVC participation.

3. Data

Our study is mainly based on four different databases. The first one is the Eora26 database (Lenzen et al., Reference Lenzen, Kanemoto, Moran and Geschke2012, Reference Lenzen, Moran, Kanemoto and Geschke2013). We use inter-country input–output tables covering 186 countries and 26 sectors for the period 1990–2015. Since the tariff rate is mainly relevant in the nine manufacturing, mining, agricultural, and fishing sectors, we continue with these sectors. The manufacturing sectors are food and beverages; textiles and wearing apparel; wood and paper; petroleum, chemical, and non-metallic mineral products; metal products; electrical and machinery; transport equipment; other manufacturing; and recycling. We calculate both forward and backward GVC participation (simple and complex) indices as well as both forward and backward lengths from the database by employing the value-added decomposition methodology of Wang et al. (Reference Wang, Wei, Yu and Zhu2017). Forward GVC participation consists of domestic value-added in exported products. If these exported products cross the border only once and are consumed in the partner country, they are classified as simple forward GVC participation. If the exported products cross the border more than once and are consumed in another (third) country other than the trade partner, they are classified as a complex forward GVC participation. Backward GVC participation consists of foreign value-added in imported products. If these imported products cross the border only once and are consumed in the importer country, they are classified as simple backward GVC participation. If the imported products cross the border more than once and are consumed in another (third) country other than the trade partner, they are classified as a complex backward GVC participation.

Production lengths include the number of times these intermediates are utilized in the production process before they are consumed as final products. In other words, a length counts the number of production stages in a value chain both from the user and producer sides. It also shows the fragmentation and complexity level of trade. Following Wang et al. (Reference Wang, Wei, Yu and Zhu2017) and UIBE (2017, 2017a, 2017b), we take the ratio of forward length to backward length, called the position index, to reach a more consistent estimate regarding a relative production length. We also use data on gross fixed capital formation and labor compensation of sectors provided by the I-O tables of Eora26. We divide gross fixed capital formation by labor compensation to reach the capital intensity of sectors.

The second database is the WITS database (WITS, 2022). We obtain bilateral effectively applied tariff rates at the product level (HS6 digit codes) from this database. We can gauge whether a specific product of a specific sector is intermediate (INT) or not by utilizing the concordance table (OECD, 2017) provided by the OECD which links the product codes (HS-6) to their broad economic categories and sectors (International Standard Industrial Classification (ISIC) Rev. 3). We calculate tariff revenues by simply multiplying imposed tariff rates with imported values. We sum these country–product–partner country-level data across sectors to obtain the country–sector–partner country-level dataset. We then divide tariff revenues into import in value-added statistics rather than gross import volumes coming from I-O calculations. Since the dataset is bilateral, we just rearrange our dataset to include both imposed and faced input tariff rates in the dataset. The imposed tariff is the tariff rate that a country imposes when it imports from a partner country. Similarly, the faced tariff rate is the tariff rate that a country sector faces when it exports to a partner country. Furthermore, following the calculation steps indicated in Rouzet and Miroudot (Reference Rouzet and Miroudot2013), we also calculate the cumulative tariff rates of each measure by taking the number of cross borderings in GVCs into account.

The third database is the FDI database on flows and stock of the United Nations Conference on Trade and Development (UNCTAD) (UNCTAD, 2022). We employ FDI stock as shares of gross domestic product (GDP). As the last database, we utilize the Our World in Data (2022) which combines three published datasets: Lee and Lee (Reference Lee and Lee2016), Barro and Lee (Reference Barro and Lee2013), and the Human Development Report (UNDP, 2018) of the United Nations Development Program. We utilize the average years of schooling of the population of countries. After merging the variables coming from these four different databases, we end up with 12 sectors and 168 countries as an operational sample. Since Eora26 country and sectoral coverage are relatively wide, we aim to separate analyses for subgroups. To achieve this, we benefit from the historical income classification provided by the World Bank and the research and development (R&D) intensity (technology) classification of the OECD (Galindo-Rueda and Verger, Reference Galindo-Rueda and Verger2016). We categorize sectors mainly into two groups as high and low technology. High-tech sectors are metal products; electrical and machinery; transport equipment; other manufacturing. The low-tech sectors are agriculture; fishing; mining and quarrying; food and beverages; textiles and clothing; wood and paper; petroleum, chemicals, and non-metallic mineral products; and recycling.

Table 1 presents the descriptive statistics of the variables we employ in the empirical analysis. We observe higher mean values, which are mainly driven by the manufacturing sectors, of backward GVC participation compared to those for forward GVC participation for both country groups. In addition, both imposed and faced tariff rates are approximately 6% of the full sample. Note that in contrast to developed countries, developing countries have relatively higher imposed tariffs. Both faced and imposed cumulative tariffs are one percentage point higher than the simple tariffs. There is no noticeable difference in a position index, which is the relative forward length, for developed and developing economies. We observe the higher capital intensity and FDI stock share in developing countries, whereas the mean years of schooling for developed countries are much higher than that of developing countries. It is important to reiterate that capital intensity is calculated by dividing gross fixed capital formation by labor compensation, which can be a reason for the lower level of capital intensity of developed countries with the higher level of labor compensation in these countries compared to that of developing countries.

Table 1. Summary statistics

Notes: Income classification is based on the country's 1990 income level, which is the initial year of our dataset (World Development Indicators (WDI)-World Bank, 2020). ‘SD’ stands for standard deviation. ‘GVC’ is the summation of forward and backward GVC linkages. ‘VA’ indicates sectoral value-added, and all trade measures are expressed as their shares in sectoral value added. ‘i’ and ‘icu’ mean simple input and cumulative input tariffs, respectively. iTariff_faced is faced simple input tariff and iTariff_imposed is imposed simple input tariff. icuTariff_faced is faced cumulative input tariff and icuTariff_imposed is imposed cumulative input tariff. GFCF_LC is calculated by dividing gross fixed capital formation by labor compensation.

Figure 1 depicts faced simple and cumulative tariff rates as well as shares of simple and complex parts in the GVC indices from 1990 to 2015. The first notable aspect is that simple and cumulative tariff rates are highly correlated to each other and follow a similar path. The cumulative tariff rate is 1% higher than the simple tariff rate. The second aspect is the decreasing share of the simple part of GVC participation and the increasing share of the complex part of GVC except for the 2008 Global Financial Crisis. Since the complex part of the GVC presents the trade volumes that cross the border more than once, this points out the importance of the cumulative tariff along with supply chains and reveals the threat of the amplified effect of input tariff.

Figure 1. Tariffs rates and GVC participation

Figure 2 presents the position index of sectors (weighted averages of countries by trade) over six points in time (1990, 1995, 2000, 2005, 2010, and 2015). To reiterate, the position index is defined as the ratio of forward linkages over backward linkages, that is the division of the distance of a particular production stage, that is the distance from starting stage to the ending stage. Since we employ the forward production length by deciding the optimal level of cross bordering, we aim to analyze the trends in a position index, that is relative forward length in Figure 2. Recycling; petroleum, chemical, and non-metallic mineral products; mining; and metal products sectors are in the relatively upstream part of a production chain.

Figure 2. Production lengths of sectors

Notes: Other: Other manufacturing. Mining: mining and quarrying. Food: food & beverages; Textiles: textiles and wearing apparel. Wood: wood and paper. Petroleum: petroleum, chemical, and non-metallic mineral products. Metal: metal products. Electrical: electrical and machinery. Transport: transport equipment. Dotted, diagonal stripes downward, solid, diagonal stripes upward, horizontal stripes, and confetti fills in columns show the year 1990, 1995, 2000, 2005, 2010, and 2015, respectively.

4. Estimation Methodology

Following the models discussed in Cheng et al. (Reference Cheng, Rehman, Seneviratne and Zhang2015) and Fernandes et al. (Reference Fernandes, Kee and Winkler2020), we specify the following empirical model to investigate the association between tariff rates and GVC participation.

(1)$$\eqalign{GVC\_Participation_{c, s, p, \;\;t} & = \beta _0 + \beta _1Tariff\_faced_{c, s, p, t} + \beta _2Tariff\_imposed_{c, s, p, t} \cr & \quad + \beta _3P_{c, s, p, t} + \beta _4P_{c, s, p, t}^2 + \beta _5S_{c, s, t} + \beta _6C_{c, t} + \beta _7T_t + \varepsilon _{c, s, p, t}} $$

c, s, p, and t stand for the country, sector, partner country, and year, respectively. $GVC\_Participation_{c, s, p, t}$ signifies the vector of the total, forward, and backward GVC participation (simple and complex parts as well). $Tariff\_faced_{c, s, p, t}$ stands for faced tariff and $Tariff\_imposed_{c, s, p, t}$ stands for imposed tariff. These tariffs are calculated by utilizing both value-added trade statistics and a cumulative tariff procedure. In the analysis, we employ total GVC participation as the left-hand side variable, we then examine the impacts of both faced and imposed tariff rates on participation. Similarly, we consider the impact of faced (imposed) tariffs on the (backward) forward GVC participation. We expect that while a faced tariff (which can be considered as a market access tariff) inevitably leads to a rise in the price of products in which import duties are levied, the competitiveness of sectors in an international market may deteriorate, and an imposed tariff is more likely to raise the production cost of sectors considering the higher dependence of sectors on intermediates in the sample (see the descriptive statistics in Table 1). We also assess the total effect of these tariffs along with the GVC by employing cumulative tariff rates.

P _c,s,p,t denotes the relative production length, which is the position index of related trade flows. We also include the square term of the position index to catch the U-shape relationship between GVC participation and production stages (if any). Shih (Reference Shih1996) and Mudambi (Reference Mudambi2008) develop the concept of the smile curve and claim that the sectors located at the first and end stages of the production chains create a higher value-added relative to sectors located in the middle stages (fabrication stages). Therefore, we expect a negative coefficient on the position index and a positive coefficient on the square term of the position index. S _c,s,t denotes the capital intensity of sectors. C _c,t denotes the vector of country-level characteristics, such as the share of foreign direct investment stock in GDP, of a country, and the mean years of schooling. T _t stands for year dummies. Given the positive impact that the literature finds (Kowalski et al., Reference Kowalski, Lopez Gonzalez, Ragoussis and Ugarte2015; Stehrer and Stöllinger, Reference Stehrer and Stöllinger2015; Buelens and Tirpák, Reference Buelens and Tirpák2017; Banerjee and Zeman, Reference Banerjee and Zeman2020), we expect that FDI stock and schooling also to appear as significant drivers for GVC participation in sectors. Attracting foreign direct investment enables industries to meet new technology, production processes, and better managerial practices (Martínez-Galán and Fontoura, Reference Martínez-Galán and Fontoura2019). Better-educated workers are well-equipped to succeed in complex and the knowledge-intensive activities required to participate in the GVC (De Vries et al., Reference De Vries, Chen, Hasan and Li2016).Footnote ¹

The empirical models are estimated by employing the Fixed Effects (FE) estimation procedure to capture the impacts of possible unobservable time-invariants that vary over country–sector–partner country units and to get rid of the omitted variable bias.Footnote ²