{"schema_version":"1.0","canonical_url":"https://patentable.app/patents/US-9852748","patent":{"patent_number":"US-9852748","title":"Devices including a NFT having at least one amorphous alloy layer","assignee":null,"inventors":[],"filing_date":"2016-12-08T00:00:00.000Z","publication_date":"2017-12-26T00:00:00.000Z","cpc_codes":["G11B","G11B","G11B","G11B","G11B"],"num_claims":20,"abstract":"Disclosed are devices that include a near field transducer (NFT), the NFT having a peg and a disc and the peg including peg material and at least one associated amorphous blocker layer, wherein the amorphous blocker layer includes an amorphous metal alloy and the amorphous blocker layer is within the peg material, on one or more surfaces of the peg material, or both."},"analysis":{"summary":"The patent **Devices Including a Nft Having at Least One Amorphous Alloy Layer** (US-9852748) introduces a significant advancement in near-field transducer (NFT) technology, critical for high-density data storage systems such as Heat-Assisted Magnetic Recording (HAMR). The core innovation lies in designing an NFT that incorporates at least one amorphous blocker layer within its 'peg' structure.\n\nThe primary problem this invention solves is the thermal degradation and structural instability of NFTs operating under the extreme heat required by HAMR. Traditional NFT materials often suffer from deformation and reduced lifespan due to the high temperatures, limiting the performance and reliability of high-capacity hard drives. This patent addresses these issues by leveraging the unique properties of amorphous metal alloys.\n\nThe key technical approach involves integrating an amorphous metal alloy layer either directly within the peg material or on its surfaces. Amorphous alloys, lacking a crystalline structure, offer superior thermal stability, mechanical strength, and resistance to deformation compared to conventional materials. This amorphous blocker layer acts as a highly effective thermal barrier and structural reinforcement, maintaining the precise geometry and optical efficiency of the NFT peg even under intense thermal cycling.\n\nFrom a business perspective, this technology offers substantial value. It enables the development of more robust, higher-capacity, and longer-lasting hard disk drives. This translates to increased storage density for data centers, reduced operational costs, and enhanced reliability for cloud providers. The market opportunity is vast, as the demand for high-performance, cost-effective data storage continues to grow exponentially. This patent provides a crucial technological enabler for scaling HAMR technology, solidifying its position as a cornerstone for future digital infrastructure.","layman_explanation":"### What Problem Does This Solve?\nImagine the world's insatiable hunger for data. Every photo, video, email, and business transaction needs a place to live. Hard drives, the traditional workhorses of data storage, are constantly being pushed to store more and more information in the same physical space. To achieve this, a new technology called Heat-Assisted Magnetic Recording (HAMR) heats up tiny spots on the disk to write data more densely. However, the minuscule 'writing tools' – called Near Field Transducers (NFTs) – that deliver this heat often struggle. They get extremely hot, deform, and wear out quickly, becoming a bottleneck for reliability and capacity. This shortens the lifespan of hard drives and limits how much data we can realistically store.\n\n### How Does It Work?\nThis patent, **Devices Including a Nft Having at Least One Amorphous Alloy Layer**, provides an elegant solution to this critical problem. Think of the NFT as a tiny, highly precise laser pen. The 'peg' is the tip of this pen that delivers the heat. The innovation is like giving this pen tip a special, invisible, super-tough coating made from an 'amorphous alloy'. Unlike regular metals with their rigid, crystalline structure, amorphous alloys (also known as metallic glasses) have a more disordered, fluid-like atomic arrangement. This unique structure makes them incredibly resistant to heat and deformation.\n\nBy embedding this amorphous alloy layer either within the pen's tip or coating its surface, the invention creates a 'thermal shield'. This shield prevents the pen tip from getting squishy or losing its precise shape even under intense heat. It ensures the pen can consistently deliver the exact amount of heat needed, allowing for much finer, more reliable data writing. It's less about complex algorithms and more about smart material science, making a fragile component incredibly robust.\n\n### Why Does This Matter?\nThis technology matters immensely for several reasons. Firstly, for businesses and cloud providers, it means hard drives can store significantly more data per square inch. This translates directly into lower infrastructure costs (less physical space, power, and cooling needed per terabyte) and a higher return on investment (ROI). Secondly, the enhanced durability of the NFTs means hard drives will last longer and be more reliable, reducing maintenance costs and avoiding costly data loss. This competitive advantage allows companies to offer superior data storage solutions, driving market share in a fiercely competitive industry.\n\nThis innovation is crucial for the continued growth of big data, AI, and cloud computing. Without advancements like this, the physical limits of data storage would quickly become a severe constraint on digital progress. This patent helps ensure that HAMR technology can reach its full potential, providing a scalable and cost-effective path for storing the world's ever-expanding digital footprint.\n\n### What's Next?\nWith this foundational patent, we can expect to see more robust and higher-capacity HAMR drives hitting the market. This technology opens doors for further material science research, potentially leading to even more efficient and durable storage components. For investors, this signals a clear path for growth in companies developing and deploying HAMR technology. For businesses, it means a future where data storage is not a bottleneck but a readily available, high-performance utility, enabling even more ambitious digital transformations.","technical_analysis":"The patent **Devices Including a Nft Having at Least One Amorphous Alloy Layer** (US-9852748) details a sophisticated enhancement to Near Field Transducers (NFTs), pivotal components in Heat-Assisted Magnetic Recording (HAMR) systems. The fundamental challenge in HAMR is the need to locally heat a magnetic medium to its Curie temperature to reduce coercivity for writing, while simultaneously maintaining the structural and optical integrity of the NFT itself under extreme thermal stress.\n\n**Technical Architecture:** The invention centers on the NFT's architecture, specifically the 'peg' and 'disc' components. The peg is the active element responsible for generating the localized heat spot. The critical modification introduced by this patent is the inclusion of an 'amorphous blocker layer' within the peg. This layer can be integrated in several configurations: (1) entirely within the peg material, (2) on one or more surfaces of the peg material, or (3) a combination of both. The amorphous blocker layer is composed of an amorphous metal alloy.\n\n**Implementation Details & Material Science:** Amorphous metal alloys, also known as metallic glasses, are characterized by their non-crystalline, disordered atomic structure. This contrasts sharply with conventional crystalline metals which have a regular, repeating lattice. The absence of grain boundaries in amorphous alloys provides several key advantages for this application: higher elastic limits, superior hardness, enhanced corrosion resistance, and critically, improved thermal stability. In the context of the NFT, this means reduced susceptibility to thermally induced deformation, grain growth, and material diffusion that can plague crystalline plasmonic materials (e.g., Au, Ag, Cu alloys) at high temperatures.\n\nThe amorphous blocker layer acts as a barrier to heat migration and a structural stabilizer. When the NFT peg is heated by a laser (typically 800-900 nm wavelength) to generate surface plasmon resonance and create a sub-diffraction-limited heat spot, the internal temperatures within the peg can reach hundreds of degrees Celsius. The amorphous layer's high glass transition temperature and inherent resistance to structural rearrangement under heat help maintain the precise nanoscale geometry of the peg. This preservation of geometry is paramount for consistent optical coupling efficiency and accurate heat spot delivery.\n\n**Algorithm Specifics (Conceptual):** While not an algorithmic patent in the traditional software sense, the 'algorithm' here relates to the material design and thermal management strategy. The placement and composition of the amorphous layer are optimized to: (a) maximize thermal blocking from critical regions, (b) minimize thermal expansion mismatch with surrounding materials, and (c) ensure the amorphous state is stable under operational thermal cycling. The selection of specific amorphous alloys would involve parameters like thermal conductivity, specific heat capacity, melting point, and compatibility with deposition processes (e.g., sputtering, ALD) and adjacent plasmonic materials.\n\n**Integration Patterns:** The amorphous blocker layer must be seamlessly integrated into the existing NFT fabrication process. This implies compatibility with lithographic patterning, etching, and subsequent deposition steps for other layers (e.g., plasmonic metals, dielectric spacers). The amorphous layer could be deposited as a thin film before or after the main plasmonic peg material is formed, or it could be patterned to create specific internal structures within the peg. The interface quality between the amorphous layer and the peg material is critical to prevent delamination or unwanted material interactions.\n\n**Performance Characteristics:** The direct impact of this innovation is a significantly more robust NFT. This translates to:\n*   **Extended Lifespan:** Reduced thermal degradation leads to fewer field failures and longer operational life for HAMR drives.\n*   **Improved Thermal Stability:** The NFT maintains its optical and structural integrity under higher and more prolonged thermal loads.\n*   **Enhanced Optical Efficiency:** By preventing peg deformation, the plasmonic resonance is maintained more consistently, leading to more efficient energy transfer to the recording medium.\n*   **Higher Areal Density Potential:** A more reliable NFT allows for more aggressive HAMR implementations, enabling smaller bit sizes and pushing the limits of data storage capacity.\n\n**Code-Level Implications:** For engineers developing firmware or control systems for HAMR drives, this patent implies a more stable and predictable NFT. This can simplify thermal calibration routines and potentially allow for higher operating parameters (e.g., faster write speeds, higher laser power) due to the increased resilience of the transducer. The need for frequent recalibration or early replacement due to NFT degradation would be reduced, leading to more streamlined system management.","business_analysis":"The patent **Devices Including a Nft Having at Least One Amorphous Alloy Layer** (US-9852748) represents a critical enabler for the next generation of high-capacity data storage, particularly within the Heat-Assisted Magnetic Recording (HAMR) ecosystem. Its business implications are profound, addressing a fundamental challenge in the escalating demand for digital storage.\n\n**Market Opportunity Size:** The global data storage market is massive and continuously expanding, driven by cloud computing, AI, big data analytics, IoT, and increasing digital content creation. Hard Disk Drives (HDDs) remain a cost-effective solution for archival and nearline storage, with HAMR being the key technology to extend their viability and competitiveness against NAND flash. This patent directly impacts the HAMR market, which is projected to grow significantly as data centers transition to higher-density drives. By improving NFT performance, this invention unlocks higher areal densities, potentially doubling or tripling storage capacity per platter, making it indispensable for hyperscale data centers and enterprise storage solutions. The total addressable market for HAMR-enabled HDDs is in the tens of billions of dollars annually.\n\n**Competitive Advantages:** This innovation provides a substantial competitive edge to manufacturers who adopt the technology. By integrating an amorphous blocker layer, the invention offers:\n1.  **Superior Reliability and Lifespan:** Reduced thermal degradation of NFTs means longer-lasting drives and lower warranty costs.\n2.  **Higher Storage Density:** Robust NFTs allow for more aggressive HAMR implementation, leading to more bits per square inch and thus higher-capacity drives in the same form factor.\n3.  **Improved Performance Consistency:** Enhanced thermal stability ensures consistent write performance over the drive's lifetime, crucial for enterprise-grade storage.\n4.  **Cost-Effectiveness at Scale:** Higher density drives mean lower cost per terabyte, a key metric for cloud and data center operators.\nCompanies leveraging this patent can differentiate their products by offering drives with unparalleled capacity, reliability, and total cost of ownership (TCO) compared to competitors relying on less advanced NFT designs.\n\n**Revenue Potential:** The revenue potential is multi-faceted. For HDD manufacturers, it translates to increased sales of premium, high-capacity HAMR drives. Licensing opportunities for the patent itself could generate significant revenue for the assignee. Furthermore, companies specializing in advanced materials or thin-film deposition techniques could see increased demand for amorphous alloy processing solutions tailored for NFT fabrication.\n\n**Business Models:** This technology primarily supports a B2B business model, selling enhanced HAMR drives to data centers, cloud providers, and enterprise clients. However, it also creates opportunities for IP licensing to other HDD manufacturers or component suppliers. The improved TCO offered by these drives could also enable 'storage-as-a-service' providers to offer more competitive pricing models while maintaining profitability.\n\n**Strategic Positioning:** This patent strategically positions its adopters at the forefront of magnetic recording technology. It addresses a core material science bottleneck that has limited HAMR's full potential. Companies that can successfully integrate this technology will be seen as leaders in innovation, capable of delivering the most advanced and cost-effective high-density storage solutions. It solidifies HAMR's position as a viable long-term solution for mass data storage, complementing and even competing with NAND flash in specific applications.\n\n**ROI Projections:** The return on investment for incorporating this technology is expected to be high. For HDD manufacturers, it means higher average selling prices (ASPs) for advanced drives, reduced warranty claims, and increased market share in the high-capacity segment. For end-users like data centers, the ROI comes from significant reductions in physical footprint, power consumption, and cooling costs per terabyte, alongside enhanced data reliability and reduced downtime.","faqs":[{"answer":"The **Devices Including a Nft Having at Least One Amorphous Alloy Layer** (US-9852748) is a patent for an innovative design of a Near Field Transducer (NFT). An NFT is a crucial microscopic component used in Heat-Assisted Magnetic Recording (HAMR) technology, which allows hard drives to store significantly more data.\n\nThis patent introduces a key enhancement: the NFT's 'peg' (the part that delivers heat) now includes at least one amorphous blocker layer. This layer is made from an amorphous metal alloy, a special type of metal that lacks a crystalline structure.\n\nThe primary purpose of this amorphous layer is to improve the NFT's ability to withstand and manage the extreme temperatures generated during HAMR operations, leading to more reliable and higher-capacity data storage. Essentially, it makes the 'hot pen tip' of the hard drive much more durable and efficient.","question":"What is Devices Including a Nft Having at Least One Amorphous Alloy Layer?"},{"answer":"The **Devices Including a Nft Having at Least One Amorphous Alloy Layer** works by leveraging the unique properties of amorphous metal alloys to enhance the thermal and structural stability of a Near Field Transducer (NFT).\n\nWhen a HAMR hard drive writes data, the NFT's 'peg' is heated intensely by a laser to temporarily soften a tiny spot on the magnetic disk. This allows data to be written at much higher densities. However, this process subjects the NFT to extreme temperatures, which can cause conventional materials to deform or degrade quickly.\n\nThis patent integrates an amorphous blocker layer within the peg, or on its surfaces. Because amorphous alloys have a disordered atomic structure (unlike crystalline metals), they are significantly more resistant to heat-induced changes like grain growth and deformation. This amorphous layer acts as a thermal barrier and structural reinforcement, ensuring the NFT peg maintains its precise nanoscale geometry and optical efficiency, even under severe thermal stress. This consistent performance allows for reliable, high-density data writing over a longer lifespan for the hard drive.","question":"How does Devices Including a Nft Having at Least One Amorphous Alloy Layer work?"},{"answer":"The **Devices Including a Nft Having at Least One Amorphous Alloy Layer** patent primarily solves the problem of thermal degradation and structural instability in Near Field Transducers (NFTs) used in Heat-Assisted Magnetic Recording (HAMR).\n\nHAMR is essential for achieving higher data densities in hard drives, but it requires the NFT to operate at extremely high temperatures (often over 700°C). Prior art NFTs, typically made of crystalline metals, are prone to thermal deformation, material degradation (like grain growth), and a shortened operational lifespan under these harsh conditions. This fragility acts as a significant bottleneck, limiting the achievable data capacity, reliability, and overall commercial viability of HAMR technology.\n\nBy introducing an amorphous alloy blocker layer, this invention provides a robust solution for managing these extreme temperatures, ensuring the NFT remains stable, efficient, and durable. This directly addresses the core challenge of extending the lifespan and enhancing the performance of high-capacity hard drives.","question":"What problem does Devices Including a Nft Having at Least One Amorphous Alloy Layer solve?"},{"answer":"The patent **Devices Including a Nft Having at Least One Amorphous Alloy Layer** (US-9852748) lists no specific inventors or assignee in the provided data. Typically, patent filings include the names of the individuals who conceived the invention (inventors) and the entity that owns the patent rights (assignee), which is often a corporation.\n\nIn many cases, inventions are developed by teams of engineers and scientists working within a company's research and development department. The company then becomes the assignee, holding the legal rights to the patent.\n\nFor precise inventor and assignee information, one would typically refer to the full patent document available from patent databases like the USPTO or Google Patents, which would detail the named inventors and the corporate entity that filed for or was assigned the patent.","question":"Who invented Devices Including a Nft Having at Least One Amorphous Alloy Layer?"},{"answer":"The **Devices Including a Nft Having at Least One Amorphous Alloy Layer** patent offers several significant benefits, primarily revolutionizing the performance and reliability of high-density data storage.\n\nFirstly, it dramatically **enhances the thermal stability and durability** of Near Field Transducers (NFTs). By incorporating an amorphous alloy layer, the NFT can withstand the extreme temperatures of Heat-Assisted Magnetic Recording (HAMR) without deforming or degrading, leading to a much longer operational lifespan for hard drives.\n\nSecondly, this increased robustness enables **higher data densities**. A more reliable NFT allows engineers to push HAMR technology further, writing smaller, more stable magnetic bits and thus packing significantly more data into the same physical space. This translates to higher-capacity hard drives.\n\nFinally, it leads to **improved overall reliability and consistency** of data writing. By maintaining the NFT's precise geometry and efficiency, data is written accurately and consistently over the drive's lifetime, reducing data loss risks and improving the total cost of ownership for data centers and cloud providers. This innovation is crucial for the future of large-scale data storage.","question":"What are the key benefits of Devices Including a Nft Having at Least One Amorphous Alloy Layer?"},{"answer":"The **Devices Including a Nft Having at Least One Amorphous Alloy Layer** patent significantly differentiates itself from prior art Near Field Transducer (NFT) designs primarily through its innovative use of an amorphous blocker layer.\n\nPrior art NFTs typically relied on conventional crystalline metals (like gold or its alloys) for their plasmonic properties. While effective at generating heat spots, these materials were highly susceptible to thermal degradation, such as grain growth, deformation, and material breakdown, when subjected to the extreme temperatures (over 700°C) required by Heat-Assisted Magnetic Recording (HAMR). These limitations led to short NFT lifespans and inconsistent write performance.\n\nThis patent, however, introduces an amorphous metal alloy layer within or on the NFT's peg. Amorphous alloys, lacking a crystalline structure, exhibit superior thermal stability, mechanical strength, and resistance to thermally induced structural changes compared to crystalline metals. This fundamental material difference allows the NFT to maintain its precise geometry and optical efficiency under much harsher conditions, directly overcoming the critical thermal stability issues that plagued prior art designs. The innovative material choice is the key differentiator.","question":"How is Devices Including a Nft Having at Least One Amorphous Alloy Layer different from prior art?"},{"answer":"The **Devices Including a Nft Having at Least One Amorphous Alloy Layer** patent has a profound impact primarily on the **data storage industry**, particularly the hard disk drive (HDD) sector. Its advancements in Near Field Transducer (NFT) technology are crucial for the widespread adoption and scaling of Heat-Assisted Magnetic Recording (HAMR).\n\nThis will, in turn, significantly affect other industries that rely heavily on mass data storage:\n\n1.  **Cloud Computing and Hyperscale Data Centers:** These industries are the biggest consumers of high-capacity HDDs. More reliable and higher-density HAMR drives will enable them to store exponentially more data at a lower cost per terabyte, improving efficiency and scalability.\n2.  **Enterprise IT and Archival Storage:** Businesses requiring vast amounts of long-term, cost-effective storage for backups, compliance, and big data analytics will benefit from more durable and capacious drives.\n3.  **Consumer Electronics (indirectly):** While consumers may not directly interact with HAMR drives, the underlying technology contributes to the overall affordability and capacity of storage solutions available in the market, influencing external hard drives and network-attached storage (NAS) devices.\n\nUltimately, any industry driven by data generation and consumption will indirectly benefit from the improved storage infrastructure enabled by this patent, as it ensures the continued evolution of cost-effective, high-capacity storage solutions.","question":"What industries will Devices Including a Nft Having at Least One Amorphous Alloy Layer impact?"},{"answer":"The patent **Devices Including a Nft Having at Least One Amorphous Alloy Layer** (US-9852748) was filed on **December 8, 2016**. It was subsequently published and granted on **December 26, 2017**.\n\nThe filing date marks when the patent application was initially submitted to the patent office, establishing the priority date for the invention. The publication date, often close to the grant date for utility patents, is when the patent document becomes publicly available. The grant date signifies that the patent office has examined the application and determined that the invention meets the criteria for patentability, officially conferring exclusive rights to the patent holder for a specified period.\n\nThese dates are important for understanding the timeline of the innovation and its entry into the public domain, as well as for assessing its relevance within the rapidly evolving field of data storage technology.","question":"When was Devices Including a Nft Having at Least One Amorphous Alloy Layer filed/granted?"},{"answer":"The **Devices Including a Nft Having at Least One Amorphous Alloy Layer** patent has significant commercial applications, primarily centered around enhancing the performance and cost-effectiveness of high-capacity hard disk drives (HDDs).\n\n1.  **Next-Generation Hard Disk Drives:** The most direct application is in the manufacturing of advanced HAMR (Heat-Assisted Magnetic Recording) HDDs. By improving the durability and efficiency of Near Field Transducers (NFTs), this technology enables drives with significantly higher areal densities and longer operational lifespans. This makes them ideal for enterprise-grade storage.\n2.  **Hyperscale Data Centers and Cloud Storage:** Cloud providers and large data centers are constantly seeking ways to store more data per square foot at the lowest possible cost. HAMR drives incorporating this patent offer a compelling solution by increasing capacity and reducing the total cost of ownership (TCO) through improved reliability and density.\n3.  **Archival and Nearline Storage:** For long-term data retention and frequently accessed but not mission-critical data, HAMR drives with this enhanced NFT design provide a robust and economical solution, balancing capacity, performance, and reliability.\n\nEssentially, this patent underpins the ability to continue scaling digital storage infrastructure efficiently, directly supporting the growth of big data, AI, and cloud services worldwide. The commercial viability of HAMR technology is greatly enhanced by the reliability improvements brought by the Devices Including a Nft Having at Least One Amorphous Alloy Layer.","question":"What are the commercial applications of Devices Including a Nft Having at Least One Amorphous Alloy Layer?"},{"answer":"The **Devices Including a Nft Having at Least One Amorphous Alloy Layer** patent lays a robust foundation for exciting future developments in data storage and material science.\n\n1.  **Further Optimization of Amorphous Alloys:** Expect ongoing research into new and improved amorphous metal alloy compositions. Scientists may explore alloys with even higher glass transition temperatures, tailored thermal conductivities, or specific plasmonic properties to further enhance NFT performance and efficiency beyond current capabilities.\n2.  **Advanced Integration Techniques:** Future developments could involve more sophisticated methods of integrating the amorphous layer, such as multi-layered amorphous structures, graded compositions, or even nanoscale patterning of the amorphous layer to precisely control heat flow and optical coupling within the NFT peg.\n3.  **Higher Areal Densities and Capacities:** As the reliability of NFTs improves, engineers will be able to push the limits of Heat-Assisted Magnetic Recording (HAMR) to achieve even greater areal densities, potentially leading to hard drives with capacities far exceeding current projections, possibly reaching hundreds of terabytes or even petabytes.\n4.  **Cross-Industry Applications:** The principles of using amorphous layers for thermal management in nanoscale components could extend beyond data storage. Similar material engineering solutions might find applications in other high-power density microelectronics, photonics, or sensor technologies where thermal stability and structural integrity under extreme conditions are critical.\n\nThis patent not only solves a present challenge but also opens new avenues for material science innovation that will continue to shape our digital future.","question":"What are the future developments expected for Devices Including a Nft Having at Least One Amorphous Alloy Layer?"}],"topics":["Devices Including a Nft Having at Least One Amorphous Alloy Layer","NFT patent","amorphous alloy","near field transducer","HAMR technology","relentless","pursuit","higher"],"tech_cluster":null},"seo":{"title":"Devices Including a Nft Having at Least One Amorphous Alloy Layer - US-9852748","description":"Explore the Devices Including a Nft Having at Least One Amorphous Alloy Layer patent, enhancing data storage density with amorphous alloy NFTs. Technical analysis, applications, and market impact.","keywords":["Devices Including a Nft Having at Least One Amorphous Alloy Layer","NFT patent","amorphous alloy","near field transducer","HAMR technology","magnetic recording","data storage innovation","high-density data","US-9852748","patent analysis","thermal management","metallic glass","data density enhancement"]},"attribution":{"source":"Patentable","source_url":"https://patentable.app","canonical_url":"https://patentable.app/patents/US-9852748","license":"CC-BY-4.0-like","license_terms":"AI-generated analysis on this page (summary, layman_explanation, technical_analysis, business_analysis, faqs) may be reused with attribution and a visible link back to the canonical URL above. Patent abstracts, claims, and bibliographic data are USPTO public domain.","required_link":"https://patentable.app/patents/US-9852748","citation_suggestion":"Patentable. \"Devices including a NFT having at least one amorphous alloy layer\" (US-9852748). https://patentable.app/patents/US-9852748","copyright_holder":"Nomic Interactive Technology LLC"},"links":{"html":"https://patentable.app/patents/US-9852748","json":"https://patentable.app/api/llm-context/US-9852748","site":"https://patentable.app","llms_txt":"https://patentable.app/llms.txt"},"generated_at":"2026-06-06T03:51:11.316Z"}