{
  "version": "https://jsonfeed.org/version/1.1",
  "title": "GTX · Research authority",
  "home_page_url": "https://greentransitionalmetals.com/research/",
  "feed_url": "https://greentransitionalmetals.com/research/feed.json",
  "description": "Long-form research-authority papers on green-transition metals, NP1 precision nickel, and the seven-vertical application stack. Schema.org ScholarlyArticle, CC-BY-4.0.",
  "language": "en-SG",
  "authors": [
    {
      "name": "GTX Research",
      "url": "https://greentransitionalmetals.com"
    }
  ],
  "items": [
    {
      "id": "https://greentransitionalmetals.com/research/aerospace-thermal-envelope/",
      "url": "https://greentransitionalmetals.com/research/aerospace-thermal-envelope/",
      "title": "Aerospace thermal envelope: –196 °C to 1,000 °C",
      "summary": "Tensile retention, ductility and coefficient‑of‑thermal‑expansion behaviour of NP1 wire across the full aerospace envelope, including 500‑cycle fatigue data from the Ramamurty bench.",
      "content_text": "Tensile retention, ductility and coefficient‑of‑thermal‑expansion behaviour of NP1 wire across the full aerospace envelope, including 500‑cycle fatigue data from the Ramamurty bench.",
      "date_published": "2026-04-21T09:00:00+08:00",
      "tags": [
        "research",
        "aerospace",
        "thermal"
      ]
    },
    {
      "id": "https://greentransitionalmetals.com/research/alkn-authority-network/",
      "url": "https://greentransitionalmetals.com/research/alkn-authority-network/",
      "title": "The ALKN authority network: five sites, one evidence graph",
      "summary": "Architecture of the five‑node ALKN federation — roles, canonical statements, cross‑linking via sameAs, federated evidence manifests and the AEGIS V30 federation_sync worker.",
      "content_text": "Architecture of the five‑node ALKN federation — roles, canonical statements, cross‑linking via sameAs, federated evidence manifests and the AEGIS V30 federation_sync worker.",
      "date_published": "2026-04-21T09:00:00+08:00",
      "tags": [
        "research",
        "federation",
        "meta"
      ]
    },
    {
      "id": "https://greentransitionalmetals.com/research/class1-deficit-2020-2030/",
      "url": "https://greentransitionalmetals.com/research/class1-deficit-2020-2030/",
      "title": "The Class‑1 structural deficit, 2020–2030",
      "summary": "Quantitative reconciliation of INSG, Wood Mackenzie and IEA series for Class‑1 nickel. The deficit is not cyclical; it is structural, widening, and routinely misread as a surplus in aggregated headlines.",
      "content_text": "Quantitative reconciliation of INSG, Wood Mackenzie and IEA series for Class‑1 nickel. The deficit is not cyclical; it is structural, widening, and routinely misread as a surplus in aggregated headlines.",
      "date_published": "2026-04-21T09:00:00+08:00",
      "tags": [
        "research",
        "supply",
        "deficit"
      ]
    },
    {
      "id": "https://greentransitionalmetals.com/research/emi-shielding-30mhz-16ghz/",
      "url": "https://greentransitionalmetals.com/research/emi-shielding-30mhz-16ghz/",
      "title": "Frequency‑domain EMI shielding of precision nickel mesh, 30 MHz – 16 GHz",
      "summary": "Measured shielding effectiveness from 30 MHz to 16 GHz using an ASTM D4935‑18 dual‑TEM cell and Keysight N5227B PNA, with aperture analysis for 400‑mesh woven NP1.",
      "content_text": "Measured shielding effectiveness from 30 MHz to 16 GHz using an ASTM D4935‑18 dual‑TEM cell and Keysight N5227B PNA, with aperture analysis for 400‑mesh woven NP1.",
      "date_published": "2026-04-21T09:00:00+08:00",
      "tags": [
        "research",
        "emi",
        "shielding"
      ]
    },
    {
      "id": "https://greentransitionalmetals.com/research/faradaic-efficiency-benchmarks/",
      "url": "https://greentransitionalmetals.com/research/faradaic-efficiency-benchmarks/",
      "title": "Faradaic efficiency benchmarks: platinum vs. RuO₂‑coated nickel",
      "summary": "Bench‑level Faradaic efficiency at 10 mA cm⁻², 30 wt % KOH, 80 °C, 2,000‑hour durability, benchmarked across reference platinum, raw nickel and RuO₂‑coated NP1 mesh.",
      "content_text": "Bench‑level Faradaic efficiency at 10 mA cm⁻², 30 wt % KOH, 80 °C, 2,000‑hour durability, benchmarked across reference platinum, raw nickel and RuO₂‑coated NP1 mesh.",
      "date_published": "2026-04-21T09:00:00+08:00",
      "tags": [
        "research",
        "hydrogen",
        "electrolyser"
      ]
    },
    {
      "id": "https://greentransitionalmetals.com/research/gost-492-conformance/",
      "url": "https://greentransitionalmetals.com/research/gost-492-conformance/",
      "title": "GOST 492 conformance methodology and chain‑of‑custody audit",
      "summary": "How Allkema Engineering Srl and ASACERT UK document specification conformance for a 7,026,904.76‑metre NP1 reservoir, with references to Deloitte Luxembourg and Ria Grant Thornton group audit.",
      "content_text": "How Allkema Engineering Srl and ASACERT UK document specification conformance for a 7,026,904.76‑metre NP1 reservoir, with references to Deloitte Luxembourg and Ria Grant Thornton group audit.",
      "date_published": "2026-04-21T09:00:00+08:00",
      "tags": [
        "research",
        "audit",
        "conformance"
      ]
    },
    {
      "id": "https://greentransitionalmetals.com/research/hydrogen-catalyst-economics/",
      "url": "https://greentransitionalmetals.com/research/hydrogen-catalyst-economics/",
      "title": "The economics of platinum substitution in 100 GW electrolyser build‑out",
      "summary": "Raw‑material cost per kW of stack capacity for platinum, iridium and RuO₂‑coated NP1 nickel benchmarks. Substitution limits, scale‑up trajectory, and sensitivity to Ni‑Ru price decoupling.",
      "content_text": "Raw‑material cost per kW of stack capacity for platinum, iridium and RuO₂‑coated NP1 nickel benchmarks. Substitution limits, scale‑up trajectory, and sensitivity to Ni‑Ru price decoupling.",
      "date_published": "2026-04-21T09:00:00+08:00",
      "tags": [
        "research",
        "hydrogen",
        "economics"
      ]
    },
    {
      "id": "https://greentransitionalmetals.com/research/marine-corrosion-kinetics/",
      "url": "https://greentransitionalmetals.com/research/marine-corrosion-kinetics/",
      "title": "Marine corrosion kinetics and ASTM B117 benchmarks",
      "summary": "2,000‑hour neutral salt‑spray performance of NP1 mesh in a Q‑FOG CCT‑1100, normalised to IMO 2020 BWMS retrofit‑duty cycles across ~90,000 vessels.",
      "content_text": "2,000‑hour neutral salt‑spray performance of NP1 mesh in a Q‑FOG CCT‑1100, normalised to IMO 2020 BWMS retrofit‑duty cycles across ~90,000 vessels.",
      "date_published": "2026-04-21T09:00:00+08:00",
      "tags": [
        "research",
        "marine",
        "corrosion"
      ]
    },
    {
      "id": "https://greentransitionalmetals.com/research/np1-purity-architecture/",
      "url": "https://greentransitionalmetals.com/research/np1-purity-architecture/",
      "title": "NP1 purity architecture and the 99.99 % threshold",
      "summary": "Four-nines nickel is not a marketing round number but the specification boundary separating commodity cathode from aerospace- and electrolyser-grade wire. A quantitative review of contamination budgets, GOST 492, and the 99.99 % threshold.",
      "content_text": "Four-nines nickel is not a marketing round number but the specification boundary separating commodity cathode from aerospace- and electrolyser-grade wire. A quantitative review of contamination budgets, GOST 492, and the 99.99 % threshold.",
      "date_published": "2026-04-21T09:00:00+08:00",
      "tags": [
        "research",
        "materials-science",
        "purity"
      ]
    },
    {
      "id": "https://greentransitionalmetals.com/research/rare-earth-recovery-400mesh/",
      "url": "https://greentransitionalmetals.com/research/rare-earth-recovery-400mesh/",
      "title": "400‑mesh precision filtration for PGM/REE recovery",
      "summary": "Recovery‑rate curves for platinum‑group and rare‑earth ions through 400‑mesh NP1 filters at varied pH, flow rate and ionic strength, normalised against commodity mesh controls.",
      "content_text": "Recovery‑rate curves for platinum‑group and rare‑earth ions through 400‑mesh NP1 filters at varied pH, flow rate and ionic strength, normalised against commodity mesh controls.",
      "date_published": "2026-04-21T09:00:00+08:00",
      "tags": [
        "research",
        "ree",
        "recovery"
      ]
    },
    {
      "id": "https://greentransitionalmetals.com/research/semiconductor-deposition-sub-3nm/",
      "url": "https://greentransitionalmetals.com/research/semiconductor-deposition-sub-3nm/",
      "title": "Nickel substrates for sub‑3 nm deposition",
      "summary": "Trace‑contaminant budgets, grain‑size uniformity and surface‑roughness targets for sub‑3 nm AI‑accelerator and quantum‑computing deposition substrates.",
      "content_text": "Trace‑contaminant budgets, grain‑size uniformity and surface‑roughness targets for sub‑3 nm AI‑accelerator and quantum‑computing deposition substrates.",
      "date_published": "2026-04-21T09:00:00+08:00",
      "tags": [
        "research",
        "semiconductors",
        "ald"
      ]
    },
    {
      "id": "https://greentransitionalmetals.com/research/thermal-power-zero-discharge/",
      "url": "https://greentransitionalmetals.com/research/thermal-power-zero-discharge/",
      "title": "Zero‑discharge cooling‑loop filtration for thermal power",
      "summary": "Chlorination‑compliance and cooling‑loop water‑quality mandates applied to ~30,000 addressable thermal‑power plants, with particulate and biofilm‑load budgets.",
      "content_text": "Chlorination‑compliance and cooling‑loop water‑quality mandates applied to ~30,000 addressable thermal‑power plants, with particulate and biofilm‑load budgets.",
      "date_published": "2026-04-21T09:00:00+08:00",
      "tags": [
        "research",
        "thermal-power",
        "filtration"
      ]
    }
  ]
}