Andrew Levy

In 1998, Honduras completed an ambitious project over the Choluteca River, a modern bridge built with Japanese engineering and intended to serve as a major artery for the country. It was constructed to be stronger and more resilient than anything that had come before it. Engineers designed it to survive hurricanes, flooding, and the intense tropical weather that often strikes Central America. For a moment it stood as a symbol of progress. Then Hurricane Mitch arrived later that same year. Mitch became one of the deadliest storms in Central American history, unleashing days of relentless rain, destroying towns, and wiping out roads across Honduras. Entire communities vanished under landslides and floodwaters. Yet in the middle of this destruction, the new bridge remained standing almost untouched. It had survived exactly what it had been built to withstand. The problem was that the storm reshaped the land itself. The Choluteca River, swollen and violent, carved a completely new channel miles to the side of the bridge. When the waters finally receded, the bridge stood proudly over an empty patch of earth, disconnected from the river it was meant to span. It became known worldwide as the Bridge to Nowhere, a strange monument to the idea that the world can change even when the structures we build remain strong. After the disaster, engineers studied the Choluteca Bridge as a case study in climate adaptation, using its survival and the river’s rerouting to illustrate why modern infrastructure must plan not only for extreme weather but also for shifting landscapes themselves. #archaeohistories

"The most important thing in the next 3-4 years is data centers in space. In every way, data centers in space, from a first principles perspective, are superior to data centers on earth. In space, you can keep a satellite in the sun 24 hours a day. The sun is 30% more intense, which results in six times more irradiance than on Earth. So you don't need a battery. The cooling in these data centers is incredibly complicated. Space cooling is free. You just put a radiator on the dark side of the satellite. The only thing faster than a laser going through a fiber optic cable is a laser going through absolute vacuum. Link satellites with lasers, and you have a faster and more coherent network than any data center on Earth."

DevDay 2025 ships: - Apps in ChatGPT - Apps SDK - Sora 2 in the API - Sora 2 Pro in the API - GPT-5 Pro in the API - AgentKit - Agent Builder - ChatKit - Guardrails - Evals - Codex GA - Codex SDK - Slack integration - Admin dashboard - gpt-image-1-mini - gpt-realtime-mini - Service health dashboard - GPT-5 40% faster w/Priority tier

A new gamma-ray camera may soon change how doctors diagnose disease. Researchers have developed the world’s first gamma-ray detector made from perovskite – a crystal best known for its role in next-generation solar cells. Now, it’s being used to capture high-resolution images of what’s happening inside the human body. In tests, this perovskite camera was able to detect faint radiation signals with unprecedented clarity – revealing structures just a few millimeters apart. That level of detail could lead to more accurate diagnoses using lower doses of radiation, and in less time. Unlike traditional detectors, which use expensive and fragile crystals like cadmium zinc telluride, perovskites are easier to manufacture, less costly, and more adaptable. Until now, their use in nuclear medicine was theoretical. This is the first real-world demonstration of their imaging power. The detector works with a process called SPECT – single-photon emission computed tomography – where a small amount of radioactive tracer is introduced into the body. The tracer releases gamma rays, and the detector picks them up to create a 3D image of internal function: blood flow, heart rhythm, or tumor activity. The technology is now being commercialized, with the goal of making advanced nuclear imaging more affordable and accessible worldwide. [“Single photon γ-ray imaging with high energy and spatial resolution perovskite semiconductor for nuclear medicine.” Nature Communications, 30 August 2025]