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Techno Agriculturae Studium of Research
Published by Yayasan Adra Karima Hubbi
ISSN : 30479835     EISSN : 30482321     DOI : 10.70177/agriculturae
Core Subject : Agriculture,
Agriculture, Biological Sciences & Forestry
Techno Agriculturae Studium of Research is an international forum for the publication of peer-reviewed integrative review articles, special thematic issues, reflections or comments on previous research or new research directions, interviews, replications, and intervention articles - all pertaining to the Research in agriculture, includes a wide range of studies and analyzes related to production, resource management, agricultural technology, environmental sustainability, agricultural policy, and more. All publications provide breadth of coverage appropriate to a wide readership in agriculture research depth to inform specialists in that area. We feel that the rapidly growing Techno Agriculturae Studium of Research community is looking for a journal with this profile that we can achieve together. Submitted papers must be written in English for initial review stage by editors and further review process by minimum two international reviewers.
Arjuna Subject : Ilmu Pertanian dan Biologi (Semua) - Ilmu Pertanian dan Biologi (Lain-Lain)
Articles 7 Documents
 1 
Search results for , issue "Vol. 3 No. 1 (2026)" : 7 Documents clear
SOIL AND WATER CONSERVATION TECHNIQUES: EXPLORING SUSTAINABLE PRACTICES FOR ECOSYSTEM RESTORATION AND RESOURCE MANAGEMENT Hakim, Dani Lukman; Lee, Shari; Farado, Kamil
Techno Agriculturae Studium of Research Vol. 3 No. 1 (2026)
Publisher : Yayasan Adra Karima Hubbi

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.70177/agriculturae.v3i1.3314

Abstract

Environmental degradation and resource scarcity necessitate an urgent transition toward integrated landscape management. This research addresses the critical challenges of soil erosion and water depletion by evaluating the effectiveness of integrated Soil and Water Conservation (SWC) techniques. The study aims to identify synergistic practices that optimize ecosystem restoration and ensure long-term resource sustainability. Utilizing a longitudinal experimental design over twenty-four months, researchers compared mechanical interventions, such as bench terracing, with biological strategies, including cover cropping and bio-swales, across forty-five stratified sample plots. Results demonstrate that integrated approaches outperform isolated methods, reducing sediment loss by over 80% and increasing water infiltration rates by 270%. Significant gains in soil organic carbon and macrofauna diversity further indicate a rapid recovery of functional ecosystem services. The findings confirm that the interaction between physical stabilization and biological enrichment creates a self-reinforcing cycle of land regeneration. This research concludes that adopting holistic, nature-based infrastructure is essential for climate resilience and global food security. The developed sustainability framework provides a scalable model for policymakers to transition from extractive land use to regenerative management, ensuring the ecological integrity of vital terrestrial resources.
CLIMATE CHANGE AND AGRICULTURE: EVALUATING THE IMPACT OF SUSTAINABLE WATER MANAGEMENT IN MITIGATING ENVIRONMENTAL RISKS Arfadly, Andi Rachmat; Dimitrov, Ivan; Tuan, Samuel
Techno Agriculturae Studium of Research Vol. 3 No. 1 (2026)
Publisher : Yayasan Adra Karima Hubbi

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.70177/agriculturae.v3i1.3315

Abstract

Climate change poses an existential threat to global food security, primarily through the disruption of hydrological cycles and increased frequency of extreme thermal stress. This research addresses the urgent need for adaptation by evaluating the efficacy of sustainable water management in mitigating agricultural and environmental risks. The study aims to quantify how precision irrigation and moisture-retention techniques stabilize crop yields and soil health under climatic volatility. Utilizing a three-year longitudinal experimental design across sixty agricultural sites, the methodology compared precision drip irrigation and mulching against traditional flood methods. Results indicate that integrated sustainable practices reduced water consumption by 40% while enhancing water use efficiency by over 200%. Crucially, these techniques lowered soil salinity by 60% and maintained vegetation health during peak drought periods, as evidenced by stable NDVI values. Analysis confirms that the synergy between technological precision and organic soil cover creates a robust buffer against environmental degradation. This research concludes that transitioning to sustainable water governance is a fundamental prerequisite for agricultural resilience. The findings provide a scalable framework for policymakers to de-risk food systems, asserting that nature-based hydrological infrastructure is essential for long-term ecological and economic stability in a warming world.
THE FUTURE OF SUSTAINABLE AGRICULTURE INVESTIGATING MULTIDIMENSIONAL APPROACHES TO ENVIRONMENTAL, SOCIAL, AND ECONOMIC SUSTAINABILITY Renawati, Pande Wayan; Singh, Karan; Kanai, Lucy
Techno Agriculturae Studium of Research Vol. 3 No. 1 (2026)
Publisher : Yayasan Adra Karima Hubbi

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.70177/agriculturae.v3i1.3397

Abstract

Sustainable agriculture has become a global imperative in response to climate change, resource depletion, biodiversity loss, and rural socioeconomic inequality. Conventional productivity-driven models have increasingly been criticized for neglecting environmental integrity and social equity. Multidimensional approaches integrating environmental, social, and economic sustainability are therefore gaining prominence; however, empirical evaluation of their combined performance remains limited. This study aims to investigate the effectiveness of integrated sustainability models in agricultural systems and to examine the interactions among environmental restoration, social inclusion, and economic viability. A mixed-methods design was employed involving 150 farms categorized into conventional, agroecological, and regenerative systems across diverse agroecological regions. Quantitative data were collected through composite sustainability indices measuring soil health, biodiversity, labor conditions, income stability, and market diversification, complemented by qualitative stakeholder interviews. Multivariate and structural analyses were conducted to assess relationships and comparative performance. Results indicate that regenerative and agroecological systems significantly outperform conventional models in environmental and social sustainability while maintaining stable economic outcomes. Strong positive correlations among sustainability dimensions suggest synergistic rather than trade-off effects. The findings support systemic, multidimensional frameworks as viable pathways toward resilient and equitable agricultural futures.
PRECISION LIVESTOCK FARMING: INNOVATIONS IN FEED MANAGEMENT AND ANIMAL HEALTH FOR OPTIMIZED PRODUCTION EFFICIENCY Sarah Williams; Jessica Green; Michael Turner
Techno Agriculturae Studium of Research Vol. 3 No. 1 (2026)
Publisher : Yayasan Adra Karima Hubbi

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.70177/agriculturae.v3i1.3611

Abstract

Precision Livestock Farming (PLF) has emerged as a strategic approach to address efficiency, sustainability, and animal welfare challenges in modern livestock systems. Advances in sensor technologies, data analytics, and automated decision-support tools have enabled real-time monitoring of feed intake, animal behavior, and health status, yet empirical evidence on their integrated impacts remains fragmented. This study aims to evaluate how innovations in precision feed management and animal health monitoring contribute to optimized production efficiency in intensive livestock systems. The research employed a quantitative experimental design combined with farm-level monitoring, involving sensor-based feed delivery systems, wearable health sensors, and automated data analytics across selected commercial livestock farms. Performance indicators included feed conversion ratio, growth or productivity rates, health incidence, and resource-use efficiency. The results demonstrate that precision-managed feeding significantly reduced feed waste while improving feed conversion efficiency, whereas continuous health monitoring enabled early disease detection and reduced morbidity rates. Integrated PLF systems produced measurable gains in overall productivity and operational efficiency compared to conventional management practices. The study concludes that the synergistic application of precision feed management and animal health technologies enhances production efficiency while supporting animal welfare and resource sustainability. These findings highlight the potential of PLF as a transformative pathway for resilient and data-driven livestock production systems.
AGROECOLOGY IN ACTION: DESIGNING FARMING SYSTEMS THAT BALANCE ECOLOGICAL INTEGRITY AND AGRICULTURAL PRODUCTIVITY Fatima Ali; Mahamat Saleh; Nadia Assingar
Techno Agriculturae Studium of Research Vol. 3 No. 1 (2026)
Publisher : Yayasan Adra Karima Hubbi

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.70177/agriculturae.v3i1.3612

Abstract

Agroecology has emerged as a transformative approach to address the growing challenges of environmental degradation, climate variability, and declining sustainability in conventional agricultural systems. Intensive farming practices have often prioritized short-term productivity at the expense of ecological integrity, leading to soil degradation, biodiversity loss, and reduced system resilience. This study aims to analyze how agroecological principles can be operationalized in the design of farming systems that simultaneously maintain ecological integrity and enhance agricultural productivity. The research employed a mixed-methods approach combining field-based comparative analysis of agroecological and conventional farming systems, ecological assessments, and secondary data review. Key indicators included crop yield, soil health parameters, biodiversity indices, input-use efficiency, and ecosystem service provision. The results indicate that agroecological farming systems achieved comparable or higher productivity levels than conventional systems while significantly improving soil quality, biodiversity, and resource-use efficiency. Enhanced ecological interactions, such as nutrient cycling and biological pest regulation, contributed to system stability and reduced dependency on external inputs. The study concludes that agroecology provides a viable framework for designing resilient farming systems capable of balancing productivity with ecological sustainability. Adoption of agroecological practices represents a strategic pathway toward sustainable food systems, ecosystem conservation, and long-term agricultural resilience.
BIOTECHNOLOGICAL INNOVATIONS IN CROP IMPROVEMENT: HARNESSING GENETIC ENGINEERING FOR ENHANCED YIELD AND DISEASE RESISTANCE Nino Tsereteli; Tedo Chkonia; Natia Shengelia
Techno Agriculturae Studium of Research Vol. 3 No. 1 (2026)
Publisher : Yayasan Adra Karima Hubbi

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.70177/agriculturae.v3i1.3613

Abstract

Biotechnological innovations have become increasingly important in addressing global challenges related to food security, crop productivity, and plant disease pressure. Conventional breeding approaches, while effective, are often time-consuming and limited in their ability to rapidly introduce complex traits such as multi-gene disease resistance and stress tolerance. Advances in genetic engineering provide new opportunities to enhance crop yield and resilience through precise modification of plant genomes. This study aims to examine the role of genetic engineering technologies in crop improvement, with a particular focus on yield enhancement and disease resistance. The research employed a comprehensive analytical approach combining experimental evidence from transgenic and genome-edited crop trials with a systematic review of recent biotechnological applications. Key performance indicators included yield performance, resistance to major crop diseases, and agronomic stability under varying environmental conditions. The results demonstrate that genetically engineered crops exhibited significant yield improvements and enhanced resistance to targeted pathogens compared to conventionally bred varieties. Reduced disease incidence contributed to lower yield losses and improved production consistency. The study concludes that genetic engineering represents a powerful and effective tool for sustainable crop improvement when integrated with responsible management and regulatory frameworks. Biotechnological innovations hold strong potential to support resilient agricultural systems and long-term global food security.
ENERGY EFFICIENCY, DEMAND-SIDE MANAGEMENT STORAGE TECHNOLOGIES A CRITICAL ANALYSIS OF INTEGRATION PATHWAYS IN AGRICULTURAL SYSTEMS S.R. Rajkumar; Abdel Raheem; Nebahat Ozaydin Cankirli; Merit Ibekeme; Chaira Audia
Techno Agriculturae Studium of Research Vol. 3 No. 1 (2026)
Publisher : Yayasan Adra Karima Hubbi

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.70177/agriculturae.v3i1.3614

Abstract

This paper presents a review of residential demand-side management (DSM) focusing on modeling approaches, optimization techniques, and future perspectives. Deterministic, stochastic, and data-driven models are analyzed to capture residential load behavior. Various optimization methods, including classical and artificial intelligence-based techniques, are discussed for improving energy efficiency and reducing peak demand. The role of smart grid technologies and IoT in enabling DSM is also examined. Key challenges and future research directions are highlighted.

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