惯性聚合 高效追踪和阅读你感兴趣的博客、新闻、科技资讯
阅读原文 在惯性聚合中打开

推荐订阅源

SecWiki News
SecWiki News
OSCHINA 社区最新新闻
OSCHINA 社区最新新闻
V
Visual Studio Blog
博客园 - 叶小钗
S
SegmentFault 最新的问题
IT之家
IT之家
大猫的无限游戏
大猫的无限游戏
博客园_首页
Apple Machine Learning Research
Apple Machine Learning Research
钛媒体:引领未来商业与生活新知
钛媒体:引领未来商业与生活新知
月光博客
月光博客
酷 壳 – CoolShell
酷 壳 – CoolShell
腾讯CDC
D
Darknet – Hacking Tools, Hacker News & Cyber Security
V
V2EX
阮一峰的网络日志
阮一峰的网络日志
L
Lohrmann on Cybersecurity
量子位
C
Cyber Attacks, Cyber Crime and Cyber Security
T
Tor Project blog
J
Java Code Geeks
cs.CL updates on arXiv.org
cs.CL updates on arXiv.org
博客园 - 三生石上(FineUI控件)
Attack and Defense Labs
Attack and Defense Labs
AI
AI
The Cloudflare Blog
T
Tailwind CSS Blog
S
Schneier on Security
爱范儿
爱范儿
PCI Perspectives
PCI Perspectives
Stack Overflow Blog
Stack Overflow Blog
S
Secure Thoughts
Exploit-DB.com RSS Feed
Exploit-DB.com RSS Feed
T
The Exploit Database - CXSecurity.com
博客园 - 【当耐特】
V2EX - 技术
V2EX - 技术
S
Securelist
P
Proofpoint News Feed
T
Threat Research - Cisco Blogs
Help Net Security
Help Net Security
C
Cisco Blogs
N
News and Events Feed by Topic
人人都是产品经理
人人都是产品经理
B
Blog RSS Feed
K
Kaspersky official blog
T
The Blog of Author Tim Ferriss
G
Google Developers Blog
S
Security Affairs
freeCodeCamp Programming Tutorials: Python, JavaScript, Git & More
Simon Willison's Weblog
Simon Willison's Weblog

DEV Community

Authentication Security Deep Dive: From Brute Force to Salted Hashing (With Java Examples) Why AI Systems Don’t Fail — They Drift Spilling beans for how i learn for exam😁"Reinforcement Learning Cheat Sheet" I Replaced Chrome with Safari for AI Browser Automation. Here's What Broke (and What Finally Worked) How Python Borrows Other People's Work The $40 Architecture: Processing 1 Billion API Requests with 99.99% Uptime Vibe Coding: A Workflow Guide (From Zero to SaaS) Most webhook security guides protect the wrong side. The scary part is delivery. Headless CMS for TanStack Start: Build a Blog with Cosmic EU Age Verification App "Hacked in 2 Minutes" — What Actually Happened Comfy Cloud’s delete function does not actually remove files Running AI Models on GPU Cloud Servers: A Beginner Guide Event-driven media intelligence with AWS Step Functions and Bedrock I scored 500 AI prompts across 8 quality dimensions — here's what broke How to Call Google Gemini API from Next.js (Free Tier, No Backend Needed) The Portal Protocol: Reclaiming Human Connection in the Age of AI How to Fix Your Team's Scattered Knowledge Problem With a Self-Hosted Forum Intro to tc Cloud Functors: A Graph-First Mental Model for the Modern Cloud Designing Multi-Tenant Backends With Both Ownership and Team Access I Built a Neumorphic CSS Library with 77+ Components — Here's What I Learned PostgreSQL Performance Optimization: Why Connection Pooling Is Critical at Scale Cómo construí un SaaS multi-rubro para gestionar expensas en Argentina con FastAPI + Vue 3 🚀 I Built an Ethical Hacking Scanner Tool – Open Source Project I Replaced /usage and /context in Claude Code With a Single Statusline A Pythonic Way to Handle Emails (IMAP/SMTP) with Auto-Discovery and AI-Ready Design I Collected 8.9 Million Polymarket Price Points — Here's What I Found About How Markets Really Move EcoTrack AI — Carbon Footprint Tracker & Dashboard Everyone's Using AI. No One Agrees How. 5 self-hosted ebook managers worth trying in 2026 Building Your First AI Agent with LangChain: From Chatbot to Autonomous Assistant Common SOC 2 Failures (Real World) Stop Vibe-Checking Your AI App: A Practical Guide to Evals How to Use SonarQube and SonarScanner Locally to Level Up Your Code Quality Your Next To-Do App Is Dead — I Replaced Mine with an OpenClaw AI Sign a Nostr event in 60 lines of Python using coincurve — no nostr-sdk, no nbxplorer, no rust toolchain ITGC Audit Explained Like You’re in Big 4 Patch Tuesday abril 2026: Microsoft parcha 163 vulnerabilidades y un zero-day en SharePoint Stop scraping everything: a better way to track competitor price changes Listing on MCPize + the Official MCP Registry while routing payments OUTSIDE the marketplace — how I kept 100% of my x402 revenue Building an AI-Powered Risk Intelligence System Using Serverless Architecture Why We Ripped Function Overloading Out of Our AI Toolchain Testing AI-Generated Code: How to Actually Know If It Works SaaS Churn Is Killing Your Business. Here Is What to Do About It (Without a Support Team) The Speed of AI Is No Longer Linear - And Self-Improving Models Are Why How to Implement RBAC for MCP Tools: A Practical Guide for Engineering Teams From Standard Quote to Persuasive Proposal: AI Automation for Arborists I built a CLI that scaffolds complete multi-tenant SaaS apps Axios CVE-2025–62718: The Silent SSRF Bug That Could Be Hiding in Your Node.js App Right Now The dashboard that ended our friendship Data Pipelines Explained Simply (and How to Build Them with Python) The Hidden Cost of AI Systems Nobody Talks About. undefined vs undeclared, and how typeof behaves Switching from file-based jobs to NATS/Kafka in Rust without changing code io_uring Adventures: Rust Servers That Love Syscalls Why Agentic AI is Killing the Traditional Database The POUR principles of web accessibility for developers and designers Quantum Neural Network 3D — A Deep Dive into Interactive WebGL Visualization How To Install Caveman In Codex On macOS And Windows Automation Pipeline Reliability: Why Your Workflow Breaks When Nobody Is Watching I Built an 'Open World' AI Coding Agent — It Works From ANY Folder From Freelancing to Product: A Tech Service Company's SaaS Transformation China's AI Giants: Adding Tencent Hunyuan & ByteDance Doubao to AI University (74 Providers) On the Vibe Coders and Their Lies clerk: Auto-Summarize Your Claude Code Sessions AI Weekly — 2026/04/10–04/17 | The Model Lockdown Is Here, but the Toolchain Is the Real Battleground AI 週報 — 2026/04/10–2026/04/17 模型封鎖潮來了,但工具鏈才是真戰場 Maybe this is how Open-Source apps are born... 🚀 Fine-Tune LLMs with LoRA and QLoRA: 2026 Guide tRPC v11 + Next.js App Router: End-to-End Type Safety Without the Boilerplate ShadCN UI in 2026: Why I Stopped Installing Component Libraries and Started Owning My Components SaaS Billing in React Server Components: Stripe + Supabase Without a Single `useEffect` Join our DEV Weekend Challenge — $1,000 in Prizes Across TEN winners! Submissions Due April 20 at 6:59 AM UTC. Implementing FSRS Spaced Repetition in Flutter + Supabase — Adding Memory Science to an AI Learning App "I Texted My Localhost From the Train — Claude Code Fixed the Bug Before I Got Home" I Built a Sales Prep AI and It Went Deeper Than Expected Design to Code #2: One JSON, Eleven Outputs Solving the 100M-Row Problem: A Summary Table Pattern for High-Volume Push Notification Logs Flutter Web With Wasm: What Actually Changes For Developers I Built 50 Royalty-Free Soundtracks for My Side Project in a Weekend Using AI Music Generation The Vibe Coding Security Checklist: 7 Things to Check Before You Ship Stop Letting Googlebot Guess Fix Your React App's SEO Right Desconstruindo o Streaming do LinkedIn: Como Criar um Engine de Extração de Vídeo de Alta Performance com HLS e FFmpeg (EDA Part-1) EDA (Exploratory Data Analysis) Explained With Real Life — Why Looking at Your Data Is the Most Important Step in Machine Learning Brand Relationship Management at Scale: Our 4-Touch Outreach System for 200+ Brands Why String.fromEnvironment() Might Return an Empty String in Dart JGuardrails 1.0.0 — Hardening Java LLM Apps Against Jailbreaks, Toxicity, and Prompt Injection Plan and Schedule a Full Week of Threads Content From One Claude Conversation Coding Cat Oran Ep3, Five Tables Changed Everything Updated: BFF Pattern I'm done watching freelancers get buried by 200 proposals. So I'm building the alternative. This is my first post BFS Algorithm in Java Step by Step Tutorial with Examples Tracking LLM Pricing Monthly: An Open Dataset for 22 AI Models How We Measure Content ROI on a Comparison Site: Revenue Attribution Without Perfect Data Introducing Nova AI Ops: The AI-Native Operating System for SRE Teams I built a free desktop video downloader for Windows — Grabbit How Talkie OCR Helps Vision-Impaired & Dyslexic Users Read the World Around Them VRCFaceTracking安装和iPhone面捕配置教程,有bug Even CrowdStrike Can't See Your Agents The Automation Gold Rush: What n8n Workflows and Claude Are Opening Up for Developers Right Now
After Silicon: The Technologies That Will Power the Next Era of Computing
Talal Ahmad · 2026-05-15 · via DEV Community

From atomic-scale transistors to chips made of light — here is what comes after the 2nm revolution, and why it matters for everything from your smartphone to artificial general intelligence.


After Silicon

Photo by Laura Ockel on Unsplash


In Q4 2025, TSMC confirmed volume production of its N2 node. At 2nm, transistor gates are approximately 10 silicon atoms wide. That is not a metaphor for "very small" — it is a regime where quantum tunnelling, variability at the atomic scale, and statistical dopant fluctuations are no longer edge cases. They are the design constraints.

The engineering community has spent decades treating Moore's Law as a roadmap. What comes next is not one road. It is six, running in parallel.


1. Gate-All-Around (GAA) Transistors

FinFETs gave the gate three sides of control over the channel. GAA wraps it around all four sides of horizontally stacked silicon nanosheets — typically 5–8 ribbons, each 5nm thick, separated by high-k dielectric.

The physics: improved electrostatic gate control means steeper subthreshold slope, lower off-state leakage current (I_off), and the ability to tune drive current (I_on) by adjusting nanosheet width at the mask level — something FinFETs could not do without a full process change.

TSMC N2: 10–15% speed gain at iso-power, or 25–30% power reduction at iso-performance vs N3E. Gate pitch ~45nm, metal pitch ~24nm.

Intel 18A: Combines RibbonFET (GAA) with Backside Power Delivery Network (BSPDN) — PowerVia. Routing Vdd and Vss on the back of the wafer eliminates IR drop from power rails competing with signal routing on the front. Result: ~6% performance gain from BSPDN alone, plus freed routing tracks for signal density.

Samsung SF3: Implemented GAA at 3nm in 2022 — earliest production GAA — but yield challenges limited the advantage. SF2 (2nm-class) targets correction in 2025.

Next milestones: TSMC A16 (backside power + GAA, 2027), Intel 14A (first High-NA EUV in full production, 2027), IMEC roadmap to "A2" — 2 angstroms — by 2036.


2. 3D Integration: Chiplets and Hybrid Bonding

Monolithic scaling hits yield walls fast — defect density is roughly constant per unit area, so doubling die area roughly halves yield. Chiplets solve this by partitioning a design into smaller dies, each manufactured at the process node best suited to it, then integrated in-package.

The interconnect hierarchy matters:

Interconnect Type Bump Pitch Bandwidth Density
Organic substrate ~100µm ~1 GB/s/mm²
Silicon interposer (CoWoS) ~10µm ~1 TB/s/mm²
Hybrid bonding (SoIC, Foveros Direct) ~1µm ~10+ TB/s/mm²

At 1µm hybrid bond pitch, a 100mm² interface carries ~1 Pb/s of theoretical bandwidth — orders of magnitude beyond anything a PCIe or HBM interface achieves off-package.

Nvidia's Blackwell B100 connects two reticle-limited dies via NV-HBI at 10 TB/s with ~900 GB/s of HBM3e memory bandwidth. The future AI accelerator likely stacks a logic die (leading-edge node), HBM (DRAM-optimised node), and a photonics die (specialised process) — heterogeneous integration as the norm.


3. Silicon Photonics and Co-Packaged Optics

The bandwidth-per-watt of copper interconnects degrades sharply beyond ~1–2m. At rack scale in AI clusters, this is the bottleneck — not the GPU.

Silicon photonics builds optical components — ring modulators, Mach-Zehnder interferometers, germanium photodetectors, grating couplers — on standard 300mm CMOS wafers. Data modulates onto light at 50–100 Gbps per wavelength; WDM stacks 8–32 wavelengths per fibre, reaching multi-Tbps per physical link.

Co-Packaged Optics (CPO) eliminates the pluggable transceiver entirely — the optical engine is wire-bonded or hybrid-bonded directly to the switch ASIC. Nvidia's Quantum-X800 and Spectrum-X800, launched in 2026, use CPO at 100–400 Tb/s aggregate, with 3.5x power efficiency improvement and 10x signal integrity improvement vs pluggable modules.

At rack scale, the bottleneck in AI computing is not the GPU — it is the copper wire. Light carries data at the speed of, well, light.

The research frontier: all-optical neural networks where matrix-vector multiplications — the core operation in transformer inference — are performed optically at the speed of light with near-zero dynamic power. MIT and University of Strathclyde groups are the ones to watch.


4. Wide-Bandgap Semiconductors: GaN and SiC

Silicon has a bandgap of ~1.1 eV. That limits its breakdown voltage, thermal conductivity, and electron saturation velocity. Wide-bandgap materials change those limits entirely:

Property Si GaN SiC
Bandgap (eV) 1.1 3.4 3.3
Breakdown field (MV/cm) 0.3 3.3 2.5
Electron mobility (cm²/Vs) 1400 2000 (2DEG) 900
Thermal conductivity (W/mK) 150 230 490

GaN exploits a 2D electron gas (2DEG) at the AlGaN/GaN heterojunction — a high-density, high-mobility channel that enables HEMT transistors switching at RF frequencies (mmWave 5G, radar) and power conversion at >90% efficiency.

SiC MOSFETs handle 650V–3.3kV switching for EV traction inverters, industrial motor drives, and grid infrastructure. SiC inverter switching losses are ~50% lower than equivalent silicon IGBTs. SiC market CAGR projected at >20% through 2030.


5. 2D Materials: Graphene and TMDs

The IEEE roadmap identifies 2D materials as the primary candidate for sub-1nm channel materials — at monolayer thickness (~0.3nm for MoS₂), the channel is physically immune to short-channel effects that plague thin-body silicon at equivalent dimensions.

Graphene: Zero bandgap limits its use as a transistor channel, but electron mobility (~200,000 cm²/Vs suspended, ~10,000–50,000 cm²/Vs on substrate) makes it exceptional for interconnects. Copper resistivity increases sharply below ~10nm wire width due to surface and grain boundary scattering. Graphene interconnects show 100x higher current density than copper at equivalent dimensions.

TMDs (MoS₂, WSe₂, WS₂): Semiconducting 2D materials with bandgaps of 1.0–2.0 eV at monolayer thickness. TSMC's research division has demonstrated stacked nanosheet GAA transistors with monolayer MoS₂ channels integrated into the exact architecture defining N2.

In 2025, a research team published a bismuth-based transistor at 0.1nm (angstrom node) — 40% faster and 3x more energy-efficient than leading silicon nodes in benchmarks.

Before graphene powers entire systems, it will make its impact in interconnects — the first real silicon-graphene hybrid applications are closer than most engineers think.
— Semiconductor Engineering, 2025


6. Neuromorphic Computing

Von Neumann architecture has a fundamental inefficiency: the memory wall. Every operation requires data to move between processor and memory — energy spent on data movement often exceeds energy spent on computation itself.

Neuromorphic chips co-locate memory and processing. Artificial neurons integrate input spikes over time; when membrane potential crosses threshold, they fire — asynchronous, event-driven, sparse. No clock. No fetch-decode-execute. Power consumption proportional to activity, not clock rate.

Intel Loihi 2: 1 million neurons, 120 million synapses. Demonstrated 1,000x energy reduction vs GPU on certain combinatorial optimisation problems.

Photonic neuromorphic: A VCSEL with optical feedback implements a leaky integrate-and-fire neuron at GHz spike rates — six orders of magnitude faster than biological neurons. University of Strathclyde demonstrated GHz-rate VCSEL spiking networks in 2023.

The convergence target: neuromorphic processors for sparse edge inference + quantum coprocessors for optimisation + classical cores for control flow. Heterogeneous in architecture, not just process node.


The Roadmap

Timeframe Milestones
2025–2026 GAA volume production (TSMC N2, Intel 18A). CPO switches (Nvidia). GaN/SiC mainstream.
2027–2028 TSMC A16 + backside power. Intel 14A + High-NA EUV. Rapidus 2nm. First commercial photonic AI accelerators. HBM4 widespread.
2029–2032 Sub-1nm nodes. 2D material transistors in pilot production. Graphene interconnects in leading-edge logic. Neuromorphic at edge scale.
2033–2036+ IMEC A2 (2 angstrom). Photonic-electronic co-integration standard. Quantum-classical hybrid systems commercial.

Why It Matters for What We Build

The software abstractions we write against — memory models, compute primitives, communication layers — are all downstream of hardware architecture. As the hardware layer fragments into heterogeneous stacks of logic, memory, photonics, and neuromorphic accelerators, the programming models will have to follow.

The engineers who understand what is physically happening at the transistor, interconnect, and package level will be the ones who extract real performance from what comes next — not just call an API and hope.


If this was useful, drop a ❤️ or 🦄 — it helps others find the article.

Have a question about any of these technologies or want me to go deeper on one? Drop it in the comments — I read and reply to all of them.

Follow me here on Dev.to for more deep dives on semiconductor technology, AI hardware, and the engineering behind next-gen computing.


References

  1. TSMC 2nm Technology
  2. Intel 18A — Intel Newsroom
  3. Beyond the 2nm Horizon — ScienceDirect
  4. TSMC Roadmap — SemiWiki
  5. Photonic Neuromorphic Computing 2026 — PatSnap
  6. The Race to Replace Silicon — Semiconductor Engineering
  7. 2D Materials Roadmap — PresCouter
  8. TSMC 2D Materials Research
  9. Graphene Interconnects — IEEE Spectrum
  10. Neuromorphic Photonics — NIH/NCBI
  11. Future of Semiconductor Materials — Electronics360