![[Deep Dive] Synthetic Fuel Without Crude Oil: South Korean Breakthrough in COβ-to-Gasoline Technology](/content/images/size/w600/2026/04/deep_dive_thumb-4.png)
π¬ DEEP DIVE ANALYSIS Synthetic Fuel Without Crude Oil: South Korean Breakthrough in COβ-to-Gasoline Technology Synthetic Fuel & Clean Energy β’ April 29, 2026 Reading time: ~12 minutes π Contents 1. Executive Summary 2. Technical Deep Dive 3. Market Landscape 4. Timeline & Milestones 5. Investment Perspective 6. Key Takeaways π Executive Summary
![[Quantum Lab | Week 2 Day 1] Si-SiO2 Electron Spin Qubit - AI Lab Simulation](/content/images/size/w600/2026/04/lab_quantum_Si_SiO2_Electron_Spin_Qubit_1.png)
[Week 2 Day 1] Si-SiO2 Electron Spin Qubit Quantum Computing Materials Lab β AI Simulator Activation 2026 π¬ Computational Research Note This analysis is based on computational modeling and theoretical predictions. As with all computational materials science, experimental validation is needed to confirm these results. 1. Why Si-SiO2 Electron Spin Qubit Caught
![[Solar Lab | Week 3 Day 1] Perovskite-Si 2T Tandem - AI Lab Simulation](/content/images/size/w600/2026/04/lab_solar_Perovskite_Si_2T_Tandem_1.png)
[Week 3 Day 1] Perovskite-Si 2T Tandem Solar Cell Materials Lab β AI Simulator Activation 2026 π¬ Computational Research Note This analysis is based on computational modeling and theoretical predictions. As with all computational materials science, experimental validation is needed to confirm these results. 1. Why Perovskite-Si 2T Tandem Caught Our Attention
π’ COMPANY SPOTLIGHT IonQ IonQ develops trapped-ion quantum computers and full-stack quantum solutions, becoming the first quantum company to exceed $100 million in annual revenue. Quantum Computing β’ Founded 2015 β’ College Park, Maryland, USA π Company Overview Focus: Quantum Computing - Trapped Ion π₯ Recent Developments First Photonic Interconnect Milestone Achievement 2026-04-14 IonQ successfully
![[Battery Lab | Week 3 Day 1] Li-S with CNT Matrix - AI Lab Simulation](/content/images/size/w600/2026/04/lab_battery_Li_S_with_CNT_Matrix_1.png)
[Week 3 Day 1] Li-S with CNT Matrix Battery Materials Lab β AI Simulator Activation 2026 π¬ Computational Research Note This analysis is based on computational modeling and theoretical predictions. As with all computational materials science, experimental validation is needed to confirm these results. 1. Why Li-S with CNT Matrix Caught Our
[Week 12 Day 5] MgβBeHββ (isotope study) Superconductor Lab β AI Simulator Activation 2026 π¬ Computational Research Note This analysis is based on computational modeling and theoretical predictions. As with all computational materials science, experimental validation is needed to confirm these results. 1. The Problem: Why Superconductors Are So Hard to
[Week 12 Day 4] LiBeHβ / LiBeβHββ Superconductor Lab β AI Simulator Activation 2026 π¬ Computational Research Note This analysis is based on computational modeling and theoretical predictions. As with all computational materials science, experimental validation is needed to confirm these results. 1. The Hype vs. Reality: LiBeHβ / LiBeβHββ Under the
![[Hydrogen Lab | Week 1 Day 4] TiH2 Titanium Hydride - AI Lab Simulation](/content/images/size/w600/2026/04/lab_hydrogen_TiH2_Titanium_Hydride_1.png)
[Week 1 Day 4] TiH2 Titanium Hydride Hydrogen Storage Materials Lab β AI Simulator Activation 2026 π¬ Computational Research Note This analysis is based on computational modeling and theoretical predictions. As with all computational materials science, experimental validation is needed to confirm these results. 1. Why TiHβ Titanium Hydride Caught Our Attention
![[Solar Lab | Week 2 Day 5] BaZrS3 Chalcogenide Perovskite - AI Lab Simulation](/content/images/size/w600/2026/04/lab_solar_BaZrS3_Chalcogenide_Perovskite_1.png)
[Week 2 Day 5] BaZrS3 Chalcogenide Perovskite Solar Cell Materials Lab β AI Simulator Activation 2026 π¬ Computational Research Note This analysis is based on computational modeling and theoretical predictions. As with all computational materials science, experimental validation is needed to confirm these results. 1. Why BaZrS3 Chalcogenide Perovskite Caught Our Attention
![[Deep Dive] Particle thought to break physics followed rules all along, research reveals - Phys.org](/content/images/size/w600/2026/04/deep_dive_thumb-3.png)
π¬ DEEP DIVE ANALYSIS Particle thought to break physics followed rules all along, research reveals - Phys.org Computing β’ April 28, 2026 Reading time: ~12 minutes π Contents 1. Executive Summary 2. Technical Deep Dive 3. Market Landscape 4. Timeline & Milestones 5. Investment Perspective 6. Key Takeaways π Executive Summary In April
![[Battery Lab | Week 2 Day 5] Beta-Al2O3 Solid Electrolyte - AI Lab Simulation](/content/images/size/w600/2026/04/lab_battery_Beta_Al2O3_Solid_Electrolyte_1.png)
[Week 2 Day 5] Beta-Al2O3 Solid Electrolyte Battery Materials Lab β AI Simulator Activation 2026 π¬ Computational Research Note This analysis is based on computational modeling and theoretical predictions. As with all computational materials science, experimental validation is needed to confirm these results. 1. Why Beta-AlβOβ Solid Electrolyte Caught Our Attention
We tested calcium superhydrides: paper claims above 210 K, our simulation predicts 210Kβ215K. Here's what the gap tells us.
![[Deep Dive] The Accidental Superconductor Discovery That Could Redefine 2026](/content/images/size/w600/2026/04/deep_dive_thumb-2.png)
Deep-Dive
π¬ DEEP DIVE ANALYSIS The Accidental Superconductor Discovery That Could Redefine 2026 Superconductors β’ April 27, 2026 Reading time: ~12 minutes π Contents 1. Executive Summary 2. Technical Deep Dive 3. Market Landscape 4. Timeline & Milestones 5. Investment Perspective 6. Key Takeaways π Executive Summary The superconductivity field entered 2026 with renewed momentum
![[Quantum Lab | Week 1 Day 5] TiN Transmon Silicon-Compatible - AI Lab Simulation](/content/images/size/w600/2026/04/lab_quantum_TiN_Transmon_Silicon_Compatible_1.png)
Quantum-Lab
[Week 1 Day 5] TiN Transmon Silicon-Compatible Quantum Computing Materials Lab β AI Simulator Activation 2026 π¬ Computational Research Note This analysis is based on computational modeling and theoretical predictions. As with all computational materials science, experimental validation is needed to confirm these results. 1. Why TiN Transmon Silicon-Compatible Caught Our Attention
![[Solar Lab | Week 2 Day 4] MA3Bi2I9 Bismuth Halide - AI Lab Simulation](/content/images/size/w600/2026/04/lab_solar_MA3Bi2I9_Bismuth_Halide_1.png)
Solar-Lab
[Week 2 Day 4] MA3Bi2I9 Bismuth Halide Solar Cell Materials Lab β AI Simulator Activation 2026 π¬ Computational Research Note This analysis is based on computational modeling and theoretical predictions. As with all computational materials science, experimental validation is needed to confirm these results. 1. Why MA3Bi2I9 Bismuth Halide Caught Our Attention
![[Battery Lab | Week 2 Day 4] Hard Carbon Na-Anode - AI Lab Simulation](/content/images/size/w600/2026/04/lab_battery_Hard_Carbon_Na_Anode_1.png)
Battery-Lab
[Week 2 Day 4] Hard Carbon Na-Anode Battery Materials Lab β AI Simulator Activation 2026 π¬ Computational Research Note This analysis is based on computational modeling and theoretical predictions. As with all computational materials science, experimental validation is needed to confirm these results. 1. Why Hard Carbon Na-Anode Caught Our Attention Lithium-ion
Superconductor-Lab
[Week 12 Day 3] NaBeβHββ Superconductor Lab β AI Simulator Activation 2026 π¬ Computational Research Note This analysis is based on computational modeling and theoretical predictions. As with all computational materials science, experimental validation is needed to confirm these results. 1. A Quick History: Why Researchers Keep Chasing This In March
Weekly-Review
Week 11 Research Review Analysis Week 11 explored Mg-Be-H based hydride superconductors, with MgβBeHββ producing an exceptionally high Tc of 450 K at a remarkably low 50.6 GPa, though the uniformity of top results suggests possible ceiling artifacts requiring verification. NaBeβHββ (241.6 K at 97.5
Company-Spotlight
π’ COMPANY SPOTLIGHT Rigetti Computing Rigetti Computing is a full-stack quantum computing pioneer specializing in superconducting quantum processors and hybrid quantum-classical systems delivered through cloud and on-premises solutions. Quantum Computing β’ Founded 2013 β’ Berkeley, California, USA π Company Overview Focus: Quantum Computing - Superconducting Qubits π₯ Recent Developments Β£100 Million UK Investment Announcement 2026-03-25
![[Deep Dive] Laser-plasma 'mirror' unlocks a new path to extreme light intensities - Phys.org](/content/images/size/w600/2026/04/deep_dive_thumb-1.png)
Deep-Dive
π¬ DEEP DIVE ANALYSIS Laser-plasma 'mirror' unlocks a new path to extreme light intensities - Phys.org Computing β’ April 26, 2026 Reading time: ~12 minutes π Contents 1. Executive Summary 2. Technical Deep Dive 3. Market Landscape 4. Timeline & Milestones 5. Investment Perspective 6. Key Takeaways π Executive Summary The
![[Deep Dive] Alternating atomic layers enable rare electron pairing mechanism in new unconventional superconducto](/content/images/size/w600/2026/04/deep_dive_thumb.png)
Deep-Dive
π¬ DEEP DIVE ANALYSIS Alternating atomic layers enable rare electron pairing mechanism in new unconventional superconducto Energy β’ April 25, 2026 Reading time: ~12 minutes π Contents 1. Executive Summary 2. Technical Deep Dive 3. Market Landscape 4. Timeline & Milestones 5. Investment Perspective 6. Key Takeaways π Executive Summary The discovery of unconventional
![[Quantum Lab | Week 1 Day 4] Tantalum Transmon High-Coherence - AI Lab Simulation](/content/images/size/w600/2026/04/lab_quantum_Tantalum_Transmon_High_Coherence_1.png)
Quantum-Lab
[Week 1 Day 4] Tantalum Transmon High-Coherence Quantum Computing Materials Lab β AI Simulator Activation 2026 π¬ Computational Research Note This analysis is based on computational modeling and theoretical predictions. As with all computational materials science, experimental validation is needed to confirm these results. 1. Why Tantalum Transmon High-Coherence Caught Our Attention
![[Solar Lab | Week 2 Day 3] Cs2AgBiBr6 Double Perovskite - AI Lab Simulation](/content/images/size/w600/2026/04/lab_solar_Cs2AgBiBr6_Double_Perovskite_1.png)
Solar-Lab
[Week 2 Day 3] Cs2AgBiBr6 Double Perovskite Solar Cell Materials Lab β AI Simulator Activation 2026 π¬ Computational Research Note This analysis is based on computational modeling and theoretical predictions. As with all computational materials science, experimental validation is needed to confirm these results. 1. Why Cs2AgBiBr6 Double Perovskite Caught Our Attention
![[Battery Lab | Week 2 Day 3] NaFePO4 Olivine Cathode - AI Lab Simulation](/content/images/size/w600/2026/04/lab_battery_NaFePO4_Olivine_Cathode_1.png)
Battery-Lab
[Week 2 Day 3] NaFePO4 Olivine Cathode Battery Materials Lab β AI Simulator Activation 2026 π¬ Computational Research Note This analysis is based on computational modeling and theoretical predictions. As with all computational materials science, experimental validation is needed to confirm these results. 1. Why NaFePO4 Olivine Cathode Caught Our Attention In