Antecedents of IoT adoption in food supply chain quality management: an integrative model

2.1 Quality management Internet of Things

Some research on the QM IoT in the food supply chain has been conducted in the current literature. The authors illustrated its application and benefits in five main areas, including source, make, deliver, return and plan. For sourcing, the optical noninvasive sensors could be used for phenotyping and plant disease detection (Wahabzada et al., 2016). In addition, the electric nose was used in quality control to accept or refuse incoming raw materials, such as coffee, tea, fish and fruit, while some applications could even determine the origin of olive oil and orange (Peres et al., 2007). Furthermore, the electronic cattle ear tags could collect and provide the data, such as an ear tag number, ear tag image, (including barcode and identification number in human-readable format), biometric identifiers (retinal scan), herd details (name and address), date of birth, GPS of premises, scan date and time stamp, device ID (serial number) and operator ID via an online database among the supply chain networks (Shanahan et al., 2009). It could also improve searching efforts on the authentication information of Halal ingredients (Ahmad Tarmizi et al., 2020).

For making, the automation and quality control in the cheese fabrication process could be made via the use of QM IoT. The attached RFID on the individual cheese could determine the humidity, temperature, product handling, mold growing, biological contamination, acid corrosion, ammoniacal gases, ripening status, kind of milk, manufacturer, batch and batch qualification. The data was collected automatically as a numerical value in the RFID, while the manual recording method was removed (Pérez-Aloe et al., 2007). Furthermore, a biosensor was used to monitor the residual peroxide during the on-line disinfection processes in the food and beverage industry (Moody et al., 2001). It could also be used for the detection of mycotoxins, bactericides, allergens and contaminating microbes (Aarnisalo et al., 2007).

For delivering, sensors in a power-safe mode, called Flexible Tag Datalogger (FTD) that are attached to the wine bottles could monitor the quality of the wine during transporting, storing and vending. The FTD wrapped around the bottleneck to effectively sense the environmental changes, such as temperature, humidity and light, during the processes in the wine logistics chain in real-time. Consumers could also easily check those data by filling in the identification number (ID) on the website (Mattoli et al., 2009). In addition, the quality of perishable foods, such as deep-frozen goods, fish and meat and vegetables, could also be captured in real-time (Aung and Chang, 2014; Wilson and Clarke, 1998). Once environmental changes exceeded the standard, such as a higher amount of heat and carbon dioxide emission, QM IoT could identify the problem location, raise the alarm and calculate the remaining shelf life automatically (Jedermann et al., 2009).

For returning, the return in the food supply chain could be determined as recalling the product back to the original locations or scraping areas due to quality concerns. During the crisis, the food products that were sent to the downstream networks could be immediately realized and recalled (Kumar and Budin, 2006). The traceback or traceforward investigation of the contamination and distribution locations could be done immediately through the use of QM IoT (Aung and Chang, 2014). Recalling might efficiently happen for partial products instead of massive calls due to the use of this technology, while consumers and supply chain networks could exchange the data that synchronized via QM IoT in real-time (Kumar and Budin, 2006; Xu, 2011). In addition, the food supply chain could use the dynamic expiration date (DED) on a food package that could control the quality of the products when distributed along the supply chain. The earliest expiry date items could be determined and sent to the nearest distributor, while the longer ones for further routes. Therefore, firms could reduce food waste, recalls and returns (Heising et al., 2017).

For planning, IoT could act as predictive analytic tools that helped make a decision in supply chain planning, such as in re-stocking, distributing and retrieving the estimated time to complete the process (Rey et al., 2021). In addition, (re)planning, booking, cancelling processes through the information of the container and vessel space availability could be completed in real-time with less manual work through the use of cloud-based platform, such as via FIspace platform in the fresh fish distribution in Norway (Verdouw et al., 2016). The planning activity could also be done via QM IoT in agricultural contexts, such as calculating the amount and period to apply the fertilizers, pesticides and water, while it could also automatically perform the site-specific weather forecast, yield projections and probability maps for diseases and disasters through the accumulated data via QM IoT (Wahabzada et al., 2016; Walter et al., 2017). In addition, the individualized feeding ratio of livestock could be planned via the use of remote-sensing signals, sensors or actuators attached to the livestock (Walter et al., 2017).

Using QM IoT could promote efficiency, quality management, performance tracking, decision-making and automatic notification for the users. This was not limited to the single users but rather shared important information with the upstream and downstream partners in the supply chain. The end consumers could also benefit from the usage of QM IoT in the food supply chain.

2.2 Technological–organizational–environmental framework and related theories

The TOE framework has been to examine the adoption of innovation of information system or technology in three context groups, including technological, organizational and environmental contexts (Tornatzky et al., 1990). TOE framework was used to analyze the adoption factors in various industries, such as in semiconductor industry (Hwang et al., 2016), SME's e-business (Chong et al., 2009), logistic service provider (Hsu and Yeh, 2017; Rey et al., 2021), healthcare industry (Karahoca et al., 2018), e-learning platform (Huang et al., 2020) and so on. The application of the TOE framework was relatively limited in food-related industry studies. Some were found in agriculture (Lin et al., 2016; Shi and Yan, 2016); however, there was a scarcity of applying the TOE framework in the food manufacturing supply chain.

Also, there was a controversy over the use of the TOE framework due to its own limit on the generalization and vagueness of the constructed factors (Gangwar et al., 2015; Hwang et al., 2016). Therefore, the authors brought in several theories to support and strengthen the model in each context explained as followed.

Under the technological context, the authors brought in four technological-related theories to strengthen this context, including the diffusion of innovation theory (DOI), technology acceptance model (TAM), unified theory of acceptance and use of technology (UTAUT) and privacy calculus theory (PVC). First, DOI indicated the fundamental approach to investigate the new technology diffusion through certain channels among social members over time, such as the adoption of Nintendo video games and home computers. There were five factors that predict the innovation's rate of adoption, including relative advantage, compatibility, complexity, trialability and observability (Rogers, 1995). Therefore, these five factors were included in the technological context as it helped investigate the new technology diffusion. Second, TAM was also included in the technological context as it proposed important determinants for the potential users to use or not use the new technology. TAM was applied as a predictor of intention in using a diverse set of technologies with two factors, including perceived usefulness and perceived ease of use (Davis, 1989). However, these two factors from TAM were essentially similar to the relative advantage and complexity of DOI, respectively (Fichman, 1992). Therefore, they were combined and presented as relative advantage and complexity in this study. Third, UTAUT was another expanding theory from TAM. It was used to understand the drivers of acceptance of the new technology. It consisted of four direct determinants of intention and usage behaviors, including performance expectancy, effort expectancy, social influence and facilitating condition (Venkatesh et al., 2003). However, those factors from UTAUT showed similarity over the adoption factors from TAM and DOI used in this study. For example, performance expectancy pertained to the relative advantage of DOI and perceived usefulness from TAM, effort expectancy was associated with the complexity of DOI and perceive ease of use from TAM, and facilitating condition was embodied in the compatibility factor from DOI (Venkatesh et al., 2003). Therefore, they were combined and presented as the relative advantage, complexity and compatibility, respectively. Fourth, PVC raised concerns about risk beliefs. It showed two inhibitors of willingness to provide information, including the perceived risk and privacy concerns. PVC was previously used to examine the wiliness to provide information, such as via e-commerce (Dinev and Hart, 2006). As QM IoT was the new technology that captured tremendous private information from each firm in the supply chain, these two factors were presented as the sixth and the seventh factors under the technological context. Therefore, this research selected seven adoption factors from four theories, including DOI, TAM, UTAUT and PVC under the technological context. Based on their similarity, those factors included relative advantage, compatibility, complexity, trialability, observability, perceived risks and privacy concerns.

There were several research that pressed importance or indicated challenges of the technological factors on the attitude toward IoT adoption and IoT adoption intention, such as in Chinese agricultural supply chain (Lin et al., 2016), Malaysian Halal agro-food SMEs (Ahmad Tarmizi et al., 2020) and fish supply chain network (Verdouw et al., 2016), Taiwanese retailer (Hong et al., 2011), India retail supply chain (Kamble et al., 2019b), the cheese supply chain network (Jedermann et al., 2009), in food retail value chain in Sweden (Carlström and Silander Hahström, 2017), business e-learning in Taiwan (Lee et al., 2011), healthcare industry (Karahoca et al., 2018), agriculture in USA (Jayashankar et al., 2018), electronic bill payment (Featherman and Pavlou, 2003) and home service in Korea (Sung and Jo, 2018). The definition, detailed current literature and hypothesis of each factor under the technological context were presented in section 2.3.

Under the organizational context, the theory of dynamic capability (TDC) indicated the way to better use of resources distinctively in a competitive and dynamic environment (Teece and Pisano, 1994; Wang and Ahmed, 2007) were also embedded in the model. The stakeholder theory (STK) was introduced to the model. Executive support was perceived as an important stakeholder that could influence the adoption of this theory (Parmar et al., 2010). Hence, the constructed factors under the organizational context were based on its similarity and appropriateness, including firm size, adaptive capability, absorptive capability, innovative capability and executive support.

Several research concluded that the organizational factors impacted the attitude toward IoT adoption and IoT adoption intention, such as in agriculture (Lin et al., 2016; Shi and Yan, 2016), Irish SMEs (Carcary et al., 2014), Malaysian Halal agro-food SMEs (Ahmad Tarmizi et al., 2020), food supply chain (Jedermann et al., 2009), smart farm development (Walter et al., 2017), Greek Fresh produce supply chain (Manos and Manikas, 2010), Italy transportation and logistics (Rey et al., 2021), Indian food retail (Kamble et al., 2019b) and manufacturing firms (Chan and Chong, 2013). In Section 2.4, the definition, current literature and hypothesis of each factor under the organizational context were explained.

Under the environmental context, the institution theory (IST) which provided the mechanism to explain the external environmental pressures was included in the model (DiMaggio and Powell., 1983). In addition, a factor under UATUT (Venkatesh et al., 2003) was also added to this context. Based on their similarities in definition, this study included five factors from three theories under the environmental context, including competitive pressure, value chain partner pressure, social pressure, presence of the service provider and government regulation.

There were several research revealed the challenges and importance of environmental factors on the attitude toward IoT adoption and IoT adoption intention, such as in the logistics industry (Hsu and Yeh, 2017), agriculture (Lin et al., 2016), electrical and electronic organization (Chong and Ooi, 2008), Malaysian SMEs (Chong et al., 2009), mobile supply chain manufacturers in Malaysia (Chan and Chong, 2013), India food retail (Kamble et al., 2019b) and smart farm (Walter et al., 2017). Their studies explored that those firms could be influenced by the environmental factors in their specific sectors. The definition, current literature and hypothesis of each factor under the environmental context were presented in Section 2.5.

It could be seen that some research focused only on some contexts or some factors. However, this research integrated all factors supported by several theories previously mentioned. Therefore, the overall views on all three contexts were captured. In addition to the TOE context, the collaborative structure was added to the model to expand the importance of the supply chain networks instead of focusing only on one party in the supply chain. The collaborative structure, including information sharing and trust, was introduced to construct the conceptual framework and to determine the relationship between the supply chain members on the QM IoT adoption in this research. The collaborative structure would help extend the focus on how collaboration in the food manufacturing supply chain members does impact the QM IoT adoption.

Some studies indicated challenges and influence of collaborative factors on the attitude toward IoT adoption and IoT adoption intention, such as in agriculture supply chain (Lin et al., 2016) and food distribution (Shi and Yan, 2016), fish supply chain (Verdouw et al., 2016), Malaysian SME (Chong et al., 2009) and Greek fresh produce supply chain (Manos and Manikas, 2010). The definition, current literature and hypothesis of each factor under the collaborative structure were presented in Section 2.6.

Furthermore, the majority of current research focused on either the attitude toward IoT adoption or IoT adoption intention. However, this research crucially expanded the scope to study the impact of the attitude toward IoT adoption on the QM IoT adoption intention. Therefore, it could help cover the current literature gap and increase the understanding of the business practitioners on its role. Also, the conceptual model proposed in this research included both attitude and intention as mediating factor and as final independent variable, respectively. The hypothesis was shown in Section 2.7.

2.3 The technological context

2.4 The organizational context

2.5 The environmental context

2.6 Collaborative structure

2.7 Attitude toward QM IoT adoption

The 19 factors discussed previously could directly influence the attitude toward QM IoT adoption and QM IoT adoption intention. In this section, the authors expanded the role of the attitude as a mediator between those 19 factors and intention. This is crucially important because firms may or may not actually have the adoption intention on the QM IoT even though their attitude toward adoption was high. Therefore, the following hypotheses have been proposed:

The conceptual model was proposed in Figure 1. The details of indicators of each factor were later explained in Table 1.

3.1 Target population

The target population was the 326 food processing manufacturers registered with the Food Processing Industry Club, the Federation of Thai Industry (Food Processing Industry Club, 2021). The Food Processing Industry Club strengthened performance of the members and worked closely with the government to solve and prevent the food-related issues. Therefore, these firms are indicated as good representatives in doing this research on QM IoT. A list of members' emails and phone numbers were provided on the federation website. The emails with a Google Form link were sent to all members, and the phone calls were also made to all members to ensure the reception of emails and as reminders. The researchers clearly stated in the email that a supervisor, assistant manager, manager or higher-level employees in the supply chain, logistics, operations, production, quality, information technology or related functions that work closely with operations was a representative for his or her firm. After four months of the survey, 201 distinct firm respondents answered the questionnaires via the Google Form. These sets of data were enough to analyze the structural equation modeling (SEM) (Barclay et al., 1995; Hair et al., 2011). Four sets of data were screened out due to data incompletion. Hence, 197 sets of data were used for further analysis.

3.2 Questionnaire development

In this research, there were two parts of the questionnaires, including general questions in Part 1 and QM IoT adoption questions in Part 2.

In Part 1, the general questions, including gender, age, education, current field of work, job level, total year of experience after graduated, company age, turnover per year, number of employees, company nationality, foreign shareholder(s) and foreign management. The respondents were asked to fill in their firm's names. However, the names would not be revealed in this research but just to ensure that there would be no duplication of answers from the same firm.

In Part 2, the total of 71 questions on the adoption factors tested with five experts in supply chain, industrial engineer, quality and IT fields were asked. All of them were developed from the literature as shown in Table 1. However, three social pressure questions (SCP02-SCP04) were developed by the authors together with the experts in food supply chain fields, and three of the presence of service providers questions (SPV01-SPV03) were developed by the expert from a well-known IoT firm. Five-point Likert scale was used since it can easily utilize the verbal response descriptors (Dawes, 2008) and reduce the frustration level of the respondents (Babakus and Mangold, 1992). The double translation (Mcgorry, 2000) was used, in which the first translator translated the questionnaires from English to Thai; then, the second translators translated them back from Thai to English; and finally, the authors compared both versions and adjusted the inconsistencies.

3.3 Partial least square structural equation modeling (PLS-SEM) assessment

This research used the SEM. Two main types of SEMs, including covariance-based SEM (CB-SEM) and partial least square SEM (PLS-SEM), have been widely applied to research. CB-SEM is more suitable for the confirmatory of the existing structural theory, while PLS-SEM is suitable for the exploratory or extension of an existing structural theory. Hence, PLS-SEM was more suitable as exploratory theory was the essence of this research. There are two assessment criteria for PLS-SEM, including the reflective measurement model assessment and the structural model assessment as shown in Figure 2.

Each assessment included four steps as explained thereafter. The reflective measurement model assessment included indicator reliability, internal consistency reliability, convergent validity and discriminant validity. The structural model assessment included collinearity assessment, explanatory power (R²), predictive relevance (Q²) and path coefficients' relevance and significance of the structural model relationship, respectively. The criteria and results were explained together with the finding in Section 4.2.

4.1 Respondent profile

The respondents were female (58.4%), male (41.1%) and not specified (0.5%) with the major ages ranged between 35 and 45 (50.3%) and 25–35 (42.6%). The respondents mostly held a bachelor's degree (43.1%) and higher (56.9%). The top five fields of work were supply chain (27.4%), quality (23.9%), production (14.2%), operations (9.1%) and logistics (7.1%) with the top three job levels, including manager (42.1%), supervisor (22.8%) and assistant manager (16.2%). The total year of experience after graduating between 6 and 10 (28.4%), 11–15 (25.95) and 16–20 (21.8%) years were the top three ranges. Majority of the company age was 15 years above (64.5%) with a turnover of 1,001–5,000 (25.9%), 501–1,000 (18.3%), and 101–500 (16.2%) million Thai Baht represented as the top three ranges. The firms mostly had employees ranged between 201 and 1,000 (39.6%); 1,001 and 5,000 (17.8%); and 51 and 200 (15.2%) people. More than half of the respondents' firms had Thai nationality (56.9%), Thai shareholders (59.4%) and no foreign management (58.9%); the rest was spreading throughout several foreign nationalities, shareholders and management.

4.2 Reflective measurement model assessment

First, the indicator reliability was assessed through the indicator loadings with the minimum requirement of 0.70 as it is indicated that the construct explained more than 50% of the indicator’s variance (Hair et al., 2019). After all indicators were measured, 54 indicators' loadings exceeded the minimum requirement, while nine indicators, including RLA02, CPX01, OBS04, OBS05, ADC01, OIN02, OIN04, EXS01 and VCP01, were dropped out as exhibited loadings below 0.70 since it would have adverse effects on the measures' convergent validity and internal consistency reliability (Sarstedt et al., 2014).

Second, the internal consistency reliability was measured through the composite reliability and Cronbach's alpha with the recommended acceptable value between 0.70 and 0.90. However, the minimum value could be 0.60 in the exploratory research, and the maximum value could be 0.95 to avoid indicator redundancy which could compromise the content validity (Hair et al., 2019). Majority of the composite reliabilities for all reflectively measured constructs were between 0.70 and 0.95 as shown in Table 2; however, four composite reliabilities from privacy concerns (PVC), adaptive capability (ADC), government supports (GSP) and information sharing (INF) were exceeded the 0.95, which might indicate redundancy; however, this research retained all of them in the model due to the reasons as followed. For PVC and GSP, the composite reliabilities showed 0.953 and 0.974, respectively. However, if we monitored the Cronbach's slpha for these two constructs, they showed the values at 0.938 and 0.947, respectively. Therefore, both were kept as their Cronbach's alphas were below the maximum requirement at 0.950. Besides, there was only one question in each ADC and INF construct. For ADC, one of two indicators was removed from the indicator reliability assessment. For INF, solely one question was asked to the respondents; thus, reporting number as 1.000 had no redundant issue for ADC and INF. Furthermore, the Cronbach's alpha for all constructs passed the minimum requirement at 0.70, except CCP valued slightly lower than 0.70 at 0.653. This construct was kept as its composite reliability indicated the satisfied value at 0.831. ADC and INF values showed at 1.000 were not an issue as a prior explanation.

Third, the convergent validity was measured through the average variance extracted (AVE) values. The criteria of 0.50 or higher indicated that the construct explained at least 50% of the variance of its items (Hair et al., 2019). All AVE values for this model exceeded 0.5 for the reflective constructs as shown in Table 2; therefore, all constructs indicated convergent validity.

Fourth, the discriminant validity was then assessed. All AVE values of each latent construct in Table 2 were higher than the construct's highest squared correlation with any other latent construct (Fornell–Larcker criterion) (Hair et al., 2011) in Table 3. In addition, all indicator's loadings for each construct were higher than its cross-loading (Hair et al., 2011) as shown in Table 4. Therefore, each construct was empirically distinct from other constructs.

4.3 Structural model assessment

First, the collinearity was assessed by means of the VIF. The VIF values of 3 or less would be ideal to confirm that there was no collinearity issue (Hair et al., 2019). There was no collinearity issue since all VIFs valued less than 3 under both ATT and AIN dependent variable tests as shown in Table 2.

Second, the explanatory power (R²) measures the model's explanatory power value with the range from 0 to 1, where the higher value represents greater explanatory power. The value of 0.75, 0.50 and 0.25 is considerate as substantial, moderate and weak, respectively (Hair et al., 2019). Both endogenous constructs indicated 0.642 for the attitude toward QM IoT adoption and 0.598 for the QM IoT adoption intention. The explanatory power for both constructs was considered as moderate since the values were above 0.5.

Third, the predictive relevance (Q²) was measured by using blindfolding to obtain cross-validated redundancy to measure the PLS path model's predictive accuracy with the criteria of 0, 0.25 and 0.50 as small, medium and large predictive relevance of the PLS-path model, respectively (Hair et al., 2019). Some researchers indicated that 0.35 already showed large predictive relevance (Chin, 2010). The value of 0.409 for the attitude toward QM IoT adoption and 0.423 for the QM IoT adoption intention was calculated in this research. Therefore, the exogenous constructs had large predictive relevance for both endogenous constructs.

Finally, the bootstrapping technique was used to assess the path coefficients' relevance and significance of the structural model relationship. The t value higher than 1.96 (p ≤ 0.05) showed statistical significance (Kock, 2016). The results revealed that 12 out of 39 structural relationships are significant (p ≤ 0.05). It included eight factors that significantly impacted the attitude toward adoption (ATT), three factors that showed a direct impact on the adoption intention (AIN), and attitude toward adoption (ATT) significantly impacted the adoption intention (AIN) as shown in Table 5.

The eight factors that significantly impacted the attitude toward QM IoT adoption (ATT) were summarized as followed. First, compatibility (β: 0.1703; t-stat: 2.730; p-value ≤ 0.01) and trialability (β: 0.1662; t-stat: 2.711; p-value ≤ 0.01) were two significant factors under the technological context. Therefore, H2a and H4a were accepted. Second, adaptive capability (β: 0.0711; t-stat: 2.349; p-value ≤ 0.05), innovative capability (β: 0.2249; t-stat: 3.662; p-value ≤ 0.001) and executive support (β: 0.1270; t-stat: 2.330; p-value ≤ 0.05) were three significant factors under the organizational context. Therefore, H9a, H11a and H12a were accepted. Third, value chain partner pressure (β: 0.1034; t-stat: 2.139; p-value ≤ 0.05) and presence of the service provider (β: 0.1561; t-stat: 3.412; p-value ≤ 0.001) were two significant factors under the environmental context. Therefore, H14a and H16a were accepted. Finally, information sharing (β: 0.2265; t-stat: 3.727; p-value ≤ 0.001) was the sole significant factor in the collaborative context. Therefore, H19a was accepted. The rest of the hypothesis, including H1a, H3a, H5a, H6a, H7a, H8a, H10a, H13a, H15a, H17a and H18a were rejected.

There were three factors that showed a direct impact on the QM IoT adoption intention (AIN). First, there was no technological factor that directly impact the adoption intention. Second, adaptive capability (β: 0.0661; t-stat: 2.166; p-value ≤ 0.05) and innovative capability (β: 0.2287; t-stat: 2.986; p-value ≤ 0.01) showed a direct impact on the adoption intention under the organizational context. Therefore, H9b and H11b were accepted. Third, there was no environmental factor that directly impact the adoption intention. Finally, information sharing (β: 0.0785; t-stat: 2.819; p-value ≤ 0.01) was the sole factor showing a direct impact on the adoption intention under the environmental context. Therefore, H19b was accepted. In addition, the attitude toward adoption (ATT) (β: 0.3765; t-stat: 3.422; p-value ≤ 0.001) significantly impacted the adoption intention (AIN). Therefore, H20 was accepted. The rest of the insignificant factors and rejected hypothesis, including H1b, H2b, H3b, H4b, H5b, H6b, H7b, H8b, H10b, H12b, H13b, H14b, H15b, H16b, H17b and H18b, were shown in Table 5.

5.1 Factors impacted the attitude toward QM IoT adoption

There were two technological factors, including compatibility and trialability that were essential for the attitude toward QM IoT adoption for the food supply chain in Thailand. Similar to previous research in the agricultural supply chain (Lin et al., 2016), cold chain firms (Jedermann et al., 2009) and India retail supply chain (Kamble et al., 2019b), compatibility also indicated as an important factor on the attitude toward QM IoT adoption among food supply chain firms in Thailand. In addition, the role of trialability also aligned with the research in the Swedish food retail chain (Carlström and Silander Hahström, 2017) and in Taiwanese e-learning technology (Lee et al., 2011). However, it was contrasted with the healthcare industry (Karahoca et al., 2018).

There were three organizational factors, including adaptive capability, innovative capability and executive support that significantly impacted the attitude toward QM IoT adoption for the food supply chain in Thailand. The result of adaptive capability was crucially important as the previous studies, such as in cold chain transportation (Jedermann et al., 2009) and smart farm development (Walter et al., 2017). In addition, innovative capability was an essential factor that could influence the attitude toward QM IoT adoption for the food supply chain in Thailand. It was not consistent in its role with previous research, such as in transportation and logistics (Rey et al., 2021) and wireless Internet service via mobile technology (Lu et al., 2005). Furthermore, the role of executive support was as important as previous studies in the Chinese agricultural supply chain (Lin et al., 2016), manufacturing firms (Chan and Chong, 2013) and logistics areas in Taiwan (Hsu and Yeh, 2017).

There were two environmental factors, including the value chain partner pressure and the presence of the service provider that were essential for the attitude toward QM IoT adoption for the food supply chain in Thailand. The value chain partner pressure was an important determinant in previous studies, such as in the Chinese agricultural supply chain (Lin et al., 2016) and supply chain in Malaysian electrical and electronic organizations (Chong and Ooi, 2008). However, there was a controversy on the influenceable impact of trading partners on e-business adoption in Malaysian SMEs (Chong et al., 2009) and the mobile supply chain management systems in manufacturers in Malaysia (Chan and Chong, 2013). Besides, the presence of the service provider was an important determinant on the attitude toward QM IoT adoption. It was consistent with previous technology-related studies, such as in integrated software solutions (Verdouw et al., 2016) and cloud computing adoption in Jordan (Al-Hujran et al., 2018).

Information sharing was the only factor under the collaborative structure that could influence the attitude toward QM IoT adoption for the food supply chain in Thailand. It was consistent with previous studies, such as e-business adoption in Malaysian SME (Chong et al., 2009) and the Greek fresh produce supply chain (Manos and Manikas, 2010).

5.2 Factors impacted the QM IoT adoption intention

Apart from the attitude toward adoption, this research also extended to the QM IoT adoption intention in food supply chain in Thailand. There were two organizational factors and one collaborative factor, including the adaptive capability, innovative capability and information sharing, respectively, that were essential for the QM IoT adoption intention for the food supply chain in Thailand. Adaptive capability was indicated as an important factor that could directly affect the adoption intention for the food supply chain in Thailand as in the previous studies, such as in the agricultural context (Lin et al., 2016). In addition, the innovation capacity was another strong factor that directly impacted the adoption intention. It was not consistent in its role with previous research, such as in transportation and logistics (Rey et al., 2021) and wireless Internet service via mobile technology (Lu et al., 2005). In addition, information sharing was also important and consistent with previous studies, such as e-business adoption in Malaysian SMEs (Chong et al., 2009) and Greek fresh produce supply chain (Manos and Manikas, 2010). The attitude toward QM IoT adoption had a positive influence on QM IoT adoption intention. As a result, it mediated compatibility, trialability, adaptive capability, organizational innovativeness, executive support, value chain partner pressure, presence of the service provider and information sharing on adoption intention significance. It was aligned with the previous study on the essential influence of attitude on intention, such as in the blockchain adoption intention (Kamble et al., 2019a).

5.3 Factor showing no impact on attitude or intention

There were several factors that did not impact the attitude toward QM IoT and QM IoT adoption intention. The five factors under the technological context were firstly discussed. The result for the relative advantage was not consistent with some research, such as in agricultural supply chain (Lin et al., 2016), Malaysian Halal agro-food SMEs (Ahmad Tarmizi et al., 2020) and fish supply chain (Verdouw et al., 2016). However, this research aligned with some research, including the adoption of big data in the fashion industry (Chen et al., 2015) and the adoption of e-commerce in the hotel industry (Mndzebele, 2013). The relative advantage was not a sufficient condition for the firm in the food processing supply chain to adopt QM IoT even though the firms understand that QM IoT could provide benefits. In addition, the result of the complexity contrasted with the previous studies that showed a negative influence on the Chinese agricultural supply chain (Lin et al., 2016), the fish supply chain (Verdouw et al., 2016) and Malaysian Halal agro-food SMEs (Ahmad Tarmizi et al., 2020). The result of the complexity also contrasted with other research on the adoption of SaaS (Mangula et al., 2014; Safari et al., 2015) and cloud computing (Tashkandi and Al-Jabri, 2015) that showed a negative impact on the adoption of innovation. However, the result aligned with the high-tech industry firms that the complexity reported as an insignificant factor in adopting cloud computing (Low et al., 2011). Instead of recreating the entire business process, the firm could enhance the existing business process under several areas by using pre-built IoT software (Oracle, 2021). QM IoT could actually reduce the complexity by better managing assets and devices, ingesting and analyzing data and reducing risks (O'Connor, 2016). IoT could collect data, monitor the processes and product quality, and adjust the interaction between connected things with minimal human intervention (Oracle, 2021). Therefore, it could be seen that QM IoT could make things easier for firms. Furthermore, the result of the observability contradicted other research, such as in food retail value chain (Carlström and Silander Hahström, 2017), in IT enterprises to adopt SaaS (Mangula et al., 2014; Safari et al., 2015), and in the firms to adopt the cloud computing service (Hsu and Lin, 2016). The reason could be that each firm needed to select both hardware and software based on their preferred capabilities under their different conditions. Therefore, only observation might not be enough to adopt QM IoT, instead the appropriate testing needed to be distinctly performed prior to the adoption.

Interestingly, both perceived risk and privacy concerns did not influence the adoption in this research. Some research indicated a negative relationship between perceived risk in the adoption of technology, such as in the IoT adoption in agriculture in USA (Jayashankar et al., 2018), in Internet-based bill payment services (Featherman and Pavlou, 2003) and in-home service IoT in Korea (Sung and Jo, 2018). However, the risk factors and cybersecurity could be already accounted for during the normal design of the system at all stages of development (Asplund and Nadjm-Tehrani, 2016). Therefore, firms in the food supply chain might already have started to hold certain confidence in using the QM IoT. Although there were also privacy concerns challenge to the adoption of IoT in other research, such as in cloud computing adoption (Al-Hujran et al., 2018; Aqeel-ur-Rehman et al., 2016). However, it did not show a significant influence on the QM IoT adoption in this research. As IoT connected a large number of devices together, the security and privacy might be concerned. The security and privacy preferences could actually be evaluated and reported to the service provider on its appropriate security level before connecting any device with the IoT (Aqeel-ur-Rehman et al., 2016). The privacy concerns could be enhanced by several technologies, such as by increasing the transport layer security, enabling encryption and authentication or using a virtual private network (Perera et al., 2020; Weber, 2010). Therefore, the food supply chain might be well acknowledged on these but did not see them as a challenge in QM IoT adoption.

Under the organizational context, there were two factors that showed no significant influence on the QM IoT adoption in this research. First, the result of the firm size was not consistent with some studies, such as in the agricultural product distribution industry (Shi and Yan, 2016), in agricultural supply chain (Lin et al., 2016) and in the Irish SMEs (Carcary et al., 2014), while it was consistent with some studies, such as Malaysian Halal agro-food SMEs (Ahmad Tarmizi et al., 2020). Each firm could specify the scope of QM IoT needs depending on the current operational conditions. Large firms may be interested in more hardware equipment and more sophisticated software, while smaller ones can reduce the scale to match their requirement. Therefore, all sizes of businesses could still access this opportunity. Second, the result of absorptive capability was contrasted with the studies on the Chinese agricultural supply chain (Lin et al., 2016), smart farming (Walter et al., 2017) and the Greek fresh produce supply chain's traceability system (Manos and Manikas, 2010), while it was consistent with some studies, such as in Malaysian Halal agro-food SMEs (Ahmad Tarmizi et al., 2020). Instead of having a strong absorptive capability (having high numbers of employees in QM IoT expertise) to adopt the QM IoT, it is more critical for the firm to work with the vendors that have the capability to deliver an IoT platform, the truly holistic solution and the world-leading communications technology as their partners (O'Connor, 2016; Things on Net, 2022). Therefore, the service provider could enable the business outcomes and be a turnkey way of knowledge to the firms.

There were another three factors under the environmental context that did not show significant influence on the QM IoT adoption. First, the result of competitive pressure was not consistent with some studies, such as in the Taiwanese logistics industry (Hsu and Yeh, 2017), in the agricultural product distribution industry (Shi and Yan, 2016) and in the supply chain in China (Lin et al., 2016). A benchmark retrieved from competitors in the same category as a good practice to improve a firm's competencies. However, the attitude and intention to adopt QM IoT were not determined by the competitors' practice. To illustrate, although the competitors might currently have the newest technology, the firm might not need to actively follow that practice if it does not create any competitive advantage or bring more value to their customers or consumers. Second, the result of social pressure was also not consistent with some studies, such as in the Chinese agricultural supply chain (Lin et al., 2016). The reason might be that the firms in the food supply chain did not have high pressure from the social generally; however, the pressure would mainly come from the end consumers instead. The pressure from the non-profit organization might not intervene in the adoption of QM IoT if the consumers do not highly value it. Third, the result of the government support was not consistent with some studies, such as in Chinese agricultural supply chain (Lin et al., 2016), pilot research on food traceability as appointed by the Taiwanese government (Hong et al., 2011), IoT adoption in the logistics industry in Taiwan (Hsu and Yeh, 2017), in India food retail supply chain (Kamble et al., 2019b) and in smart farm IoT (Walter et al., 2017). Even though the Thai government has promoted the policy and long-term plan for digital economy improvement (Digital Economy Promotion Agency, 2017) and Thailand 4.0 (National Broadcasting and Telecommunications Commission, 2017), it is still not visible and attractive yet to the management in the food industry. Therefore, the government should intensively promote more campaigns to make the adoption of QM IoT more attractive.

The trust was the solely factor under the collaborative structure that found no significant influence on the QM IoT adoption in this research. It was not consistent with some studies, such as in the agriculture supply chain (Lin et al., 2016) and in the food distribution (Shi and Yan, 2016). However, when dealing with corporations locally or globally, trust could be reinforced through contracts. The justifications of contract law implicitly carried the notions of trust or at least supported its existence (Bukspan, 2006). In today's business world, contracts were created between parties in their supply chain to define social and economic engagement. As a result, trust was not an important factor that directly influenced firms or firms' attitude or intention to adopt QM IoT in their food supply chain since the contract itself implicitly carried the notion of trust already.

6.1 Theoretical implications

The IoT has been introduced to various industries and household for quite a few years. Several research quantitatively and qualitatively studied and published its usage and benefits in various areas. This research advances the literature in three ways.

First, no studies have so far empirically tested the adoption of the QM IoT in the food supply chain, in which quality is the most crucial part for the food-related manufacturers and its supply chain partners. Therefore, the authors filled this crucial gap where QM IoT played an important role in the food supply chain.

Second, this study brought in several theories to strengthen the TOE framework which was criticized for its limitation toward the generalization and vagueness in constructing the adoption factors (Gangwar et al., 2015; Hwang et al., 2016). Therefore, the traditional adoption theories, such as DOI, TAM, UTAUT, PVC, TDC, STK and IST were brought in to strengthen the factors under the technological, organizational and environmental constructions. Also, the collaborative structure was brought into the model to expand the focus to the supply chain area. The theoretical implications for each context were explained as follows.

Even though several studies showed that all five factors from DOI showed their influencing power on the innovation adoption. However, only two factors from DOI, including compatibility and trialability, showed a significant impact on the QM IoT adoption, while the remainingthree factors, including relative advantage, complexity and observability did not indicate this. Thereby, two factors from TAM (perceived usefulness and perceived ease of use) and another two factors from UTAUT (performance expectancy and effort expectancy) were also revealed as having no significant impact on the QM IoT adoption as they were similar to the relative advantage and complexity, respectively. Only one factor from UATUT (facilitating condition) showed significant impact on the QM IoT adoption as it was similar to the compatibility. Interestingly, both two factors under PVC, including perceived risk and privacy concerns, did not show influencing power on the QM IoT adoption. Therefore, two technological-related factors, including compatibility and trialability should be first considered for future research in a similar context. In addition, TDC and STK theories strengthened the organizational construct. Two factors from TDC, including the adaptive capability and innovative capability, showed a significant influence on QM IoT adoption, while the absorptive capability did not reveal. The executive support factor from STK also indicated the influencing power on the QM IoT adoption, while firm size from the original TOE factor did not show the influencing result. Thus, the adaptive capability and innovative capability should be firstly prioritized in the organizational context for future research in a similar study field. Furthermore, IST and UTAUT tightened the environmental construct. There were two factors, including the value chain partner pressure from IST and presence of service provider from TOE showed significant results, while the rest of the factors, including the competitive pressure, social pressure and government support from IST and UTAUT did not show significant impact on the QM IoT adoption. Therefore, these two significant environmental factors, including value chain partner pressure and presence of service provider should be emphasized in a similar context for future research. Likewise, the collaborative structure reinforced the TOE framework on the supply chain collaboration perspectives where they were lacking from the original TOE framework. The information sharing indicated influencing power on the QM IoT adoption, while the other factor (trust) did not reveal. Therefore, trust should be emphasized in the collaborative context for future research.

Third, current studies on the adoption of new technology purely focused on either attitude or intention. Only a few studies brought in both attitude and intention and considered their relationship. This study considered this important point as it brought more benefits to the practitioner and fulfilled this gap in the adoption of QM IoT in the food supply chain. The statistically validated model indicated tentatively high explanatory power (R² = 0.642 for ATT and 0.598 for AIN) and large predictive relevance (Q² = 0.409 for ATT and 0.423 for AIN).

6.2 Managerial implication

The results of this research have significant implications for the food supply chain practitioners, employees and executives to emphasize the factors that are important for their firms and their supply chain to adopt the QM IoT in the future. In addition, the QM IoT service providers can also increasingly understand the crucial requirement of the firms in the food supply chain. The implications were suggested in four contexts, including technological, organizational, environmental and collaborative contexts.

Under the technological context, food supply chain firms should pay high attention to compatibility and trialability. For compatibility, the firms might not be able to amend the current IT infrastructure since they already existed in the firms. However, the firms could actively participate in setting technology standards that allow for expanded modularity and interoperability among and within applications and devices (Wee et al., 2015). In addition, the firms could seek a vendor who can retrofit the existing supply chain infrastructure and systems and who could provide trialability on the prototype systems that can be easily plugged in and out as needed in case it does not fit with the requirement. Hence, the trialability would then be importantly to consider together with the compatibility.

Under the organizational context, innovativeness and executive support were also important for the firms. Creativity and innovation among employees could be promoted through the organizational characteristics, such as communication, control mechanisms and organizational and management support (Antoncic, 2007). In addition, the firms should also empower their employees to develop a good relationship between employees and the organization which can potentially help create higher innovation, such as developing newer, faster and better processes and methods in the supply chain. To enable this innovativeness, the executive should support the employees to look for better methods and options, such as setting stretch goals and should not discourage their creativity. In addition, they should encourage employees to participate in an innovative community where employees in diverse fields can share their ideas and promote the willingness to change. Besides, executives could consider different organizational structures where IT function is no longer only back-end supports but rather synergizes with the operations team as technology is not embedded in everything businesses do. These strategies or directions could be supported by the executive team since they are the ones who set it up.

In addition, the firms in the food supply chain needed to consider both capital and operational expenses to strengthen their adaptive capability. It is difficult to precisely predict the IT project cost; however, the estimated budgets need to be assessed prior to the implementation of a project, not in the current year but for the long-term view. Once the budget for the software, hardware and maintenance is actively considered and flexible enough for allocation, the adoption rate could possibly be accelerated.

Under the environmental context, value chain partner pressure and the presence of service provider were crucially important for the firms. For value chain partner pressure, the firms should seek a long-term contract with a limited number of partners and integrate them as part of the firm's operations, especially those from downstream since they can exercise higher pressure than the upstream ones. Therefore, the long-term relationship could potentially enhance the firm's readiness for large investment, such as IT and information sharing. For the presence of service provider, the firms should prepare to seek for service providers who can provide preferred solutions and provide compatibility with the current infrastructure. In addition, those providers should be able to evaluate and implement technology with customer's requirement together with the standard ones, such as security and privacy. Hence, the firms will have a higher potential to adopt QM IoT faster when they have better preparation with the value chain partners and the service providers.

Under the collaborative context, information sharing is important for the firms in the food supply chain to adopt the QM IoT. Similar to value chain partner pressure, the firms in the food supply chain should build a long-term relationship with the partners because it helps enhance the level of information sharing among their supply chain partners. Thus, a good collaboration in sharing the information could fasten the QM IoT adoption for food supply chain firms.