Tebibit to Exabit

A terabit (Tbit) = 10¹² bits (SI decimal). A tebibit (Tibit) = 2⁴⁰ bits = 1,099,511,627,776 bits (IEC binary). Tebibit is 9.95% larger. At enterprise storage scale, this 10% difference has real financial consequences: a storage specification error confusing Tbit with Tibit on a 100-unit deployment results in nearly 10 units' worth of capacity discrepancy.

Tebibits appear in: NAND flash memory die specifications and yield calculations, high-speed fabric interconnect specifications (InfiniBand HDR = 200 Gbit/s), supercomputer storage system designs, and academic papers on distributed storage systems. Consumer applications never display tebibits; the term is confined to engineering and procurement contexts.

Modern 3D NAND stacks 100+ layers of memory cells vertically. A single die from a 232-layer TLC NAND chip can hold about 1 Tibit (128 GiB) raw capacity. Manufacturers measure at the die level in tebibits because binary addressing maps directly to the physical array geometry — each layer, block, and page aligns to powers of 2. A 16-die package thus holds 16 Tibit (2 TiB) before error correction overhead.

Each binary prefix multiplies by 1,024 instead of 1,000. The compounding effect: kibi vs kilo = 2.4% difference, mebi vs mega = 4.9%, gibi vs giga = 7.4%, tebi vs tera = 9.95%, pebi vs peta = 12.6%, exbi vs exa = 15.3%. The difference grows by approximately 2.4% with each prefix step, making precision in naming increasingly important at larger scales.

1 Tibit = 2⁴⁰ bits = 2⁴⁰ / 8 bytes = 2³⁷ bytes = 137,438,953,472 bytes ≈ 137.4 GB (decimal). To convert Tibit to GB: multiply by 137.4. To convert Tibit to GiB: divide by 8 (since 1 Tibit = 0.125 TiB = 128 GiB). The exact value: 1 Tibit = 128 GiB.

One exabit = 10¹⁸ bits = 125,000 terabytes = 125 petabytes. If every person on Earth (8 billion people) each stored 15 GB of data — roughly a modern smartphone's photos and messages — the total would be about 120 exabytes, or about 960 exabits. The entire human genome is about 1.5 GB; sequencing every person on Earth would produce about 12 exabytes of data.

Cisco's annual internet traffic reports estimated global IP traffic at roughly 4.8 exabytes per day in 2022, rising about 20% per year. Expressed in bits, that's about 38 exabits per day or roughly 440 petabits per second continuously. Video streaming accounts for over 60% of total internet traffic volume.

Data gravity is the principle that massive datasets attract applications, services, and additional data toward them — rather than being moved to where processing occurs. At exabit scale, physically transferring data becomes impractical: moving 1 exabit over a 100 Gbps link takes 116 days. Instead, companies deploy compute resources alongside the data. This effect drives cloud concentration — once an organisation stores exabits in AWS or Azure, the cost and latency of moving that data elsewhere creates powerful vendor lock-in, shaping the economics of the entire cloud industry.

The Square Kilometer Array (SKA), under construction in Australia and South Africa, will be the world's largest radio telescope. Its thousands of antennas will collectively produce roughly 1 exabit of raw sensor data per day — more than the entire global internet traffic of the early 2000s. This data cannot be stored in full; instead, on-site supercomputers reduce it by a factor of ~10,000 in real time, keeping only scientifically relevant signals. The SKA illustrates how radio astronomy pushes data processing to extreme scales that rival commercial internet infrastructure.

At 1 Gbps (a fast home connection), downloading 1 exabit would take 1 billion seconds — about 31.7 years. At 1 Tbps (a high-end data center link), it would take 1 million seconds, or about 11.6 days. This illustrates why exabit-scale data movements require massively parallel infrastructure — no single link or device handles exabit transfers directly.