This study uses panel data on 25 MICs1 from 1996 to 2022. Relevant data for specific independent variables in other MICs are unavailable from existing sources; therefore, this study employs a convenience sample method for selecting MICs. Previous studies have used various innovation proxies, such as R&D expenditures (Minovic & Jednak, 2021; Nguyen et al., 2020), patents (Ordeñana et al., 2024; Bucci et al., 2021; Burhan et al., 2017; Feki & Mnif, 2016; Hashmi & Alam, 2019; Saleem et al., 2019; Ulku, 2004), trademarks (Acheampong et al., 2022), scientific and technical publications, high-technology exports, and R&D as a percentage of GDP (seeAppendix A, Table A1). These indicators have been utilized individually or in combination as proxies for innovation. Some researchers used the innovation index (Mughal et al., 2022; Yu et al., 2021; Pradhan et al., 2020); however, the data for selected variables from MICs reveal significant multicollinearity among various innovation proxies. While previous research often employed multiple innovation indicators individually, we introduce a novel approach by constructing a composite innovation index using PCA that includes the most commonly used proxies: R&D expenditure (RD), patent records (PAT), and trademark records (TM). Before conducting the PCA, we assess the appropriateness of the data using Bartlett’s test of sphericity and the Kaiser–Meyer–Olkin (KMO) measure. Bartlett’s test exhibits that the variables are appropriately correlated for dimensionality reduction (χ²(3) = 1,389.08, p < 0.001). The KMO measure is 0.74, exceeding the suggested threshold of 0.60 (Kaiser, 1974), with individual KMOs ranging from 0.67 to 0.83. Therefore, the generated innovation index was used as the dependent variable for this study.

Remittances are a significant source of income for many MICs, and they can have a positive impact on poverty reduction, economic growth, and human development (Islam et al., 2024). Remittances can foster innovation by providing financial resources to entrepreneurs and businesses, creating a more educated and skilled workforce, and contributing to the development of a more entrepreneurial environment. The extant literature presents remittances in various dimensions. For instance, Adebayo et al. (2023) found that remittances are associated with reduced CO2 emissions. Chishti (2023) found that remittances have a positive impact on the ecological footprint, while Zhang and Ullah (2023) discovered that remittances contribute to increased green growth. Conversely, Fackler et al. (2020) stated that emigration has a positive impact on innovation in source countries. Finally, Das et al. (2020) found that skilled immigration promotes innovation and reduces wage gaps in the United States (US). Therefore, remittances are a crucial variable that influences innovation and contributes to economic growth.

Our model incorporates multiple control variables to enhance research reliability and mitigate bias by establishing a causal relationship between variables. Control variables include GDP per capita (PCI), financial development (FD), carbon dioxide emissions (CO2), industrial output (IND), and capital stock (KS). These factors are widely recognized as direct determinants of innovation within countries. All data are obtained from public and open data sources, and the data series is transformed into common logarithm values to minimize the effect of outliers. Table 2 presents the data descriptions, along with their sources.

All variables are selected based on established literature and existing references to achieve the research objectives; however, innovation is defined as a function of remittances and a set of control variables. Accordingly, our foundational regression model is structured as follows:

Here, “INNO” means innovation, “FR” represents foreign inward remittances, and “Z” represents a group of control variables. The static baseline regression models below examine the influence of remittances on innovation in MICs. We transform it into a linear Eq. (2) by applying the logarithm to both sides of Eq. (1) and incorporating relevant control variables. The baseline innovation equation is represented in the coefficient notation.

Here, εit denotes the residual term, i means cross-section, and t stands for time. β1 represents demonstrations of the coefficients of the predictors, and α0 represents the intercept. LINNOit is the endogenous variable, while LFRit is the exogenous variable. γ′ is the coefficient for control variables (CV), while Zit is the vector of CV, including LPCIit, LFDit, LCO2it, LINDit, and LKSit.

We assess cross-sectional dependence (CD) using the Pesaran (2004) CD test. Given the limitations of traditional unit root tests, we employ second-generation tests, including the cross-sectionally augmented Im, Pesaran, and Shin (CIPS) test and the cross-sectional augmented Dickey–Fuller (CADF) test. After confirming the existence of long-run equilibrium associations among the variables, we conduct a more in-depth analysis of cointegration using Westerlund’s (2007) panel cointegration tests. These tests allow for heterogeneity in the slope coefficients across individual units and CD among the panel variables.

We employ the panel NARDL model introduced by Shin et al. (2014) to investigate nonlinear associations and asymmetries in both the short and long run. We first verify that the panel data meet the necessary criteria. The panel NARDL model effectively handles mixed orders of integration (I[0] and I[1]), making it suitable for analyzing nonlinear relationships and long-term dynamics. The panel NARDL model addresses cross-sectional dependence, serial correlation, and endogeneity; however, the panel NARDL model can be constructed by incorporating both positive and negative changes in independent variables (LFR). Eq. (3) presents a simplified long-run NARDL equation:

Here, αi means country-specific intercept, and β1+LFR_POSit denotes long-term coefficients of remittances for positive change. β1−LFR_NEGit represents long-term coefficients of remittances for negative change. Eq. 4 allows us to obtain the short-term dynamics of the affiliation.

In this framework, δi denotes country-specific intercept for the short run, and ⋌jpresents short-run coefficients for lags of the predicted variable; φj represents control variables. ωj+and ωj− denote the short-term coefficients associated with lags of positive and negative remittance changes, respectively. The error correction term is denoted by θECTit−1, which measures the rate of convergence to the long-run equilibrium.

We use the Dumitrescu–Hurlin (D–H) (2012) panel causality check to identify the pattern of causation among variables. All coefficients are expected to exhibit cross-sectional variation. Eq. 5 provides a concise overview of the D–H model.

In this equation, βi means constant, δi represents the coefficient slope, and αi denotes the lag parameter. Eq. 6 outlines the null and alternative hypotheses, providing a precise framework for statistical analysis.

Despite the lack of homogeneous Granger causality in all cross-sections, the alternative hypothesis posits that a panel data approach could reveal at least one causal relationship between the variables.

The preliminary analysis employs cross-sectional dependency (CD) tests due to the commonality of data across different countries. Table 3 presents (column 2) the empirical CD findings utilizing the Pesaran CD test (2004), showing that the null hypothesis is rejected at a 1 % significance level in the series. The findings reveal CD in designated variables, driven by interconnected factors such as macroeconomic conditions, globalization, and national economic aspirations.

We then employ second-generation unit root tests (CIPS and CADF) due to the presence of CD, finding that the cross-sections are generally stationary, with varying orders of integration. Table 3 presents the URT results, indicating that the variables are either I(0) or I(1). We also conduct unit root tests (URTs) for I(2) integration, determining that none of the variables exhibit I(2) integration; therefore, the NARDL approach is appropriate for our study.

Table 3 also displays the results of the multicollinearity variance inflation factor (VIF) test (column 7). The average VIF values are 1.96, with all individual values below 2.32; therefore, the VIF test results indicate that there is no multicollinearity issue in the model.

After confirming long-term equilibrium associations among variables through URTs, we conduct a more in-depth analysis of cointegration using Westerlund’s error-correction-based (ECM) panel cointegration tests.

The study utilizes Gt and Ga as group-mean statistics as well as Pt and Pa as panel-mean statistics. This approach allows us to test for cointegration at the individual country level and across the panel as a whole, with the null hypothesis rejected. Table 4 shows Westerlund’s (2007) ECM panel cointegration test results, indicating significant cointegration among the variables and rejecting the null hypothesis of no cointegration across all tests. Gt and Pt utilize conventional standard errors, while Ga and Pa adjust for heteroscedasticity and autocorrelation. The test outcomes reject the null hypothesis of no cointegration at the 1 % significance level based on robust bootstrap p-values; therefore, the panel reveals cointegration, indicating that the selected variables are long-term connected.

The pooled mean group model employs a nonlinear ARDL approach, specified as NARDL (1, 1, 1, 1, 1, 1, 1, 1). The maximum lag for the dependent variable is set to 1 for automatic selection. Dynamic regressors are also automatically selected based on the Akaike information criterion. Table 5 presents the long-term and short-term NARDL outcomes. Revealing that all independent variables, except for negative remittances (LFR_NEG) and industrialization (LNIND), positively affect innovation, with LNIND being statistically significant at the 1 % level in the long term.

The positive and statistically significant coefficient of LNFR_POS indicates that positive remittance shocks are positively associated with innovation, signifying a long-run stimulative effect on innovation. Conversely, the negative and highly significant coefficient of LNFR_NEG indicates that adverse remittance shocks have a detrimental effect on innovation. Moreover, the magnitude exceeds the positive effects, suggesting a strong asymmetry in the long-term impact of remittances on innovation. Therefore, the findings reveal an apparent asymmetry in the effect of remittances on innovation: positive remittance shocks significantly boost innovation, while negative shocks exert a far more significant adverse impact. Consequently, remittances play a dual role in MICs, fostering innovation during positive inflows while posing considerable risk when flows decrease. The outcome is similar to that of Fackler et al. (2020), who found that emigration influences innovation in source nations despite not spreading asymmetries. Correspondingly, Das et al. (2020) proposed a policy-guided hypothesis that skilled immigration encourages innovation and reduces wage gaps in the US. Thus, remittances tend to correlate with higher innovation; countries with higher remittance inflows tend to accelerate innovation activities due to their governments’ greater capacity for investment.

In contrast, LPCI’s 1 % level positive coefficient indicates that higher per capita GDP significantly enhances innovation, underscoring the crucial role of economic development in fostering innovation in the long term. This result aligns with Galindo and Méndez (2014). Subsequently, we found that financial development (LFD) has a significant influence on innovation, demonstrating that improved financial systems can enhance innovation activities in MICs over the long term. Our empirical findings on FD outcomes align with key macroeconomic theories and literature, partially supporting the work of Li (2024) and Hsu et al. (2014).

The significant 1 % level coefficient of LCO2 (CO2 emissions) indicates that higher CO2 emissions are positively associated with innovation, suggesting that environmental challenges drive the development of long-term, sustainable technologies. This outcome is consistent with the results of Mehmood et al. (2024) for Pakistan and Alexiou (2025) for developed countries. The results indicate that CO₂ emissions and innovation are positively correlated; however, this may be due to the transitional phase of industrialization, when energy-intensive production initially follows technological improvements (Bekun et al., 2025). This correlation may also occur at the early stage of the environmental Kuznets curve, where the heavy use of nonrenewable energy may increase innovation but temporarily worsen the environment (Alexiou, 2025). Therefore, MICs should implement policies that promote the adoption of low-carbon technologies, energy-efficient production processes, the integration of renewable energy sources, and green R&D incentives. Such policies can foster innovation and mitigate emissions, thereby supporting environmental sustainability goals. Conversely, Bergougui (2024) discovered that negative technological innovation shocks can increase CO2 emissions, while positive shocks have the opposite effect.

The industrialization (LIND) coefficient is consistently negative and highly significant, indicating that industrialization has a negative long-term impact on innovation. The findings align with those of Bustos et al. (2019), who found that the expansion of low-tech industries diverted workers from high-tech sectors, ultimately hindering growth in manufacturing productivity. In contrast, Zou (2024) and Yang et al. (2024) demonstrated the positive impact of industrialization on innovation. The following frameworks can theoretically contextualize the negative connection between industrialization and innovation. First, the early deindustrialization hypothesis (Rodrik, 2016) suggests that many MICs experience manufacturing decline before achieving satisfactory technological maturity, thereby creating structural gaps in their innovation capabilities. Second, the technology trap phenomenon (Mazzucato, 2013) clarifies how industrialization designs dominated by low-value-added production may force out R&D investment while constraining economies into imitative activities. Third, structural hysteresis effects (Andreoni & Chang, 2019) underscore how historical industrial policies can create path dependencies that hinder the transition to knowledge-intensive production.

Finally, the significant positive coefficient of LKS (capital stock) at the 1 % level emphasizes the crucial role of physical capital investment in driving long-term innovation. Our finding aligns with Fengju et al. (2020), who discovered a reciprocal affiliation between sustainable innovation ability and capital stock with industry-specific variations. Therefore, our findings are indispensable for enhancing innovation activities in MICs, where remittances, CO2 emissions, GDP per capita, FD, and capital stock are steadily increasing.

In contrast, the short-run dynamics are replicated in the coefficients of the differenced variables and the error correction term (COINTEQ01). The significant error correction term of –0.373 (p < 0.0001) specifies a swift adjustment of 37.3 % per period toward long-run equilibrium, indicating that short-run disruptions to innovation are rapidly corrected. The coefficients for positive and negative remittance shocks are insignificant in the short run, suggesting that remittance shocks have no immediate impact on innovation. The long-run counterparts dominate the short-run effects.

The empirical results reveal asymmetric impacts in both magnitude and temporal dimensions. The short-term remittance shocks exhibit limited innovation impacts; however, their long-term effects are substantially more substantial and statistically significant, with the system correcting disequilibria at a rate of –0.37 % quarterly. This framework suggests three essential features for innovation systems in MICs. First, the delayed positive effect indicates innovation earnings require (a) time-consuming human capital growth through remittance-funded education (Yavuz & Bahadir, 2022), (b) gradual technology approval from migration networks (Meyer & Wattiaux, 2006), and (c) institutional growth to support R&D commercialization. Second, the stronger negative long-term coefficient indicates that innovation systems change remittance dependencies. Moreover, rapid drops damage ongoing research projects and hinder the retention of skilled labor, consistent with Djeunankan et al.’s (2023) findings on threshold effects. Third, the adjustment speed confirms notable persistence in the innovation systems of MICs, reinforcing why short-term remittance volatility has muted effects, while sustained flows yield compounding knowledge spillovers (Audretsch & Fiedler, 2024). Therefore, policy implications accordingly emphasize long-term stability over short-term stimulus.

Conversely, the positive and significant short-run coefficient (0.67) for GDP per capita emphasizes its ongoing positive influence on innovation. In contrast, the short-run coefficients for FD, CO2 emissions, industrialization, and capital stock are insignificant. This outcome suggests that their effects on innovation are primarily long-run in nature.

Table 6 displays the residual diagnostic check and long-term asymmetry tests. The residual diagnostic check using the Pesaran CD test presents a CD value of –1.257 and a p-value of 0.208, indicating no discernible cross-sectional dependency. Therefore, the null hypothesis of no CD cannot be rejected, suggesting that residuals are relatively independent across different cross-sections in the panel data. In contrast, the long-term asymmetry test results in Table 6 also show strong evidence against the null hypothesis of symmetric effects (H0: C1 = C2). The statistically significant test statistics (t, F, and χ2) confirm significant differences between the coefficients C1 and C2, indicating a long-term asymmetric affiliation between remittances and innovation in MICs.

To ensure the robustness of the results regarding the effect of remittances (both positive and negative shocks) on innovation in MICs, we employ additional analyses using the dynamic ordinary least squares (DOLS) approach in conjunction with the NARDL method. The DOLS technique yields results consistent with the NARDL outcomes, confirming the reliability of the initial findings in Table 7. The DOLS approach accounts for endogeneity, while serial correlation confirms the robustness of the outcomes, particularly in the long-run dynamics. Therefore, the DOLS method confirms our findings using the NARDL approach, even after controlling for per capita GDP, CO2 emissions, FD, industrialization, and capital stock.

We employ the D–H causality test to determine the causal relationships between remittances and innovation, revealing bidirectional causality in 23 cases and unidirectional causality in 5 cases. Table 8 presents the outcomes of the causal relationships related to the dependent variable (innovation), which comprises five bidirectional and two unidirectional variables. The results reveal that all designated variables, except for positive remittance shocks and FD, exhibit unidirectional causation with innovation (LFR_POS→LINNO and LINNO→LFD), indicating that positive shocks and FD have a favorable impact on innovation. Conversely, negative remittance shocks, GDP per capita, CO2 emissions, industrialization, and capital stock are causally related in both directions with innovation (LFR_NEG ↔ LINNO, LPCI ↔ LINNO, LCO2 ↔ LINNO, LIND ↔ LINNO, and LKS ↔ LINNO); therefore, they have a reciprocal affiliation with innovation.

On the contrary, all other designated variables have a two-way causal affiliation, except for three variables, which denote that they have a positive effect on one another, and four variables negatively affect one another, and vice versa. The remaining three unidirectional variables are LFR_POS→LPCI, LIND→LFD, and LFR_POS→LIND, indicating that positive shocks to remittances lead to increased GDP per capita, industrialization stimulates FD, and positive shocks to remittances have a positive impact on industrialization. The panel NARDL results are confirmed as precise, and their robustness is verified by the 23 feedback and 5 unidirectional causations; therefore, the series demonstrates a causal connection between the chosen predictor and the predicted variables.