Find a Data CenterSearch 5,870 Data Centers

The cloud is expanding—not just in volume, but in geography.In 2025, the next frontier of hyperscale infrastructure isn't on the coasts or in traditional Tier 1 markets. It’s emerging in the heartland—in cities like Columbus, Reno, Boise, and Kansas City. As the demands of latency-sensitive applications rise, hyperscalers are rethinking their location strategies, moving compute power closer to end users to deliver a new standard of performance.Why Latency is the New UptimeIn the cloud economy of 2025,latency is as critical as availability. Real-time responsiveness isn’t a luxury—it’s a requirement. Technologies reshaping user experience, such as:Online multiplayer gaming and esportsAI inference at the edgeAugmented and virtual reality (AR/VR)Connected cars and industrial roboticsReal-time financial platforms...are all latency-dependent.Centralized cloud infrastructure, no matter how powerful, can’t always meet the demands of millisecond-level responsiveness. Every mile matters. Each additional millisecond can affect gaming performance, delay AI decision-making, or degrade real-time analytics.By deploying infrastructure in smaller cities closer to users, hyperscalers reduce round-trip times—improving performance, increasing retention, and unlocking new use cases.Five Forces Powering the Shift to Smaller Cities1. Edge-Driven AI GrowthAI is evolving from centralized data center inference tolocalized decision-making. Whether it’s an autonomous drone interpreting surroundings or a smart factory optimizing processes in real time, AI needs to be near the data it consumes.Local nodes enable:Faster inference and reduced backhaulLocalized caching and model updatesQuicker insights and closed-loop decision systems2. Gaming and Content Delivery at ScaleGamers demandping times below 20ms. Content consumers expect no-buffer video streams. With growing global gaming markets and 4K/8K video on the rise, hyperscalers are racing to bring compute and storage as close as possible to user bases.3. Resilience through DistributionBeyond performance, there’srisk mitigation. Spreading workloads across geographies:Improves fault toleranceEnhances disaster recoveryReduces single-region failure exposureSmaller metros offer a canvas forredundant availability zones and failover strategies.4. Power and Land AvailabilityLarge metros like San Francisco or New York face:Limited power supplySkyrocketing land costsStrained zoning regulationsIn contrast, smaller cities present:Lower real estate and utility costsBetter zoning flexibilityEmerging renewable energy partnerships5. Compliance and Data SovereigntyPrivacy regulations (e.g., GDPR, CCPA, and country-specific localization mandates) increasinglyrequire localized infrastructure. Deploying in more geographies supports:Regional data residencyLegal compliance for global SaaS providersFaster legal processing in case of auditsEmerging Hyperscale Hubs to Watch in 2025Hyperscalers are no longer limiting their footprint to traditional Tier 1 metros. Instead, they're betting big onregional marketsthat combine favorable economics, power availability, and low-latency access to growing user bases. These smaller cities are rising as serious contenders in the global cloud map:Columbus, Ohio:Already home to Google Cloud and AWS infrastructure.Offers ample room for expansion, with strong fiber connectivity and a growing tech talent pipeline.The city benefits from a central location, making it ideal for midwestern coverage.Kansas City, Missouri:A geographically central location provides excellent latency coverage across the U.S.The city is expanding its dark fiber and broadband initiatives, making it attractive for both hyperscalers and enterprise edge deployments.Reno, Nevada:Hosts large-scale data center campuses for both Apple and Google.Offers low-cost, renewable power options and a business-friendly environment.Its proximity to Silicon Valley makes it ideal for overflow capacity and DR infrastructure.Austin and San Antonio, Texas:This fast-growing tech corridor is attracting hyperscalers due to a deep engineering talent pool and scalable power grid.Strong state-level incentives and diverse energy options make it a high-potential investment zone.Boise, Idaho and Spokane, Washington:These Pacific Northwest cities are appealing alternatives to over-saturated Seattle.They provide excellent coverage for latency-sensitive workloads while offering lower operational costs and environmental benefits.Proximity to clean energy sources makes them attractive for ESG-aligned infrastructure investments.Each of these locations is becoming more than a satellite edge presence—they're evolving intofull-fledged regional cloud zones, complete with multiple availability zones, colocation options, and hyperscaler-built campuses.Why This Matters for Enterprises and Cloud CustomersAs hyperscalers deploy into new metros,enterprises reap tangible benefits:1. Lower Latency = Better UXFaster compute access improves app responsiveness, customer satisfaction, and competitive edge.2. Regulatory ReadinessBeing able to deploy in compliance-friendly zones helps with global expansion, especially for healthcare, finance, and legal sectors.3. Optimized Workload EconomicsCompanies can run latency-sensitive workloads in local zones while offloading batch processes to lower-cost regions, maximizing performance and budget.4. More Flexible ArchitecturesEnterprises can now implementmulti-region, multi-cloudandedge-firststrategies without massive upfront investment.Changing the Economics of the CloudThe move toward regional hubs isn’t just technical—it’s strategic and economic.Hyperscalers are driving cost efficiency by negotiating:Tax incentives with local governmentsRenewable energy contracts for ESG alignmentPublic-private partnershipsfor connectivity and workforce developmentWater rights and climate-based cooling efficienciesSmaller metros are more willing to offer favorable terms, and hyperscalers gain acost-advantaged, environmentally aligned growth path.Real-World Moves by HyperscalersThis isn’t theoretical—here’s what’s happening now:Amazon Web Services (AWS):Investing in Des Moines, IA and Columbus, OH to meet Midwest demandMicrosoft Azure:Building data centers in rural Wisconsin and western Texas to enhance North American distributionGoogle Cloud:Scaling operations in Indiana and Kansas, tapping underserved tech regionsThese investments aremulti-phase, multi-megawatt buildsdesigned to last 10+ years.A Cloud That Follows the UserThe cloud is no longer centralized. It'severywhere the user is.In 2025 and beyond, hyperscalers are no longer content with coastal strongholds. As the digital world becomes more real-time, immersive, and distributed, the infrastructure must follow. Smaller cities are taking the spotlight—not as edge accessories, but asprimary cloud hubsreshaping global compute.Welcome to the era of proximity cloud.

In the race for digital dominance, land isn’t just a foundation—it’s a frontier.Land Is the New BandwidthThe digital economy is surging—and it’s not slowing down. Artificial intelligence, cloud computing, video streaming, IoT, and blockchain are driving exponential growth in data. But all that digital horsepower still needs a physical home. That’s why in 2025, land for data centers isn’t just real estate—it’s infrastructure strategy.For developers, hyperscalers, colocation providers, and investors alike, the question isn’tifto acquire land, butwhere,how fast, andhow much. As land markets tighten and development hurdles grow, securing the right parcel can offer a massive edge—or become a costly bottleneck.This blog unpacks thekey land acquisition trendsshaping the future of data centers in 2025: where demand is shifting, what site selectors prioritize, and how developers are navigating power, policy, and pricing.Why Land Strategy Is a Competitive WeaponData centers in 2025 are bigger, denser, and more demanding than ever. With workloads driven by high-performance computing, AI training, and latency-sensitive applications, the land beneath your facility must support:Power Density: 50MW+ requirements are the new norm.High-Throughput Connectivity: Multi-path fiber access is essential.Cooling-Ready Conditions: Sustainable water and airflow options.Scalability: Room to expand over 10–20 years.Reliability and Risk Mitigation: Climate-resilient, low-disruption zones.In essence, land is no longer just a place to build—it’s a foundation forlong-term compute capacity.2025’s Top Data Center Land Acquisition Trends1. Power-First Site SelectionForget location, location, location—it’s all about power.In 2025, land without sufficient, reliable electricity is a non-starter. As AI clusters drive demand for megawatt-scale deployments, operators are:Sourcing parcels within a1-mile radiusof substations.Locking inpower purchase agreements (PPAs)and green energy.Partnering early withutility providersto forecast capacity growth.This “power-first” strategy means grid access trumps geography in many cases.2. Pre-Zoned Permitting-Ready PropertiesSpeed-to-market is now a strategic necessity.Sites already zoned for industrial, tech, or special-use purposes—and located injurisdictions with expedited permitting—are commanding premium prices. Developers prefer municipalities that:Offerfast-track reviews and approvals.Have experience working with digital infrastructure.Providetax incentives or abatementsfor data center development.In other words, cities that play nice with data centers win big.3. Buying Big Banking for the FutureLong gone are the days of parcel-by-parcel development. Hyperscalers and REITs are snapping up:Hundreds to thousands of acresat a time.Strategically locatedgreenfield and brownfield properties.Sites intended formulti-phase, multi-decade buildouts.Land banking is becoming a long game. Owners are acquiring now—even if construction is 5–10 years away—to get ahead of zoning shifts, pricing spikes, and geopolitical risks.4. Climate, Cooling Water StrategySustainability isn’t optional anymore. Climate risk and water availability now shape acquisition decisions more than ever. In 2025, savvy buyers are:Avoidingflood plains, high-seismic zones, and wildfire-prone regions.Favoringcooler climatesthat support free-air or hybrid cooling.Securingwater rights or building air-cooled designsfor arid zones.Calculatingclimate resilienceinto long-term TCO models.As ESG standards tighten and public scrutiny intensifies, sustainable land decisions pay reputational and operational dividends.5. Fiber Network Proximity Is MandatoryWithout fiber, there’s no future.Buyers are demanding proximity todark fiber routes,long-haul backbones, andmetro ring networks. Some are going a step further—partnering directly with telecom providersto:Build fiber infrastructure in tandem with land development.Establish network redundancy during initial design.Ensure low-latency access to regional and global markets.In 2025, connectivity is baked into the site plan—not bolted on later.Emerging Secondary Markets for Data Center LandWhile Northern Virginia, Silicon Valley, and Dallas remain core hubs,secondary markets are booming. Developers are expanding into:Phoenix, AZ– Affordable land, solar power, low seismic activity.Columbus, OH– Central location, reliable power grid, educated workforce.Reno, NV– Pro-business tax climate, cool weather, low water usage.Las Vegas, NV– West Coast adjacency, smart water planning.San Antonio, TX– Favorable regulations, abundant land, high-capacity grid.These regions offer compelling cost-benefit tradeoffs, with scalable footprints and regulatory openness that larger metros increasingly lack.Private Equity REITs Ramp UpLand for data center development is now ahot alternative asset class. Major players in 2025 include:Real Estate Investment Trusts (REITs)acquiring land portfolios.Private equity firmsforming joint ventures with hyperscalers.Institutional investorsbacking long-term infrastructure funds.Sale-leaseback dealsallowing operators to unlock capital.These players see land not just as dirt—but asdigital gold.Navigating Community Relations Regulatory RiskNot every town rolls out the red carpet.Data centers can face opposition around energy usage, noise, heat emissions, and perceived lack of local benefit. Smart developers are:Engaging earlywith local governments and residents.Emphasizingtax revenue, job creation, and infrastructure upgrades.Designing facilities withnoise abatement,low-profile structures, andgreen buffers.Incorporatingcommunity benefit agreements(CBAs) to win support.A solid land strategy includes acommunications strategy.2025 Buyer Playbook: Best PracticesTo thrive in today’s competitive real estate environment, here’s what leading buyers are doing:Start with power: Evaluate current and future capacity.Secure zoning early: Don’t assume fast permits.Plan for modular growth: Futureproof your footprint.Get smart on water: Know your rights and cooling limits.Co-design with fiber providers: Embed connectivity from Day 1.Land Strategy = Infrastructure StrategyIn today’s AI-driven, cloud-fueled digital economy, land isn’t just a piece of the puzzle—it’s theplatform for everything that follows. In 2025, buying land for data center development has evolved from a tactical real estate move into acore infrastructure strategythat determines whether companies can scale, compete, and lead in the data era.The most forward-thinking operators are no longer just deploying servers or racks—they're buildingland pipelines, negotiatingmulti-decade utility agreements, and expanding intostrategic regionsthat support long-term capacity and sustainability goals.Whether you're a hyperscaler architecting the next 500MW campus, a colocation provider seeking speed-to-market, or an investor identifying the next breakout market, one truth remains:Land is where digital infrastructure becomes physical reality.

Artificial intelligence is evolving—and so is the infrastructure that powers it. Gone are the days when AI lived exclusively inside hyperscale cloud zones. In 2025, AI has broken free from the data center walls and is now running on the streets, in factories, inside hospitals, and at the edge of the network.Fromautonomous vehicles navigating traffic in real-timetoAI-powered sensors optimizing industrial automation, intelligent systems are increasingly deployed where decisions need to happen fast and close to the source. This shift is driving explosive demand fordecentralized infrastructure—a smarter, faster, and more agile alternative to the traditional cloud model.What Is Decentralized Infrastructure?Decentralized infrastructurerefers to compute and storage resources that are distributed across many geographic locations, rather than being centralized in a few mega cloud regions. This model includes:Edge data centersdeployed near users and devicesColocation clustersoffering dedicated capacity in key metrosBare metal nodesthat can be orchestrated globallyOn-premise AI serversintegrated with hybrid cloud toolsThis decentralized model flips the old paradigm on its head. Instead of pushing all data to the cloud for processing, it brings the infrastructurecloser to where data is generated and consumed—making AI systems faster, more secure, and better aligned with real-world needs.Why Centralized Cloud Isn’t Enough for AI AnymoreToday’s AI workloads are exposing the cracks in centralized cloud infrastructure. High-performance use cases like autonomous driving, healthcare diagnostics, industrial robotics, and real-time analytics require:Low latency:Waiting for cloud round-trips adds dangerous delays to real-time decision-making.Massive bandwidth:Transferring large datasets (e.g., video, telemetry, logs) to the cloud is expensive and inefficient.Data compliance:Regulations like GDPR and HIPAA often require data to be stored and processed locally.High availability:Relying on a single cloud zone creates single points of failure—an unacceptable risk for mission-critical systems.Centralized cloud is great for storage, scalability, and experimentation—but it’s increasinglyinsufficient for production-grade AI workloadsthat require speed, resilience, and data proximity.Key Benefits of Decentralized Infrastructure for AI1. Real-Time AI Inference at the EdgeBy deploying inference engines directly in stores, clinics, vehicles, or industrial plants, AI decisions can happen instantly—without sending data back to the cloud. This is crucial for applications where milliseconds matter.2. Distributed Model TrainingAI training jobs can be distributed across multiple regional clusters or colocation sites, tapping into local compute and reducing bottlenecks in central cloud hubs. This approach also leverages underutilized infrastructure and improves cost efficiency.3. Built-In Data PrivacyWhen sensitive data—such as medical images or customer behavior logs—never leaves the premises, organizations can ensure compliance from the ground up. Decentralization supportsprivacy by designand satisfies stringent data residency requirements.4. Resilience RedundancyBy spreading infrastructure across multiple sites, organizations gain fault tolerance and geographic redundancy. Outages in one region don’t grind operations to a halt, and disaster recovery becomes easier to orchestrate.Technologies Powering the Shift to Decentralized AIThe rise of decentralized infrastructure is backed by a maturing stack of modern technologies:Bare Metal Automation:Platforms like MetalStack, Equinix Metal, and Canonical MAAS now enable orchestration of physical servers at global scale—just like VMs in the cloud.Federated Learning:This technique trains AI models across decentralized nodes without sharing raw data—boosting privacy and enabling collaboration across jurisdictions.Containerization Microservices:Lightweight containers allow AI components to run in diverse environments—whether in a rack server or a remote retail store.Next-Gen Networking:With the help of5G,SD-WAN, and evensatellite internet, bandwidth bottlenecks at the edge are becoming a thing of the past.Together, these tools empower developers and IT teams to treat edge and remote infrastructure like an extension of the cloud—automated, observable, and ready for AI.Real-World Use Cases: Decentralization in ActionSmart Citiesare leading the way with AI used in traffic control, surveillance, waste management, and energy optimization—all processed locally for real-time action.Inretail, edge AI tracks foot traffic, predicts stock needs, and adjusts pricing dynamically—without waiting on centralized systems.Healthcare providersuse on-site AI for imaging diagnostics, patient triage, and equipment monitoring in hospitals and rural clinics.Manufacturersdeploy real-time quality control systems on the production line using cameras and sensors powered by localized AI.Eventelecomandgaming platformsare embracing decentralization, offering ultra-low latency experiences by pushing compute closer to players and users.Challenges on the Road to DecentralizationDespite its promise, decentralized infrastructure is not plug-and-play. It introduces a set of complex challenges:Operational Complexity:Managing a dispersed fleet of nodes across different environments is hard—especially at scale.Security Risks:More nodes mean more entry points. Zero-trust security frameworks become critical.Visibility Gaps:Monitoring fragmented infrastructure is tricky. Organizations need unified observability solutions.Hardware Diversity:With different vendors, specs, and environments, standardization becomes a challenge.Forward-thinking enterprises are tackling these issues by investing inDevOps for edge, leveraging tools like Ansible and Terraform, and building outobservability pipelinesthat span from core to edge.How Enterprises Are EvolvingLeading organizations aren’t replacing cloud—they’re augmenting it. Here's how they're adapting to decentralized AI:Placing workloads in Tier 2 and edge data centersto reduce latency and boost redundancyCombining private AI clusters with cloud burstingfor scale-on-demandDeploying AI nodes near end usersto process data locally and improve performanceBuilding hybrid architectureswith real-time decision-making at the edge and long-term storage in the cloudThe result? An infrastructure strategy that’s faster, smarter, and better aligned with how AI actually needs to work in the real world.The Infrastructure That Thinks AheadDecentralized infrastructure is no longer a nice-to-have—it’s the new standard for AI workloads that demand speed, scale, and security. It enables businesses to deliver intelligence at the edge, meet regulatory demands, and build resilient systems that adapt to change.In 2025 and beyond, the winners in AI won’t just be the ones with the best models—they’ll be the ones with the bestarchitecture. By rethinking infrastructure from the ground up and embracing decentralization, organizations can unlock the full potential of artificial intelligence.AI is everywhere. Now, your infrastructure needs to be too.

In the early stages of growth, startups walk a tightrope. They need infrastructure that’s fast, flexible, and scalable—but also affordable, reliable, and secure. In 2025, more and more startups are discovering that the answer isn’t just in the public cloud. It’s inbare metal servers—a strategic middle ground that offers cloud-like flexibility with physical hardware power.Bare metal gives startups complete control over their environment without requiring them to build and manage physical infrastructure from scratch. It's a cost-effective solution for companies that have outgrown cloud trials and want more stability, better performance, and a clearer financial path forward. For startups balancing innovation and efficiency, bare metal is becoming the infrastructure secret weapon.What Is Bare Metal?Bare metal refers to physical, non-virtualized servers that are dedicated entirely to a single tenant. When a startup rents a bare metal server, they’re not sharing CPU, memory, or storage with anyone else. It’s a one-to-one relationship: your team, your server.This direct ownership translates into consistent performance and complete customization. Startups can install their own operating system, configure the BIOS, and fine-tune hardware to match their specific workloads. Most bare metal providers offer cloud-like features such as remote provisioning, hourly or monthly billing, and powerful APIs—making it easier than ever to spin up dedicated infrastructure without the complexity of managing a data center.Why Startups Are Choosing Bare Metal in 2025One of the biggest reasons startups are flocking to bare metal isperformance. Whether you're building a multiplayer game, processing AI inference at scale, or delivering a high-speed video platform, performance matters. Bare metal delivers the low-latency, high-throughput environment these use cases demand—without the variability that often plagues virtual machines in the cloud.Cost is another key factor. Public cloud platforms are easy to adopt, but their pay-as-you-go models can become expensive quickly. As usage increases, so do the surprise bills. Bare metal offers a more predictable pricing structure, especially for steady, consistent workloads. You know what you're getting, and you know what you’re paying for.Then there’s the issue of control. For startups in regulated industries like healthcare, finance, or enterprise SaaS, having full oversight of data storage and processing isn’t optional—it’s essential. Bare metal provides physical isolation and data sovereignty, which helps with compliance and risk management. And finally, there's no “noisy neighbor” issue. In a shared cloud environment, other users on the same hardware can slow down your applications. With bare metal, that’s not a concern—you own 100% of the performance.Bare Metal vs. Cloud: Where It WinsWhile cloud services offer speed and elasticity, they often abstract away control. Bare metal gives startups full visibility and ownership of their infrastructure. From operating system to hardware layer, everything is customizable. This makes bare metal ideal for fine-tuned deployments that need consistency, such as GPU-intensive AI models, blockchain validation nodes, or high-performance analytics platforms.Cloud infrastructure is designed for fast scaling and short-term experimentation. But when a startup finds its footing and starts to scale production workloads, costs can balloon. Bare metal offers cost predictability and resource guarantees—important assets for growing companies that need financial clarity and operational stability.While bare metal takes slightly longer to provision than cloud services, the trade-off is access to dedicated machines tailored to exact needs. And modern bare metal providers are closing that gap with API-driven provisioning, cloud-style automation, and support for tools like Terraform and Ansible.Use Cases for Smart StartupsToday’s high-growth startups are using bare metal in all kinds of creative and strategic ways. Game studios need ultra-low latency to ensure smooth rendering and real-time responsiveness. AI and ML startups rely on GPU-heavy configurations to train and deploy large models efficiently. Streaming companies benefit from the high network throughput that bare metal supports, keeping content delivery fast and reliable.For SaaS platforms serving enterprise customers, bare metal offers the ability to create isolated, high-performance environments for each client—without sacrificing control or uptime. And in the world of Web3 and blockchain, where decentralization and compute integrity matter, bare metal servers give developers the freedom to manage infrastructure on their terms.Bare Metal in the Modern Startup StackRather than going all-in on one type of infrastructure, many startups are choosing ahybrid approach. They use cloud services for rapid prototyping, development environments, and elastic workloads. But when it’s time to scale their core applications, they shift to bare metal to gain efficiency and better control.This hybrid model gives startups the flexibility of the cloud with the performance and stability of dedicated servers. It also provides a strong foundation for resilience—allowing teams to build disaster recovery plans across different environments and infrastructure types.Who’s Leading in Bare Metal?In 2025, several providers stand out for their bare metal offerings tailored to startup needs.DedicatedNodesspecializes in edge-optimized, developer-friendly servers ideal for agile deployments.Equinix Metaloffers a global footprint with robust APIs and a vast network ecosystem.OVHcloudprovides a cost-effective option with strong privacy standards, especially appealing to European startups.PhoenixNAPdelivers high-performance, GPU-ready configurations with automated provisioning.Many of these companies offerbare metal as-a-service, blending the power of physical infrastructure with the ease of cloud automation. That means startups can deploy globally, integrate with CI/CD pipelines, and scale workloads without sacrificing performance or control.Pitfalls to Watch Out ForBare metal is powerful—but it’s not without its challenges. One common mistake startups make is over-provisioning. Unlike the cloud, there’s no “pause” button for idle servers. You pay whether you're using them or not, so careful capacity planning is key.Another trap is underestimating setup and scaling time. Even with automation, bare metal deployments can take longer than spinning up a cloud instance. Startups should plan ahead and consider how to automate provisioning using tools like Terraform or Ansible. Finally, bare metal doesn’t mean no management. Monitoring, patching, and securing your stack is still your responsibility—so embrace modern DevOps practices early on.Getting Started with Bare Metal: Best PracticesThe best way to get started is small. Deploy a single-node pilot to benchmark performance and understand how your workload behaves on bare metal. Compare results with your current cloud setup to evaluate cost and performance gains.Automate wherever possible. Provision servers using infrastructure-as-code tools. Standardize builds and set up monitoring and alerting to catch issues before they escalate. Choose a provider with scalable inventory so you can grow as demand increases. And above all, secure your environment—apply patches, configure firewalls, and implement strong authentication from day one.In a landscape where agility, cost, and performance can make or break a startup, bare metal stands out as the infrastructure that delivers all three—without compromise. It bridges the gap between the instant convenience of the cloud and the raw power of owning your own hardware, giving startups a serious edge.Whether you're building the next big SaaS platform, training AI models, running high-speed game engines, or launching Web3 applications, bare metal offers the control, consistency, and cost-efficiency that fast-moving teams need. And with modern bare metal providers now offering cloud-like automation, deployment is faster and more flexible than ever.Startups no longer have to choose between burning budget in the cloud or managing racks on their own.Bare metal is the modern middle ground—purpose-built for innovation, ready to scale, and powerful enough to support whatever you’re building next. It’s not just an alternative to cloud—it’s your launchpad to something bigger.