This report analyzes the technology evolution and ecosystem dynamics driving the development of Fault-tolerant Quantum Computing (FTQC) systems. As industries demand higher computational reliability and scalability beyond noisy intermediate-scale quantum devices, FTQC emerges as a key enabler of practical quantum advantage. The study covers the full FTQC landscape, including error suppression, mitigation, and correction techniques, hardware-software co-design, and technology readiness milestones across innovation pathways. It offers comparative insights into advanced sub-techniques, such as tunable couplers, gate optimization, and stabilizer codes, and maps emerging approaches across modalities and architectures. The report also evaluates FTQC’s application potential across pharmaceuticals, finance, logistics, aerospace, and telecom sectors, while assessing funding trends, regulatory frameworks, IP activities, and system case studies from leading providers such as IBM, Rigetti, and Alice & Bob. With a forward-looking perspective on value chain evolution and commercialization roadmaps, this research serves as a strategic guide for stakeholders across quantum hardware, software, government R&D, and enterprise adoption segments to inform investment, partnership, and innovation decisions.

As global demand for electric vehicles and stationary energy storage surges, the limitations of conventional lithium-ion batteries, such as supply chain challenges, energy density caps, and safety risks, are becoming increasingly apparent. These barriers prompt a paradigm shift in battery R&D, spurring global momentum toward next-generation battery chemistries that promise to be safer, more efficient, and more sustainable. This report examines the evolving battery innovation landscape, with a specific focus on emerging chemistries including Solid-state Batteries (SSBs), Sodium-ion Batteries (SIBs), Lithium-Sulfur Batteries (LSBs), Metal-air Batteries (MABs), and Lithium Manganese Iron Phosphate (LMFP) batteries. Each of these chemistries has unique attributes that address traditional lithium-ion systems’ core limitations. The report highlights how these innovations are shaping the future of battery R&D, emphasizing their role in enabling long-duration storage, decarbonizing transport and industry, and supporting renewable energy integration. It explores the driving forces behind their development. It also maps the technology landscape by cost, performance, and scalability, and profiles the leading innovators and stakeholders advancing commercialization. By offering a forward-looking view into emerging battery adoption, R&D trends, application fit, and investment activity, the report equips decision-makers with key insights to navigate the complex transition toward next-generation energy storage solutions. Scope Geography: all Industry: energy, environment, energy storage Contents In this report, we examine batteries, with a major focus on emerging battery chemistries, including SSBs, SIBs, LSBs, MABs, and LMFP batteries.

This report examines technology advances enabling solid waste valorization, where waste streams, such as plastics, biomass, and municipal residues, are converted into valuable outputs (fuels, monomers, and specialty chemicals). As regulatory pressure increases and sustainability becomes core to industrial strategy, solid waste-to-chemical technologies offer a path to decarbonize material production, recover resources, and reduce landfill use. The report evaluates four key technology categories – chemical, biochemical, thermochemical, and physiochemical – covering solvent purification, depolymerization, fermentation, gasification, pyrolysis, and hydrothermal liquefaction methods. It assesses their readiness, operating parameters, industry-specific applications, and impact potential. Through deep diving into case studies, patent trends, and innovation hotspots, the report offers guidance on commercialization pathways, investment patterns, and ecosystem shifts. Stakeholders across chemicals, energy, automotive, and waste management can use this analysis to implement scalable circular strategies and reduce reliance on fossil-based inputs. Scope Geography: global Industry: chemical, packaging, energy, agriculture, automotive, and construction Application: solid waste-to-chemical processes, including fuel generation, monomer recovery, fertilizer production, and high-purity material recycling Contents In this report, we examine: Key solid waste valorization pathways: chemical, biochemical, thermochemical, and physiochemical Technology maturity and impact of over 18 processes, including pyrolysis, gasification, enzymatic depolymerization, and HTL Adoption trends across packaging, energy, agriculture, and automotive sectors Regional investment analysis, policy frameworks, and commercial pilots Comparative efficiency analysis and future roadmap for modular, distributed deployment Strategic action points for R&D, infrastructure, regulation, and public-private partnerships

Everest Group’s Deep Dive – Technology Awareness reports offer a comprehensive and forward-looking view into a technology’s impact, adoption prospects, and how it can shape an industry over the next four to six years. This report examines advanced materials and sensor technologies that enable traceability and trackability in global supply chains. It covers various innovations, including smart labels, intelligent packaging, quantum dot markers, IoT sensors, digital watermarks, and environmental monitoring tools, which are reshaping supply chain visibility. These technologies help industries address the growing demands for product authenticity, regulatory compliance, counterfeiting prevention, and sustainability reporting. In this report, we analyze adoption drivers, emerging applications, technology readiness levels, and barriers to scale. The report outlines strategic roadmaps, key use cases across industries, and evolving standards. The insights help supply chain, R&D, and sustainability leaders make informed technology investment decisions and future-proof their operations. Scope Geography: global Industry: food and beverage, pharmaceuticals and healthcare, consumer packaged goods, agriculture, chemicals, and materials Application: supply chain transparency, product authentication, regulatory compliance, sustainability tracking, real-time monitoring, and logistics optimization Contents In this report, we examine: The traceability and trackability technologies landscape Smart materials and identification systems, including DNA markers, QD tags, spectral, and edible tagging Sensor and monitoring technologies, such as IoT sensors, GPS, environmental, optical, and thermal sensors Industry use cases and case studies across chemicals, pharma, FMCG, food, and agriculture Key adoption drivers and barriers, including regulatory shifts and implementation costs Future technology roadmaps and innovation opportunities

This report deeply analyzes digital platforms and advanced automation technologies enabling traceability and trackability in global supply chains, with a particular focus on the chemicals, materials, and agriculture sectors. It examines the convergence of digital twins, IoT cloud platforms, blockchain, Automated Guided Vehicles (AGVs), drones, and AI-powered analytics to create transparent, predictive, and autonomous supply chain ecosystems. As regulatory pressures, operational risks, and sustainability expectations increase, these technologies are becoming key enablers of end-to-end visibility, compliance, fraud prevention, and agile decision-making. The report maps technology readiness, identifies high-impact use cases, evaluates adoption barriers, and provides strategic guidance for digital transformation. Scope Industry: chemicals, materials, agriculture Geography: global Application: real-time tracking, supply chain visibility, compliance automation, predictive logistics, warehouse robotics, digital product passports Contents In this report, we examine The role of digital platforms, automation, and analytics in traceability and trackability Technologies such as blockchain, digital twins, RPA, AGVs, drones, and AI supply chain towers Adoption roadmaps, regulatory drivers, and investment trends Use cases across chemicals, agriculture, and manufacturing Challenges around integration, skill gaps, and RoI justification Industry case studies demonstrating impact

This report dives deep into technology advances in sustainable packaging and their role in accelerating the shift toward a circular economy. It evaluates emerging material innovations –including bio-based polymers, mono-material laminates, compostable films, and fiber-reinforced biocomposites – and examines enabling technologies such as digital watermarks, intelligent packaging, and reusable logistics systems. As companies face increasing pressures from evolving regulatory mandates, consumer sustainability expectations, and the need for climate resilience, this report delivers actionable insights into packaging transformation opportunities and challenges. It offers an ecosystem view of the sustainable packaging value chain, maps technology readiness and adoption barriers, and highlights how stakeholders across industries can design for recyclability, integrate smart features, and close material loops. Case examples, roadmaps, and innovation trends further contextualize the strategic and operational implications for brands, manufacturers, and policymakers. Scope Geography: global Industry: packaging, consumer goods, food and beverages, healthcare, retail, logistics Application: primary, secondary, and tertiary packaging formats; recyclable, compostable, reusable, and intelligent packaging systems Contents In this report, we examine: Material innovations, including bio-based polymers, mono-material laminates, and biocomposites Degradation and detoxification technologies, such as enzymatic depolymerization and accelerated composting Reuse systems, return logistics, and refill models Intelligent packaging formats with embedded sensors, digital tracking, and recycling guidance Regulatory drivers, market adoption challenges, and value chain dynamics Industry case studies and technology-readiness assessments

The Gaseous Waste Valorization: Technology Advances and Application Assessment report evaluates technology, economic, and regulatory trends shaping the gas-to-chemicals landscape. It examines key innovation clusters, technology readiness levels, and the evolving market landscape for converting carbon dioxide, methane, and other industrial gases into commercially viable products. The report highlights diverse valorization routes, including thermal conversion, catalytic copolymerization, electrochemical reduction, enzymatic processes, mineralization, and plasma catalysis. Each route is assessed for its current impact and future potential across chemicals, energy, plastics, and automotive sectors. The report further evaluates the investment landscape, policy drivers, industrial partnerships, and technology roadmaps to help stakeholders build resilient strategies for scaling circular carbon solutions. Scope Industry: chemicals, energy, automotive, and plastics and packaging Geography: global Application: gaseous waste-to-chemical conversion technologies, decarbonization strategies, CO₂ and methane valorization, synthetic fuels, and sustainable polymers Contents In this report, we examine Technology maturity and adoption trends across valorization pathways Key drivers and restraints for technology deployment Industry-specific application analysis and future outlook Comparative analysis of conversion technologies by efficiency and energy demand Technology development roadmaps through 2030 Innovation ecosystem: patents, partnerships, and pilot projects Investment trends and regional activity hotspots

Policymakers and industrial stakeholders globally are striving to transition to a low-carbon economy to achieve net-zero targets in the long term. However, sectors such as aviation, shipping, long-distance transport, and heavy industries have difficulty decarbonizing using direct electrification. These hard-to-abate sectors need large-scale, high-energy-density feedstocks to decarbonize. Hydrogen is the ideal energy carrier, enabling energy diversification when produced through renewable energy, significantly reducing emissions while aiding policymakers to meet long-term pledges. Additionally, renewable energy sources are highly intermittent, leading to fluctuations in renewable energy storage. Power-to-X (PtX) technology advances help convert surplus renewable energy into stable energy carriers, such as hydrogen and its derivatives, including Sustainable Aviation Fuel (SAF), methanol, ammonia, and synthetic methane, for aviation, maritime, agriculture, and chemicals industries. PtX efficiently harnesses renewable energy by producing synthetic fuels, chemicals, and other specialty compounds. It also reduces carbon emissions and minimizes dependency on fossil fuels. In this report, we analyze the growing PtX technology adoption across industries and how it aids decarbonization. Scope Geography: all Industry: energy, environment, and transportation Contents In this report, we examine: The PtX technology landscape and its significant pathways Key factors driving R&D and adoption Key technology developers, regulations, and techno-economic analysis PtX technologies’ future trajectory